1 4b 1 Agriculture
Canada
FORAGE CROPS
in the Aspen Parklands
of Western Canada
1*1
Agriculture
Canada
OCT 22 1991
Library / Bibliotheque, Ottawa K1A 0C5
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PROD UCTION
Digitized by the Internet Archive
in 2012 with funding from
Agriculture and Agri-Food Canada - Agriculture et Agroalimentaire Canada
http://www.archive.org/details/foragecropsinOObeac
FORAGE CROPS
in the Aspen Parklands
of Western Canada
PRODUCTION
Research Station Melfort, Saskatchewan
Research Branch
Agriculture Canada
Publication! 87 1/E
1991
© Minister of Supply and Services Canada 1 99 1
Available in Canada through
Associated Bookstores
and other booksellers
or by mail from
Canada Communications Group — Publishing
Ottawa, Canada Kl A 0S9
Cat. No. A53-I87I/1991E
ISBN 0-660-14057-8
Canadian Cataloguing in Publication Data
Forage crops in the aspen parklands of Western
Canada. Production
(Publication;! 87 1/E)
Cat. no. A53- 187 1/1 99 IE
ISBN 0-660-14057-8
1 . Forage plants — Canada, Western. I. Canada.
Agriculture Canada. Research Station (Melfort,
Sask . ) II . Series: Publication (Canada.
Agriculture Canada). English ; 187I/E.
SB193.3.C3A8 1991 633.2'0097I2 C91-099106-5E
TABLE OF CONTENTS
ACKNOWLEDGMENTS vi
INTRODUCTION 1
WHY GROW FORAGE CROPS? 2
SELECTING A FORAGE CROP 2
Grasses 5
Bromegrass 5
Crested Wheatgrass 5
Russian Wild Rye 6
Intermediate Wheatgrass 7
Slender Wheatgrass 8
Reed Canarygrass 8
Timothy 9
Tall Wheatgrass 9
Meadow Bromegrass 10
Legumes 12
Alfalfa 12
Sweetclover 13
Sainfoin 15
Red Clover 16
Alsike Clover 17
Birdsfoot Trefoil 18
ESTABLISHING A FORAGE STAND 19
Time to Seed Forage Crops 19
Seeding Rates 20
COMPANION CROPS FOR ESTABLISHING PERENNIAL FORAGES 21
Wheat 22
Canola 22
PERSISTENCE OF ALFALFA VARIETIES GROWN WITH SMOOTH BROMEGRASS 25
A COMPARISON OF GRASS SPECIES FOR HAY PRODUCTION ON TWO SOIL TYPES
IN THE ASPEN PARKBELT 26
A COMPARISON OF REED CANARY GRASS AND TIMOTHY 27
GROWING ALFALFA FOR THE DEHYDRATING INDUSTRY 28
Seed 29
Land Preparation 29
Harvest 29
WEED CONTROL IN FORAGE CROPS 30
Tolerance of Seeding Forage Grasses to Herbicides 30
Weed Control in Seedling Forage Legumes 31
in
Vepd Control in Forage Sped Crops 33
Alfalfa 33
Weed Competition 33
Companion Crops 34
Residual Herbicides in Established Alfalfa for Seed 35
Experimental and Unregistered Herbicides 37
Seedling clovers and sweetclover 37
Seedling Birdsfoot trefoil 38
FORAGE GRASSES GROWN FOR SEED 38
Tolerance of Seedling Grasses to Herbicides 38
Effects of Graminicides on Seed Production 39
Effects of Broadleaf Herbicides on Established Grasses 39
THE ROLE OF FERTILIZERS IN A SUSTAINABLE AGRICULTURE 40
NUTRITION OF PERENNIAL FORAGES 43
Alfalfa 43
Number of Harvests Annually 44
Nutrient Removal 44
Response to Fertilizer 44
Fertilizing at Establishment 45
Fertilizing Established Stands 46
Nitrogen 46
Phosphorus 47
Potassium 47
Sulfur 49
Micronutrients 49
Grasses 50
Nutrition 50
Nitrogen 51
Potassium 54
Sulfur 54
Micronutrients 55
Nutrition of forage legume-grass mixtures 55
DETERMINING THE OPTIMUM LEVEL OF NITROGEN (N) FERTILIZER IN
SEVERAL GRASSES 55
EFFECT OF DATE OF FIRST CUT AND OF SPRING VS FALL APPLIED NITROGEN
ON HAY PRODUCTION AND PROTEIN LEVEL 59
EFFECT OF FERTILIZER ON THE PRODUCTION OF ALFALFA HAY ON THREE SOIL
TYPES IN NORTHEASTERN SASKATCHEWAN 61
USE OF BARNYARD MANURE 64
COMMON DISEASES OF FORAGE CROPS 65
FORAGES IN CROP ROTATIONS 68
IV
A Comparison of Grain and Grain-Forage Rotations 68
Soil Improvement 70
BREAKING GRASS SOD FOR CEREAL AND OILSEED CROP PRODUCTION 72
ANNUAL CROPS FOR FORAGE 76
Silage Crops 77
Managemen t 78
Pasture 78
Hay 79
Kochia 82
ACKNOWLEDGMENTS
The author acknowledges with sincere appreciation the help of the
following people in conducting the research on which this publication is
based and/or for preparing some of the written material included.
MELFORT RESEARCH STATION
Ken Bowren, B.Sc.
W.F. Nuttall, Ph.D.
D.A. Cooke, M.Sc.
J. Waddington, Ph.D.
S. Bittman, Ph.D.
N. Malik, Ph.D.
W. Berkenkamp, Ph.D.
P.R. Horton, Ph.D.
1947-87 (Retired) Forages in Crop Rotations, Use of
Animal Manure
1965-present Fertilizer for Forage Crops
1950-1977 (Deceased) Forage Variety Testing &
Agronomy
1968-1984 (now at Swift Current) Forage Agronomy &
Weed Control
1978-1987 (now at Agassiz) Forage Agronomy
1985-1990 (now at FP&I, Ottawa) Weed Control in
Forage Crops
1987-present Plant Pathologist; Crop Diseases;
Annual Crop Production
1989-present Forage Agronomy and Range Management
BRANDON RESEARCH STATION
Dr. L.D. Bailey
A.T.H. Gross
Dr. P. McCaughy
1966-present Forage Crop Nutrition and Soil
Fertility
1952-1979 (Deceased) Forage Agronomist
1988-present Forage Crop Agronomist
OTHER CONTRIBUTORS
Dale Pulkenin
Zelda Fisher
Dr. Karen Wittenburg
Saskatchewan Dehydrator's Association, Tisdale,
Saskatchewan - producing alfalfa for the Dehydrated
Alfalfa Industry
Department of Animal Science, University of Manitoba
Appreciation is also expressed for statistical information on crop
production supplied by the Policy and Economics Branch of Manitoba
Agriculture.
The author also acknowledges with deep appreciation the invaluable
contribution of Mrs. Susan Wittig, who typed the manuscript and prepared the
tables, and Drs. Lorraine Bailey, Russel Horton and Bill Berkenkamp who
reviewed the manuscript.
VI
INTRODUCTION
La production de plantes fourrageres vivaces a un role crucial a jouer
pour ce qui est de diversifier l'economie agricole et de maintenir la
productivity des sols dans les Prairies. La plupart des exploitations
agricoles de la prairie-parc de l'ouest du Canada (fig. 1) auraient grandement
interet a faire plus de place aux plantes fourrageres dans leurs assolements.
Cela est particulierement vrai dans les cas des terres difficiles a
travailler, regulierement inondees au printemps, caracterisees par une courte
periode exempte de gel ou aux prises avec de graves problemes d' erosion. II y
a egalement des avantages a cultiver des plantes fourrageres sur les terres
qui conviennent aux cultures annuelles.
En semant des legumineuses telles que le melilot, le cerealiculteur peut
ameliorer la fertilite et les proprietes physiques de ses sols. La production
de foin comme culture commerciale ameliore l'utilisation de la main-d'oeuvre
disponible et diversifie les sources de revenus. Les naisseurs et les
engraisseurs de bovins de boucherie peuvent acquerir une plus grande marge
d' independance en produisant leurs aliments du betail. Des options plus
nombreuses s' off rent pour la formulation des rations, ce qui permet de tirer
parti des aliments les plus economiques, car le foin de qualite superieure
peut la plupart du temps etre vendu avec profit.
La rentabilite des cultures fourrageres a souffert par le passe et
continue de souffrir d'une reticence a appliquer la technologie disponible a
tous les aspects du systeme de production. Souvent, les cultures fourrageres
sont releguees aux terres les mo ins productives, les paturages sont mal
amenages et la production fourragere jouit d'une faible priorite. Meme
lorsque le foin est recolte, on deplore souvent une forte baisse de sa valeur
nutritive imputable a une alteration au cours de la periode separant la
recolte de l'utilisation. Jusqu'a tout recemment, les possibilites
d' incorporation des fourrages dans les rations d'engraissement etaient
largement meconnues. Cette technologie permet de remplacer les cereales par
des plantes fourrageres sur des terres mieux adaptees a ce type de
production. Une telle substitution ne se traduirait pas necessairement par
une forte croissance du cheptel d'elevage dans l'hypothese ou les fourrages
remplaceraient les grains comme principal ingredient des rations. Toutefois,
lorsque les grains se vendent a des prix derisoires ou sont difficiles a
ecouler, 1 * intensification des productions animales pourrait avoir des
retombees favorables sur l'economie, pour peu que des marches normaux ou en
croissance existent.
La presente publication resume les recherches menees a la Station de
Melfort sur la production fourragere, et elle integre de 1 ' information
provenant d'autres sources situees dans la prairie-parc, en particulier la
Station de recherches de Brandon. L'accent est mis dans une large mesure,
mais non exclusivement , sur les plantes fourrageres vivaces cultivees, a cause
de leur role dans les systemes agronomiques de conservation. II est reconnu
que les cultures annuelles jouent un role important comme sources de
paturages, de foin et d' ensilage pour les ruminants, mais leur production a
fait l'objet de beaucoup de recherches et de publicite. La presente etude
s'inscrit dans une serie de publications visant a promouvoir une production,
une recolte et une utilisation plus efficaces des plantes fourrageres. Elle
est d'abord confue a 1' intention des agronomes et des etudiants en agriculture.
VII
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VIII
INTRODUCTION
The production of perennial forage crops has a vital role to play in
diversifying the agricultural economy of the prairies and maintaining the
productivity of the soil. Most farms in the Aspen Parklands of Western
Canada (Fig. 1) would benefit considerably if more forage was included in the
cropping program. This is especially true for land that is difficult to work.
or that regularly experiences spring flooding, a short frost-free period or
serious soil erosion. There are also advantages in growing forage crops on
land suitable for the production of annual crops.
By growing legumes such as sweetclover, the grain farmer can benefit
through improved fertility and physical condition of the soil. Hay produced
as a cash crop, will better utilize the available labor supply and diversify
income possibilities. The cow-calf operator and cattle finisher can benefit
by being more independent of others for their feed supply. More options are
available for formulating rations to take advantage of the cheapest feeds
available and high quality hay can be sold profitably in most years.
The economics of forage crop production has suffered in the past, and
still does because of failure to apply available technology covering all
aspects of the forage system. Forages on many farms are grown on the
least-productive areas, pastures are often mismanaged and haying operations
are given a low priority. Even when hay is harvested, it often seriously
deteriorates in feeding value because of weathering during the period from
harvesting to feeding. Until recently, the technology of utilizing forages
in finishing rations for beef cattle has been largely overlooked. This
technology allows forage crops to replace cereal crops grown on land that is
better suited for forage crop production. Such a shift would not necessarily
mean a large increase in livestock numbers if forages replaced cereals as the
main component of the feed supply. However, when grain is low priced or
difficult to market, increasing livestock production could have a positive
impact on the economy provided normal or increased markets were available.
This publication summarizes research carried out at the Melfort Station
on the production of forage crops and includes information from other sources
in the Aspen Parkbelt, particularly the Brandon Research Station. The
material focuses largely, but not exclusively, on cultivated perennial forage
crops because of their role in soil conserving agronomic systems. It is
recognized that annual crops play an important role in providing pasture, hay
and silage for ruminant livestock, but their production has been well
researched and publicized. This publication is one of a series of
publications aimed at promoting more efficient production, harvesting and
utilization of forage crops. The publication is designed to provide
information primarily to agrologists and agriculture students.
WHY GROW FORAGE CROPS?
Including perennial forage crops, (particularly legumes) in crop
rotations in the Aspen Parkland can have the following beneficial effects.
1. The year-round stand provides physical protection to the land from
wind and water erosion and may prevent the development of soil salinity.
2. Alternating cereal, oilseed, and pulse crops with perennial forages
crop can help to break insect and disease cycles and to control weeds.
3. The deeper rooted perennials can use moisture and leached nutrients
that lie below the reach of annual crops.
4. The more extensive root system of forages helps to improve soil
structure and to hold the soil more firmly against the forces of wind and
water.
5. By building up the organic matter content of the soil, water holding
capacity is increased, favorable microflora activity is increased (helping to
make more nutrients available to the plant), soil temperature fluctuations
are moderated and the soil is much easier to work (for example, power
required to till soil at Melfort was reduced by 25% when legumes were
included in the crop rotation).
6. Perennial legumes interact with microorganisms to fix nitrogen from
the air to meet up to 100% of their N requirements. The process can be
managed to improve soil fertility.
7. Forage crops properly grown, harvested, stored and fed can supply
high quality feed to ruminant livestock, and, in a competitive market, often
return greater profits to the farmer in addition to benefitting his soil.
8. Forage crops are less weather dependent with respect to seeding,
frost, hail and drought damage than are cereal and oilseed crops.
9. Forage crops for hay and silage can help make more effective use of
available labor and equipment (swathers, tractors), as peak requirements do
not coincide with those of either cereal or oilseed production.
10. Harvesting, storing, and feeding mechanization have greatly reduced
the labor required to produce hay and silage.
SELECTING A FORAGE CROP
The key factor in the choice of a forage crop is the environment (soil
and climatic conditions) prevailing in the area. A suitable forage species
must be able to produce high yields of good quality forage if it is to be
profitable to the grower. Because new forage crop species or varieties are
constantly being introduced and/or developed for specific purposes, it is
recommended that growers check with their nearest forage crop agronomist
before seeding land to perennial forages, which could be in production for
many years.
When assessing characteristics of forage crop varieties, remember that
unlike cereal, oilseed and pulse crops, the primary purpose of a forage crop
is to produce hay, silage and pasture. Dry matter yield (and quality) are
much more important than ability to produce seed. Obviously, a high dry
matter producing forage variety that also has a good seed yield, is
preferable to one that produces little seed, but a high seed-producing
variety that doesn't have good dry matter production under any environmental
situation is of no real economic value.
Usually, there are several species or varieties of forages that are well
adapted to a specific environmental condition. Within these, the following
factors should be considered when choosing a forage.
1. What use is to be made of the forage? Will it be harvested for hay,
silage, dehydrated alfalfa or seed, or will it be used for pasture or perhaps
for several uses?
2. To what class of livestock will it be fed?
3. What harvesting method will be used?
4. How will the crop be stored prior to feeding to livestock?
5. Ease of establishment? Will it compete with the weeds present in
the soil?
6. Does it have resistance to disease and insects likely to be a
problem in the area?
7. If not used on the farm, is there a ready market for the crop?
8. How long will the stand be expected to produce?
9. How important are the soil improving capabilities of the crop?
Many species and varieties of perennial forage crops are adapted to one
or more of the environmental conditions prevailing in the Aspen Parkbelt.
The following are some of the more important forages currently produced.
Their general description and their suitability for various conditions and
purposes are briefly described. (The companion bulletin "Pasture Production
and Utilization in the Aspen Parkland of Western Canada" contains information
on perennial forages which are well suited for pasture purposes.) A summary
of various characteristics of some species commonly grown in the Aspen
Parkland is found in Table 1.
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GRASSES (See Tables 2 and 3)
Bromegrass
A leafy grass reaching a height of around 1 meter and spreading rapidly
by means of underground rhizomes. The creeping tendency varies in degree
from variety to variety but eventually results in such a heavy mat of
rhizomes that plant vigor is affected and yields are reduced. The grass is
long-lived and with good management will produce satisfactorily for many
years.
Adaptation; - widely adapted, prefers cool, moist conditions
and a well-drained soil
Drought resistance: - moderately good
Spring flooding tolerance: - about 2 weeks with cool temperatures
- moderate to high, depending on vigor of the
creeping habit
- several leaf spots may reduce quality
- moderate
- very good, both as pasture and hay
- hay 2-4 tonnes/ha, seed 300-400 kg/ha
- Carleton, Magna, Rebound, Signal
- best-quality hay: cut no later than flowering
stage
- poorer but acceptable hay: cut immediately
after seed crop is removed
- seed: swath when stem just below seed head has
turned brown
Crested wheatgrass
A long-lived bunchgrass growing 60 to 90 cm tall, with wide-spreading
root system, fine stems and fairly narrow leaves. It is well adapted to Brown
soil zones but has performed extremely well at Melfort. Spring growth
commences very early. The grass should be grazed or mown before seed heads
develop as they are unattractive to stock. It tends to go dormant in dry, hot
weather and to recommence growth when moisture conditions improve.
Drought resistance: - very good
Competitive ability:
Pests and diseases:
Salinity tolerance:
Palatability:
Productivity:
Varieties:
Time to harvest:
Spring flooding tolerance
Competitive ability:
Pests and disease:
Salinity tolerance:
Palatability:
Productivity:
Varieties:
Time to harvest:
- about 7 days
- good, combines well with alfalfa and is a good
weed competitor
- no serious problems
- fair
- excellent when young; seed heads unpalatable as
pasture. Good feed conversion efficiency.
- hay 2-4 tonnes/ha; seed 300-650 kg/ha
- Parkway, Fairway, Kirk
- hay: cut before flowering
- seed: swath when heads are brown but stems
still green (seed in medium-dough stage)
- pasture before heading
Russian wild rye
A long-lived bunchgrass, producing an abundance of bluish-green basal
leaves 30-45 cm high, topped by a seed stalk about a meter high. This grass
is the first to start growth in spring and continues to grow until late fall.
The leaves remain palatable at all times and provide excellent pasture. For
adequate and sustained seed production, the grass must be mown or grazed to
the ground immediately after seed harvest; otherwise, growing points develop
too far above ground and future seed production is imperilled. Maximum
production is not reached until the 3rd or 4th year after establishment.
Adaptation:
Drought resistance:
Spring flooding tolerance:
Competitive ability:
Pests and diseases
Salinity tolerance:
- loam and clay loam soils in drier parts of the
Black soil zone
- excellent
- very low
- weak, slow-growing seedlings are hard to
establish when weed competition is strong; once
established, it is very competitive, and will
suppress most weed growth for at least 30 cm
distant
- leaf diseases on some varieties, e.g., Sawki
- excellent tolerance once established
Palatability:
Varieties:
Productivity:
Time to harvest
- moderately good at all stages of growth
- Swift, Mayak, Tetracan
- forage for pasture: about 2 tonnes/ha (not
grown for hay)
- seed: 300-550 kg/ha common in 2-4-year-old
stands when grown in rows 45-90 cm apart
- pasture: best to graze early in spring and late
in fall with a mid-summer rest if possible
- seed: swath just above basal leaves when straw
has turned yellow (seed at firm-dough stage) and
combine as soon as seed is dry
Intermediate wheatgrass
A tall-growing perennial often exceeding a height of 120 cm. It produces
a stemmy growth, with fewer basal leaves than bromegrass, and looks like
quackgrass. It is usually considered a moderately short-lived grass (3-4
years), but at Melfort, in mixtures with alfalfa, has persisted for 7 years.
It is well adapted to the Parkland area and with alfalfa provides good
pasturage.
Adaptation:
Drought resistance:
Spring flooding tolerance:
Competitive ability:
Pests and diseases:
Salinity tolerance:
Alkalinity:
Palatabili
IX:
Productivi
ty:
Varieties:
Time to harvest:
- prefers well-drained soils with adequate moisture
- fair
- poor
- fair; combines well with alfalfa, but is not a
vigorous creeper
- no severe problems
- poor
- tolerant
- excellent
- hay 2-4 tonnes/ha; seed 300-400 kg/ha
- Chief, Clarke, Greenleaf
- hay: cut when seed head appears
- seed: swath when most seed heads have turned
light brown (earliest heads will be shattering)
Slender vheatgrass
A short-lived bunchgrass (3 years) producing a stemmy growth 60-90 cm
high. Seedlings are vigorous, easily established and under good growing
conditions a crop can be taken in the seedling year. Hay is of fairly good
quality, provided the crop is cut at the early heading stage.
Drought resistance; - good
Spring flooding tolerance: - 1-2 weeks
- good
- good
- fairly good
- hay: 2-3 tonnes/ha (4-year average, including
year of seeding)
- seed: 450-675 kg/ha
Varieties: - Revenue
Pests and
diseases:
Salinity
tolerance:
Palatabil
ity:
Productivity:
Reed canarygrass
A long-lived, creeping-rooted grass, growing 1-2 meters tall. It
produces large amounts of leafy forage, which varies in palatability from
plant to plant because of differing levels of alkaloids. Palatable forage can
be obtained if grass is harvested before flowering. Adapted to long periods
of flooding, but also produces good yields under dryland conditions. Because
of shattering, this grass is difficult to harvest for seed. It can be
straight combined, but timing is very critical.
Adaptation:
Drought resistance:
Spring flooding tolerance
Competitive ability:
Pests and
diseases:
Salinity
tolerance:
Palatabil
ity:
prefers adequate moisture and a cool climate.
Thrives in areas with a high water table or
subject to flooding.
fair
excellent
good
no severe problems
low
variable, but is satisfactory if harvested early
Varieties:
- Rival, Venture (all low alkaloid)
Productivity:
Time to harvest:
hay: 4-6 tonnes/ha
seed: 200-250 kg/ha
for best hay: cut between boot and early
flowering stages (not always possible because of
soil moisture where this grass grows)
coarse hay: cut as soon as possible after seed
crop is harvested
seed: swath when seeds at top of panicles have
turned brown or gray; or straight combine as
soon as seeds in top of panicle start to fall
out when struck
Timothy
A long-lived bunchgrass, producing good-quality hay. The grass is quite
shallow rooted and produces high yields of hay only where moisture is
plentiful.
Drought resistance: - poor
Spring flooding tolerance: - very good
Competitive ability:
Pests and diseases:
Salinity tolerance:
Palatability:
Productivity:
Varieties:
- good with adequate moisture; fairly good on
dryland once established
- rusts and leaf spots may occur in some years
- very low
- good. A popular hay for horses if put up free
of dust prior to the fully-headed stage.
- hay 1-2 tonnes/ha; seed 300-450 kg/ha
- Climax, Champ, Basho, Itasca, Timfor
Tall wheatgrass
A long-lived, coarse bunchgrass. It is useful because it is the most
saline tolerant of the better quality grasses. Hay is of good quality,
provided it is made before the grass flowers. The grass matures too late for
reliable seed production in the Parkland area of Western Canada. It is
usually grown only on saline soils where other grasses are unsatisfactory.
Yields vary, depending on moisture and degree of salinity.
Drought resistance:
Spring flooding tolerance
Pests and diseases
Salinity tolerance
Palatability:
Varieties:
Productivity:
- fairly poor
- 3 weeks
- no severe problems
- very good
- good, when harvested before fully headed
- Orbit
- hay; 2-3 tonnes/ha. Three years after
establishment on a moderately saline black soil
at Melfort, a yield of 5.6 tonnes/ha was
obtained, in two cuts, when fertilized with 90
kg N and 45 kg P^/ha.
Meadow bromegrass
A long-lived perennial bunchgrass, similar in appearance to smooth brome
but with less creeping ability. Produces considerable root and crown material
and provides good protection against soil erosion. Plant material has a
higher proportion of leaf than smooth bromegrass. Seed stalks are 60-90 cm
tall. Seed matures earlier than does that of smooth bromegrass.
Adaptation:
Drought resistance:
Flooding
tolerance:
Competitive ability
Pests and
diseases:
Palatabil
ity:
Salinity
tolerance:
Persistence:
- well suited to areas where smooth bromegrass
thrives. Requires at least 350 mm precipitation
annually for good production. Prefers soils
ranging from slightly acidic to mildly alkaline.
Winter hardiness may be a problem under some
conditions and is still being evaluated.
- good
- up to two weeks in the spring before growth
begins. None after that
- compatible with alfalfa
- susceptible to aphid infestations
- vegetative growth very palatable
- somewhat tolerant
- long term persistence still unproven in the
Aspen Parkland. Some winter killing has
occurred at Melfort.
10
Yield:
Varieties:
- similar *fo, or slightly higher than, smooth
bromegrass, with better recovery following
cutting or grazing, thus greater late season
production
- Fleet, Paddock, Regar
Table 2. Comparative Yield of Forage Grass Species for Hay and
Pasture at Melfort (kg DM/ha) 2 year average (1980-1981)*
Species
Hay
Simulated Pasture
Two-cut
(3-4 cuts)
10180
8480
8660
9300
8170
7260
8170
8820
7870
8060
7450
7700
7050
6130
6380
7620
5920
6410
5830
5170
5720
6710
5330
4930
4920
4140
3000
3450
2770
2710
Crested wheatgrass
Intermediate wheatgrass
Meadow bromegrass
Altai wild rye
Pubescent wheatgrass
Slender wheatgrass
Russian wild rye
Smooth bromegrass
Green stipa grass
Creeping red fescue
Tall wheatgrass
Meadow foxtail
Timothy
Hard fescue
Kentucky bluegrass
*Including first harvest year
11
Table 3. Comparative Yields' of Fertilized and Unfertilized Grass
Species in a Two Cut System at Melfort (kg DM/ha) 2 year average
(1983-1984) - Seeded 1980
Species
Unfertilized
Fertilized*
Smooth bromegrass
Crested wheatgrass
Intermediate wheatgrass
Pubescent wheatgrass
Altai wild rye
Russian wild rye
Meadow bromegrass
Green stipa
Kentucky bluegrass
Creeping red fescue
1150
1360
960
1080
1010
700
1270
1220
950
620
2940
3060
2570
2400
2290
1790
3150
2890
2690
2590
*100 kg 11-51-0/ha prior to seeding plus 100 kg N and 30 kg P205
annually.
Note: A comparison of Tables 2 and 3 reveals startling variations in
production between years and that growing conditions can
affect the relative yields of species.
LEGUMES
Alfalfa
A bloat-causing legume, growing to a height of 60-90 cm. Leaves are
trifoliate with smooth or slightly toothed margins. Stems are fairly slender,
either solid or hollow. Flowers grow from leaf axils and are usually blue,
purple or variegated in color, although other colors are not uncommon. Seed
pods vary in shape from crescent-shaped to several tight whorls, with several
seeds per pod. Root systems vary from a branched taproot to a creeping-rooted
type, all penetrating deeply. For pasture, alfalfa is usually grown with a
grass. For seed production, use of leafcutter bees is essential for good
pollination.
Adaptability:
- wide, but prefers deep, well-drained loam with
high calcium content (neutral to slightly
alkaline)
Drought resistance: - very good
Spring flooding tolerance: - 1 week
Competitive ability: - good to very good, increasing with proportion of
12
Pests and diseases:
Winterhardiness:
creeping-rooted plants
- forage fields seldom suffer seriously from pests
and diseases
- the most prevalent pests are plant bugs that
damage flower buds and reduce seed yields
- several leaf spots and stem blights can weaken
plants by causing early leaf death but rarely
kill plants
- winter crown rot weakens plants and makes them
unproductive and shortens life of the stand
- most modern alfalfa varieties are resistant to
bacterial wilt
- burning an alfalfa seed field in early spring
helps control most diseases and insects
- excellent for recommended varieties
Salinity tolerance:
Palatability:
Productivity:
Popular varieties:
Time to harvest:
- moderate
- very palatable; excellent pasture or hay, but
may cause bloat under some conditions
- 2-5 tonnes (non-irrigated)
- seed: 200-400 kg/ha (dryland), up to 800 (under
irrigation)
- Rambler, Roamer, Heinrichs, Drylander,
Rangelander, Beaver and others. (See local
forage agronomist for varieties best suited to
your needs.) (See Table 4)
- pasture: do not overgraze; allow regrowth to
reach early-bud stage; avoid heavy grazing
between 1st week of September and freeze-up
- hay: cut between late-bud and 10%-bloom stages
(usually late June - early July)
- seed: straight combine after severe frost dries
out stems; or swath when 75% of seed pods have
turned black or dark brown and combine when
stems have dried out (swath when the crop is
slightly damp from dew as seed pods are less
likely to break off and be lost)
Sweetclover
An upright biennial (or occasionally annual) legume reaching a height of
1-2 meters. Leaves are trifoliate with toothed margin and bitter taste.
Spikes of flowers grow from leaf axils and, after pollination, are replaced
13
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by small pods each containing one seed. The stems are succulent at first,
but turn woody as plants mature. Yellow-flowered varieties are finer-stemmed
and better for hay or pasture. There is some danger from badly cured hay of
some varieties due to the formation of a blood anticoagulating substance. To
avoid this, try to ensure the crop is cured rapidly and stored to prevent
spoilage (molding).
Adaptation;
- prefers well-drained clay and loam soil but can
be successfully grown on sandy and heavy clay
loams, and on gray wooded soils
Drought resistance: - good
Spring flooding tolerance; - very poor (less than 1 week)
Competitive ability:
Pests and diseases:
Winterhardiness:
Salinity tolerance:
Palatability:
Productivity:
Varieties:
Time to harvest:
- as seedling, fair; as mature plant in 2nd year,
good.
- no serious diseases
- main pest is sweetclover weevil, which can eat
seedlings to the ground in a short time
(2nd-year plants usually grow fast enough to
withstand infestation)
- excellent in recommended varieties
- moderate
- fairly palatable when young and succulent, can
cause bloat
- hay 2-4 tonnes/ha; seed 500-700 kg/ha
- Norgold, Polara (low coumarin varieties)
- pasture: graze in 2nd year when growth reaches
30-45 cm
- hay: cut at early bud stage
- seed: when 2/3 of seed pods have turned brown
- green manure: preferably when the plant is in
full bloom
Sainfoin
A tall, perennial legume reaching a height of about 1 meter. The plant
has pinnately divided leaves, which resemble those of vetch without tendrils;
and coarse, succulent, hollow stems, which are terminated by long spikes of
pink flowers. The seeds are smooth, kidney-shaped, olive to dark brown,
about 0.3 cm long and usually enclosed in pods the shape of a flattened
15
hemisphere with a raised network of veins on the surface. A deeply
penetrating, branched taproot makes the plant drought resistant. Spring
growth starts very early. Regrowth after a harvest is usually slow. Leaf
retention is good and quality loss with increasing age is slower than for
alfalfa. This legume does not cause bloat.
Adaptation:
Drought resistance:
Spring flooding tolerance:
Competitive ability:
Pests and diseases:
Salinity
tolerance:
Palatability:
Vinterhardiness:
Varieties:
Productivity:
Time to harvest
- prefers dry calcareous soils, but does well on
thin and gravely soils
- very good
- very poor
- because of its open growth, weeds can become
established easily but are tolerated well
because the crop is tall. In pasture mixtures
sainfoin does not persist because of its
excellent palatability.
- no problems at present
none
- very palatable, both as hay and pasture
- good, provided crop is well established (do not
harvest in year of establishment until after
freeze-up)
- Melrose, Nova
- hay: 2-4 tonnes
- seed: 500-900 kg/ha
- pasture: graze at bud or early bloom stage to
allow good regrowth
- hay: cut at 10-50% bloom for optimum yield and
quality
- seed: swath when lowest seed pods on heads
have turned brown and are about to break off;
combine several days later (seed should not be
threshed free of pod)
Red Clover
A short-lived perennial with many stems arising from a crown, which has
a fairly deep, branched taproot. The stems are succulent and bear trifoliate
leaves with a distinct pale V marking on each leaflet. The flowers are pink
and are in compact heads at the tips of the stems. The whole plant is often
16
very hairy. Red clover is not grown for forage in northeastern Saskatchewan
because alfalfa and sweetclover produce higher yields.
Drought resistance: - fairly poor
Spring flooding tolerance: - 1-2 weeks
Competitive ability:
Pests and diseases:
Salinity tolerance:
Vinterhardiness:
Palatability:
Varieties:
Productivity:
- fairly good, but deteriorates as stand thins
after 3rd year
- several diseases (mildews, leaf spots, northern
anthracnose, clover sclerotinia rot) alone do
not kill plants but together weaken them too
much to survive winter
- very low
- fair under dryland conditions; good when soil
moisture plentiful
- very palatable, but may cause bloat
- Altaswede, Norlac - produces one hay crop and
some regrowth
- hay 2 tonnes/ha; seed 280-675 kg/ha
Alsike clover
A bloat-causing perennial, tillering profusely from the crown and
producing slender, somewhat prostrate stems 60 to 90 cm long. Leaves are
trifoliate and heads of pinkish-white flowers are produced in leaf axils.
The plant is completely hairless. Alsike clover is often grown for seed in
northeastern Saskatchewan, but seldom for forage as alfalfa and sweetclover
outyield it. The legume combines well with timothy or reed canarygrass in
areas too wet for more productive legumes.
Adaptation:
Drought resistance:
Spring flooding tolerance
Competitive ability:
Pests and diseases:
cool, moist growing conditions, well suited to
acidic organic soils, Gray Luvisol soils and
heavy, moist, alkaline soils. Low tolerance to
salinity.
fairly poor
several weeks (5-6)
good
no serious problems
17
Sal inity tolerance:
Palatability:
Vinterhardiness;
Varieties:
Productivity:
- low
- very palatable, but can cause bloat
- poor, but generally reseeds itself
- Dawn, Aurora
- seed: 500 kg/ha
Birdsfoot trefoil
A perennial, producing many fine stems 30-60 cm long. Leaves have five
leaflets, two close to the stem and three on a short stalk. Flowers are
fairly large and bright yellow in clusters of 5-7. The plant does not cause
bloat. It yields less than alfalfa in northeastern Saskatchewan and so is
not usually grown for forage.
Drought resistance:
Spring flooding tolerance:
Competitive ability:
Pests and diseases:
Salinity tolerance:
Palatability:
Vinterhardiness:
Varieties:
Productivity:
- fair
- several weeks
- poor
- no serious problems
- low
- very palatable
- fair
- Cree, Leo (also Empire in Manitoba)
- hay: 2.0 tonnes/ha (where moisture is good)
- seed: potential 700-800 kg/ha, but likely to
get 200-300 kg/ha (seed set usually good but
shattering can quickly reduce yields)
A summary of characteristics of various species of perennial forages is
presented in the following chart.
COMMENTS
Yields of all forage crops are extremely variable, depending on many
factors, especially moisture supply and level of available soil and
fertilizer nutrients. In general yield figures cited are for average to
above average growing conditions and are not intended to provide valid
18
"between species" comparisons.
ESTABLISHING A FORAGE STAND
Soil moisture conditions are critical to the establishment of perennial
forage crops. Because forage seeds (except Sainfoin) are quite small
compared to seeds of cereal and pulse crops, they must be seeded shallowly (1
to 2 1/2 cm) in order to reach sunlight before their energy supply is
exhausted. It is essential that the moisture supply near the soil surface be
ample to meet the need of the germinated seed until its roots can reach
moisture at lower levels.
Seeding into a properly prepared seedbed is required for successful
establishment of a forage crop. Veeds should be controlled prior to seeding
to the extent practical, by the use of cultivators or appropriate herbicides
to eliminate competition for water, sunlight and soil nutrients. Packing or
rod-weeding before seeding helps to firm the seedbed. A firm, level seedbed
makes it easier to control the depth of seeding. Although a finely worked
soil is best for the seedlings, it can predispose to erosion and crusting
problems in some soils, hence some lumpiness may have to be tolerated.
With the advent of zero-tillage it may be satisfactory to seed the
forage crops directly into standing stubble. Provided weeds are absent or
can be controlled with a non-residual herbicide, this will help to protect
both the soil and the developing seedling from the adverse effect of wind
(erosion and loss of moisture) and may in some conditions provide beneficial
shade.
In the Aspen Parkbelt perennial forages are usually seeded in 30 cm
(12") rows for hay production (see section on seeding rates).
When the forage stand is used for hay or silage production, the weed
problem can be considerably reduced during the initial year or two by
harvesting the crops before weeds produce seeds (See section on Weed
Control) .
TIME TO SEED FORAGE CROPS
Seeding Time Overall Rating
Late April- Fair to very good
mid-May
Comments
Excellent moisture and cool
temperatures are good for forage
establishment. Limited opportunity
for preseeding weed control may
lead to problems later. Frost
hazard.
19
Mid-May-
mid-June
Mid-June-
mid-August
Very good to fair
Poor
Good moisture and cool temperatures
are good for forge establishment.
Opportunities exist for preseeding
weed control. Probably the best
time of year for seeding,
especially last half of May.
Moisture can be variable, leading
to patchy germination. High day
temperatures can desiccate
seedlings. Rapid growth of annual
weeds can cause problems in
control.
Mid-August-
September
Late October
Good, except
legumes
Fair
Moisture can be good, and cool
temperatures, especially at night,
are good for grass establishment.
Legumes may winterkill due to
insufficient time for them to
become properly established. Weeds
not usually a problem.
Seeds germinate the following April
when moisture is excellent,
temperatures are cool and frost
damage may occur.
SEEDING RATES (Northeastern Saskatchewan)
Sow at the following rates, kg/ha (lb/ac), in rows 30 cm (12") apart,
except where otherwise indicated:
Forage
Grasses
Bromegrass
Crested wheatgrass
Intermediate wheat-
grass (pubescent
wheatgrass)
Meadow bromegrass
Russian wild
ryegrass
Tall wheatgrass
Slender wheatgrass
Reed canarygrass
For hay
9 (8)
8 (7)
14.5 (12-14)
U (10)
Not recommended
13 (12)
U (10)
6-8 (5-7)
For pasture
9 (8)
8 (7)
14.5 (12-14)
U (10)
8 (7); 4.5 (4)
(60 cm rows)
13 (12)
U (10)
6-8 (5-7)
For seed
5.6 (5)
3.5 (3) (90 cm rows)
3.5 (3) (60-90 cm rows)
5.5 (5) (90 cm rows)
7 (6)
r (2) (90 cm rows)
Not recommended
11 (10)
2 (2) (90 cm rows)
20
Timothy
Meadow fescue
Legumes
Alfalfa
Sweetclover
Birdsfoot trefoil
Sainfoin
Red clover
5-6 (5) 5-6 (5) 5-6 (5) (15-18 cm rows)
(15-18 cm rows)
Not recommended Not recommended 8 (7)
6.8 (5-7)
11 (10)
Not recommended
22-45 (20-40)
Not recommended
Grass-legume mixtures
Bromegrass-alfalfa
Crested wheatgrass-alfalfa
Intermediate
wheatgrass-alfalfa
Reed canary-alsike clover
Meadow bromegrass-alfalfa
Timothy-alsike clover*
9
8
14
2-4
2-4
Not recommended
U (10)
4.5 (4)
22-45 (20-40)
Not recommended
1-2 (1-2) (909 cm rows)
6-7 (5-6)
4.5 (4)
11 (10) (60-90 cm rows)
4.5 (4)
(8
(7
+ 2-4)
+ 2-4)
2-4 (12 + 2-4)
+ 2 (6 + 2)
10-3
+ 3 (2 + 3)
9 + 2-4 (8 + 1-2) n/a
8 + 2-4 (7 + 2-4) n/a
14 + 2-4 (12 + 1-2) n/a
7 + 2 (6 + 2) n/a
10-2 n/a
2 + 3 (2 + 3) n/a
*Recommended in hay and pasture mixtures on moist, non-saline, non-alkaline,
acidic soils
COMPANION CROPS FOR ESTABLISHING PERENNIAL FORAGES
A companion crop, sometimes misleadingly called a nurse crop, is often
sown with forage. A companion crop provides grazing, hay or grain in the
year of forage establishment, protects the land against wind and water
erosion to some extent, and offers some protection to the forage seedlings
against extreme weather. Annual cereal stubble will also have the added
benefit of trapping snow, both for water and for insulation during winter.
On the other hand, companion crops compete with the forage seedlings for
water, light, and nutrients, and make weed control more difficult because
suitable herbicides for the combination of companion crop and forage are
often not available.
Flax is considered to be the least competitive annual companion crop,
followed by spring wheat, barley and oats in that order. Flax is sometimes
not competitive enough: green growth in the swath can be a problem if the
flax is seeded with a very vigorous forage such as sweetclover. Annual
cereals can be used for pasture, hay, or allowed to mature, depending on the
grower's requirements and judgment of his changing needs as the growing
season progresses. The advice that cereals be seeded at half the usual rate
is recognition that companion crops compete with forage seedlings, to the
detriment of the forages. Recently canola (rapeseed) has been used as a
companion crop with some success. Between 1972 and 1986, several experiments
21
were conducted in the Melfort and Tisdale areas on the effects of wheat and
canola on underseeded forages.
WHEAT
At Melfort, a harvestable amount of brome or alfalfa was obtained in the
seedling year when they were clear-seeded on fallow. When they were
underseeded in wheat, there was little growth in the seedling year, and
yields were reduced by about one-third in the following year (Table 5).
Thereafter, alfalfa produced about the same, whether seeded with or without
wheat, but bromegrass yield showed a rebound effect. Areas seeded with wheat
produced more hay after the first harvest year than areas clear-seeded.
Weeds were not a major component in either forage. Wheat produced about 2900
kg/ha whether seeded at 50 or 100 kg/ha, and seeding rate had little effect
on forage establishment. In the Tisdale and Choiceland areas, applications
of nitrogen in amounts based on soil testing, increased wheat yields but
depressed alfalfa hay yields the year after seeding (Table 6). Phosphorus
also increased wheat yields but had very little effect on the alfalfa.
CANOLA
Both canola species showed effects similar to wheat on underseeded
forages (Tables 7 and 8). Volunteer canola was a major problem with the
Polish varieties. Control using 2,4-D on grasses or 2,4-DB on legumes is
effective but represents an added cost. Russian wild ryegrass established
poorly under Polish canola. Sweetclover seemed quite compatible with Polish
canola. Normal seeding rates for both crops were satisfactory (Table 9).
There are two major considerations when deciding whether to use a
companion crop when establishing forages. First, is the gain in companion
crop greater than the loss in forage? Second, is a big yield the year after
seeding preferable to a more uniform but lower productivity over several
years? The big yield the year after seeding is largely a result of seeding
on fallow, and is not as evident following seeding on stubble. Reducing the
seeding rates of either wheat or rapeseed did not have much effect on the
underseeded forages when compared with the major reduction of growth from
using a companion crop. Taken together, tests show that establishment of the
commonly-used forages, bromegrass and alfalfa, will be satisfactory most
years whether a companion crop is used or not. Individual circumstances
should dictate which option to use.
22
Table 5. Forage Crop Yields (3-yr average, kg/ha) After Establishment with
a Wheat Companion Crop
Forage Crop
Year from Seeding
With/Without
Companion Seedling Yr. First Year Second Year Third Year
Crop (one cut) (two cuts) (two cuts) (one cut)
Alfalfa
without
1969
7650
5456
3262
with
112
4781
5344
3206
Bromegrass
without
2756
8325
5175
2756
with
225
4894
5962
3600
Weed X in
without
17
9
12
26
alfalfa
with
10
15
13
24
Veed X in
without
7
2
1
8
bromegrass
with
3
3
0
3
Source: J. Waddington
Table 6. Yields After Seeding With a Wheat Companion Crop Fertilized With
Nitrogen (average of five tests)
Alfalfa Yields
(kg/ha)
Nitrogen rate
on wheat
kg/ ha
First Year
after seeding
Second Year
after seeding
Third Year
after seeding
(average of 4 tests)
0
62
113
4556
3600
3544
4669
4275
4500
4219
4050
4163
Source: S. Bittman
D.A. Pulkinen
23
Table 7. Forage Crop Yields (3-yr average, kg/ha) After Establishment With
an Argentine Canola Companion Crop.
Forage Crop
With/Without
Companion Seedling Yr
Crop (one cut)
Year after seeding
First Year
Se
cond Year
Third Year
(two cuts)
(t
wo cuts)
(one cut)
7031
4894
3488
4275
4275
3488
9113
5343
3825
5006
5119
4331
6
11
14
34
15
16
0
0
3
1
1
1
Alfalfa
Bromegrass
Weed X in
Alfalfa
Weed X in
Bromegrass
v:
w:
wi
vi
v:
v:
thout
th
thout
th
thout
th
without
with
956
56
2025
225
18
20
11
3
Source: J. Waddington
Table 8. Forage Crop Yields (3-yr average, kg/ha) After Establishment With a
Polish Canola Companion Crop.
Forage Crop
With/Without
Seedling Year
First Year
X
Weeds in
Companion
Crop
(one cut)
(one cut)
First Year
without
2306
5175
2
with
169
2588
39
without
3319
6525
2
with
394
3769
3
without
2588
4613
10
with
281
2475
51
without
450
2869
28
with
56
1688
65
Alfalfa
Bromegrass
Sainfoin
Russian Wild
Rye
Source: J. Waddington
24
Table 9. Sweetclover Dry Matter Yields (3-yr average, kg/ha) After
Establishment With a Polish Canola Companion Crop.
Rapeseed seeding Sveetclover seeding rate (kg/ha)
Rate (kg/ha) 1 4 7 10
3 3094 3600 3713 3825
5 2588 3319 3431 4050
7 1744 2700 3375 3938
Source: J. Waddington
PERSISTENCE OF ALFALFA VARIETIES WHEN GROWN WITH SMOOTH BROMEGRASS
Most of the alfalfa on the prairies used for hay or pasture is grown in
mixture with a grass (to reduce the hazard of bloat, to facilitate field
drying when harvesting as hay, to improve the feeding value of the grass, and
to reduce losses should alfalfa winterkill). Based on variety tests at
Melfort and elsewhere on the prairies, the varieties recommended in
Saskatchewan include Beaver, Rambler, Rangelander, Algonquin, Anchor, and
more recently, Heinrichs. However, an apparent contradiction exists between
results of variety tests and the experience of producers, pasture managers,
and pasture specialists. Whereas most recommended varieties usually survive
well year after year in variety tests, these varieties when grown with
grasses, diminish and often disappear in farmers' hay fields and pastures.
Under test conditions in northeast Saskatchewan two harvests of alfalfa can
be taken safely each year, yet local producers very often take only one
harvest for fear of losing the stand.
An experiment was established in 1980 on gray-wooded soil near Melfort
to compare alfalfa varieties under conditions which closely resemble those on
farms, implementing the following variations from conventional variety
tests:
a) Both low and high levels of P maintained.
b) Both simulated pasture and hay cutting managements were used.
c) All varieties were grown in mixture with smooth bromegrass.
Plots were harvested in 1981 but yields were not determined. In 1982,
the strain SCMF3713 yielded less than other varieties. In 1983, yield of all
varieties was similar. However, in 1984-1986 SCMF3713 yielded significantly
more than all other varieties tested. In 1984-1986, Beaver was the lowest
yielding variety. Phosphorus level and cutting management affected yield,
but not the relative performance of the varieties.
25
Table 10. Yield of Alfalfa Strains Grown in Mixed Swards with Smooth
Bromegrass at Melfort, Saskatchewan. Values are means of four management
systems.
Yield
1981*
1982
1983 1984
1985
1986
kg/ha
Beaver
1083
1916 409
276
584
Rambler
1005
1963 679
561
1249
Peace
1246
2208 609
507
1104
Drylander
845
2136 624
607
1260
Rangelander
1027
1926 626
602
1123
SCMF3713
731
1868 1109
1012
1910
*1981 plots harvested
but
yields
not
recorded.
Sou
rce: S.
Bittman
The results (Table 10) show that for long-term hay and pasture stands,
alfalfa varieties should be evaluated in combination with the grass(es) with
which they are to be grown in practice.
A COMPARISON OF GRASS SPECIES FOR HAY PRODUCTION ON TWO SOIL TYPES IN THE
ASPEN PARKBELT
Twenty grass species were compared over a seven year period on a deep
black soil (Melfort silty clay) and thirteen species over a six year period
on a gray-wooded soil (Waitville loam). Plots were fertilized annually with
90 kg N and 22 kg P/ha. Plots were harvested in late June-early July and
during the third week in September.
Several species had substantial loss of stand over the course of the
experiment due to winterkill and other factors (orchard grass, meadow fescue,
tall fescue, reed canary grass, tall wheatgrass, slender wheatgrass). Other
species had consistently low yields (timothy, creeping red fescue, hard
fescue, Kentucky bluegrass, meadow foxtail). Altai wild rye was particularly
prone to invasion by weeds. The performance of the best species is
summarized in Table 11).
26
Table 11. Average Yield of Grass Species Under Hay Management on Two Soil
Types in the Aspen Parkbelt. (kg DM/ha)
Black Soil Gray-wooded Soil
Species (1980-1986) (1981-1986)
Crested wheatgrass 7957 2684
Intermediate wheatgrass 7166 2192
Smooth bromegrass 7619 2457
Meadow bromegrass 6251 2581
Russian wildrye 6658
Green stipa (needle grass) 6069 2220
Source: S. Bittman
In the first year of seeding, Russian wildrye and green stipa yielded
much less than the other species due to poor vigor. Intermediate and crested
wheatgrass have the most vigorous seedlings followed by smooth and meadow
bromegrasses. Species with poor seedling vigor require better control of
weeds, should not be seeded with a companion crop and require up to two years
to provide a usable stand.
A COMPARISON OF REED CANARY GRASS AND TIMOTHY
New, low-alkaloid varieties of reed canarygrass and the good seasonal
production curve of this species has prompted increased interest in reed
canarygrass for both hay and pasture. Because both reed canarygrass and
timothy produce best under favorable moisture conditions, three low alkaloid
varieties of reed canarygrass were compared to timothy when harvested at
comparable stages of maturity and fed to 23 kg lambs for a six week period.
The results are summarized in Table 12.
27
Table 12. Chemical Analyses and Feeding Value of Three Varieties of Reed
Canarygrass and Timothy (three year average)
Species:
Variety: Frontier*
Reed Canarygrass
Rival
Timothy
Venture Champ
Heading to Early Anthesis
Dry matter at harvest (%)
Crude protein (%)
Acid detergent fibre (%)
Dry matter intake (g/day)
Dry matter digestibility (%)
Digestibility of crude protein (%)
Regrovth (5-6 leaf stage)
Dry matter at harvest (%)
Crude protein (%)
Acid detergent fibre (X)
Dry matter intake (g/day)
Dry matter digestibility (%)
Digestibility of crude protein (%)
24
21
28
27
17
19
16
13
37
35
37
37
659
710
746
662
58
60
59
62
74
73
77
70
20
20
22
24
14
19
18
12
42
37
38
41
613
642
616
644
54
61
55
59
73
76
73
64
*A high alkaloid variety.
Adapted from Dr. K. Wittenberg, University of Manitoba, Manitoba
Intake and digestibility of the reed canarygrass varieties were similar
to those of Champ timothy when harvested at comparable stages of maturity and
fed to lambs. Crude protein levels were higher for reed canarygrass
varieties than for timothy. Palatability of reed canarygrass was equal to
that of timothy when there was no choice. Rival was the variety of choice.
Under dry conditions gramine (an alkaloid) levels rose to levels that
caused reduced animal performance (concentrations above 2 mg/kg of D.M.
appear to adversely affect intake).
GROWING ALFALFA FOR THE DEHYDRATING INDUSTRY
In 1984, there were 23 alfalfa dehydrating plants in Western Canada with
a capacity of approximately 400,000 tonnes. Currently, the total annual
production for Western Canada is estimated at 600,000 tonnes, with five of
the plants located in North East Saskatchewan. Export markets are the major
source of product demand as approximately 75 percent of Canada's total
processed alfalfa is exported. While Japan is the main customer, other
28
markets have started to have some significance to the industry.
The domestic market has stabilized somewhat, but having a larger
domestic market would add to the stability and flexibility of the processing
industry as a whole.
In the Parkbelt area of Western Canada, alfalfa is grown on nonirrigated
land. Yields of 3.5 to 5.5 tonnes of dry matter/ha are usual, depending on
rainfall, age of stand, number of cuts, variety, management and other
factors. Unfortunately, wide fluctuations in yield and quality occur between
fields and from year to year, making management of fields and the dehy plant
extremely difficult.
For those planning to produce alfalfa for sale to a dehydrating plant,
the following suggestions are presented for consideration.
SEED
Always select pedigreed seed of the recommended varieties. Beaver and
Algonquin appear to be the superior varieties as they provide the best
balance between yield and quality. Algonquin may yield slightly better than
Beaver and is of comparable quality. Many of the other varieties, including
Anchor and Alouette, are high yielding but lower in quality. The
creeping-rooted varieties are unsatisfactory because they tend to be high in
fiber and regrowth is slow.
LAND PREPARATION
Use only fields free from perennial and hard-to-kill annual weeds to
produce alfalfa for dehy. Excess trash or stubble may be removed by burning
in the spring, provided the burning is done early enough to prevent damage to
the alfalfa crowns. This is usually in late April when the ground in still
wet and the stubble or trash dry enough to carry a fire.
Obtain a soil test to determine the amount and kind of nutrients that
the alfalfa will require. Follow provincial recommendation guide for
nutrient application times and rates. Nitrogen fertilizer is generally not
required because alfalfa is capable of hosting nitrogen-fixing bacteria on
its roots.
HARVEST
In northeastern Saskatchewan research has shown that if a stand is
harvested three times per season for two consecutive years, it may not
produce a satisfactory yield the following year. If possible, allow stands
that have been harvested three times to recoup by letting them reach 20-50%
bloom before being harvested the following year. Conversely, fields that
29
were harvested only once (sun-cured) will likely provide the hest stands for
two or three cuts of dehy the next season.
Cutting height affects regrowth and persistence. Take the first cut as
low as possible, especially in dense stands, because shading accelerates
senescence. However, for the second and third cuts, it is suggested that
cutting high enough to leave some green leaves on the stubble will enhance
quality and persistence by leaving some photosynthetic area to support
regrowth thereby lessening the drain on root reserves.
WEED CONTROL IN FORAGE CROPS
TOLERANCE OF SEEDLING FORAGE GRASSES TO HERBICIDES
'Fairway' crested wheatgrass, 'Magna' smooth bromegrass, 'Regar' meadow
bromegrass, 'Prairie' altai wild ryegrass and 'Climax' timothy were seeded,
along with separate rows of wild oats and green foxtail, into Melfort silty
clay loam on May 28, 1986. Because of lack of soil moisture, crop
establishment was slow and erratic until mid July when adequate rainfall was
received. Fourteen herbicide treatments (including four numbered herbicides)
were applied on July 16, 1986 across the grass strips in each of the 4
replicates. The herbicides were applied in 125 L/ha of water at 275 kPa with
a tractor-mounted shielded sprayer. The forage grasses were in the 2-5 leaf
stage at time of herbicide application.
At recommended rates MCPA + mecoprop + dicamba formulation was safe on
all forage grasses at the 2-5 leaf stage. The mixture provided satisfactory
control of lambs' -quarters and redroot pigweed. Sethoxydim completely killed
timothy and severely injured crested wheatgrass, smooth brome and meadow
brome. Altai wildrye was also affected slightly. Addition of bentazon
improved the selectivity of sethoxydim on the forage grasses but
significantly reduced its efficacy on wild oats. Bentazon applied alone was
safe on all forage grasses and provided excellent control of the annual
broadleaf weeds. Timothy was not as tolerant as the other forage grasses to
chlorsulfuron. All forage grasses were tolerant to both rates of
metsulfuron-methyl. The three sulfonylurea herbicides provided excellent
control of the annual broadleaf weeds but were ineffective against the annual
grass weeds (See Table 13).
With the exception of timothy, the tank-mixed formulation of
dichlofop-methyl + bromoxynil was safe on all forage grasses. However,
addition of bromoxynil drastically reduced the effectiveness of
dichlofop-methyl against the annual grass weeds (See Table 13).
30
ciicaa \j l neiuKJ
nes
tor w«
?ea u
>ntroi
in c
•rasses
Rate
kg a.i./ha
Crop
(Aug.
Tolerance
20, 1986)
Veed
(Aug.
GF V0
Contrc
22, 19
LQ
1
86)
Treatments
CVG
TIM
AWG
MB
SB
RRP
MCPA/Mecop/Dicamba
MCPA/Mecop/Dicamba
.275/. 062/. 062
.412/. 094/. 094
9
8
8
8
8
7.5
8
8
8
8
0.5
2
0
0
9
9
8
9
Sethoxydim + Assist
Sethoyxdim + Assist
.250 + IX
.250 + IX
3
0
6
4
3.5
9
9
0
0
+ Bentazon
+ 1.08
5
1
8
7
8
8
4
9
9
Bentazon + Assist
1.08 + 5%
9
8
8
8
8
1
0
9
9
Chlorsulfuron
Chlorsulfuron
.01
.02
9
8.5
7
6
8
7
8
8
7.5
8
2
3
0
0.5
9
9
9
9
Metsul. methyl
Metsul. methyl
.003
.0045
9
9
8
8
8
8
8.5
8
8.5
8
2.5
1
2
1
8
8.5
9
9
Dichlofop-Methyl
+ Bromoxynil
.70
.30
8
5
8
8
7.5
3
1
9
9
Check
-
9
8.5
8
8
8
0
0
0
0
LSD (5%)
1.5
1.5
1.5
1
1
1.5
1.5
0.5
0.5
CVG = crested vheatgrass, TIM = timothy, AVG = Altai wild ryegrass, MB = meadow
brome, SM = smooth brome, GF = green foxtail, V0 = wild oats,
LQ = lamb's-quarters, RRP = redroot pigweed.
- Crop tolerance ratings (0-9), where 9 = no effect, 0 = complete kill.
- Veed control ratings (0-9), where 0 = no control, 9 = complete control.
Source: N. Malik, Melfort Research Station
VEED CONTROL IN SEEDLING FORAGE LEGUMES
Beaver alfalfa, Altaswede red clover and Norgold sweetclover were
planted in strips 3 m wide into a silty clay loam (O.M. = 11£) on May 27,
1986. Vild oats and green foxtail were sown in 1 m strips between the crops.
Infestations of barnyard grass, redroot pigweed and stinkweed were present in
the plot. EPTC and ethalf luralin 5G were applied pre-plant and incorporated
to a depth of 7 cm with a rotovator on May 20. A second incorporation of
ethalf luralin was done 4 days later. Sethoxydim was applied post-emergence
when the grass weeds were in the 1- to 6-leaf stage. Establishment of the
three legumes was successful, and by late August their growth was
exceptionally vigorous (Table 14).
31
Table 14. Effectiveness of Herbicides for Weed Control in Seedling Legume
Crops. (Scoring range 0 to 9).
Crop Vigor
Weed
Control
Rate
(kg a. i ./ha)
(Aug. 1/86)
Alf RC SC
(Aug. 1/86)
Herbicide
WO
GF
BG
SW
RRP
EPTC
3.6
8.8
8.5
8.2
6.2
8.0
8.0
4.0
6.0
EPTC
4.4
8.2
8.0
8.2
8.0
8.5
9.0
3.5
7.5
EPTC
8.8
7.2*
5.6*
6.8*
8.8
9.0
9.0
5.2
8.5
Ethalfluralin
5G
1.1
9.0
8.8
9.0
7.6
6.4
8.3
2.0
7.8
Ethalfluralin
5G
2.2
8.5
8.5
8.5
8.5
9.0
9.0
5.2
9.0
Sethoxydim
0.25 + IX
8.8
8.5
8.5
9.0
9.0
9.0
0.0
0.0
+ Assist
Sethoxydim
0.80 + 2%
8.6
9.0
9.0
9.0
9.0
9.0
0.0
0.0
+ Assist
Check
-
8.8
8.8
8.2
0.0
0.0
0.0
0.0
0.0
LSD (0.05)
\
0.9
1.0
0.9
1.8
2.3
1.7
3.1
2.6
Alf = alfalfa, RC = red clover, SC = sweet clover, W0 = wild oats, GF = green
foxtail, BG = barnyard grass, SW = stinkweed, RRP = redroot pigweed
*Values significantly different from check (P < 0.05)
Source: N. Malik - Melfort Research Station
Table 15. Effect
of Severa
1 Herbic:
ide Treatments on
Forage
Dry Matter
Yield.
Rate
(kg
Forage
Dry Matter Yield
(kg/ha)
Red
Sweet
Herbicide
a. i ./ha)
Alfalfa
Weeds
clover
Weeds
clover
Weeds
EPTC
3.6
4218
637
2625
1206
5176
648
EPTC
4.4
3910
692
2653
449
4945
950
EPTC
8.8
4028
397
2062
480
4719
402
Ethalfluralin
5G
1.1
4842
288
2774
1255
5378
1117
Ethalfluralin
5G
2.2
4481
247
3054
145
6092
451
AC 263 499
0.037
3969
443
2878
187
6423
924
AC 263 499
0.075
3867
426
2827
308
5766
234
AC 263 499
0.150
3964
200
2774
472
6056
629
Hoe 33171
0.25
4374
634
2627
1422
4718
1396
Sethoxydim
+ Assist
0.25
+ IX
4096
573
2437
931
5156
1907
Sethoxydim
+ Assist
0.80
+ 2X
4475
129
3096
796
5391
750
Check
4322
476
2778
925
4790
801
LSD (0.05)
898
939
1386
Source: N. Malik - Melfort Research Station
32
The seedling legumes were tolerant" to applications of F.PTC up to 4.4
kg/ha. At the 8.8 kg/ha rate, emergence of alfalfa and red clover was
delayed for a few days and some injury was observed on red clover and sweet
clover. Control of the annual grass weeds was satisfactory at 4.4 kg/ha.
The seedling legumes were tolerant to both rates of ethalf luralin tested and
excellent control of the grass weeds and pigweed was obtained at 2.2 kg/ha.
Sethoydim was safe on all three legumes even at the 0.8 kg/ha rate and
excellent control of the grass weeds was observed at both rates tested.
The legumes were harvested on August 28, 1986 and weeds were
hand-separated from the samples. Alfalfa and red clover forage dry matter
yield differences were not significantly better than the check. In general,
the total dry matter yield of broadleaf and grass weeds associated with
alfalfa was less than those found in red clover and sweetclover samples.
WEED CONTROL IN FORAGE SEED CROPS
Alfalfa
Weeds are often a major problem in the production of alfalfa seed. Weed
control is essential for successful establishment of alfalfa because the
seedlings are not vigorous in the early stages of growth and offer little
competition to aggressive weeds. In northeastern Saskatchewan, annual
broadleaf weeds such as stinkweed, wild mustard, Shepherd's purse, cleavers,
volunteer canola and annual grass weeds such as wild oats, green foxtail and
volunteer cereals compete with alfalfa seedlings during the establishment
year. In established stands, weeds also present a serious threat and may
result in lower seed yields and lower grade due to weed seed contamination.
Established stands are often invaded by dandelion, Canada thistle, perennial
sow thistle, perennial grasses and the biennial narrow-leaved hawk's beard.
Weed competition
The effect of weed competition on alfalfa seed production has not been
measured directly, but yield increases of 30 or more have been obtained at
Melfort where terbacil (SINBAR) was used at the start of each growing season
for three years. Applications of metribuzin (SENCOR) at the start of each
season for four years controlled dandelion and increased seed yield by 68%.
Results of the Agro-Man Project in Manitoba showed that applications of
fluazifop (FUSILADE), sethoxydim (POAST) and haloxifop (VERDICT) for
suppression of quackgrass resulted in 75-109% increases in alfalfa seed yield
in test sites where quackgrass density ranged from 546 to 1032 culms/m .
Weeds can reduce alfalfa seed yields beyond their competitive effect if their
floral parts offer better attraction to leafcutter bees than the alfalfa
flowers or if the weeds smother the crop and the alfalfa flowers become less
visible to the pollinators.
-Common names of herbicides are followed by trade names in brackets.
Research results referring to unregistered (on alfalfa) or experimental
herbicides do not constitute recommendations.
33
Companion crops
Seedling alfalfa is most resistant to post-emergence applications of
herbicides from the first to third trifoliate leaf stage. Seedlings should
not be sprayed after reaching 10 cm (4") in height. Use relatively large
volumes of water and low pressures for spray treatments. A good canopy
formed by the companion crop (if used) and weeds will reduce the risk of
injury.
Herbicides used in forages underseeded to companion crops must be safe
on both crops. Use a registered herbicide to control annual grass weeds in
companion crops. There are at least eight registered herbicides that can be
used in seedling alfalfa (Table 16). There are few registered herbicides for
control of broadleaf weeds in companion crops. For instance, if alfalfa is
underseeded to canola, there is no registered herbicide for control of
stinkweed, wild mustard, flixweed and shepherd's purse.
EMBUT0X/C0BUT0X/BUTYRIC 400 is registered for use in alfalfa but these
products cannot be used on canola. At Melfort it has been found that TREFLAN
and the trifluralin analog, ethalfluralin (EDGE), can be used at the
recommended rate on seedling alfalfa or alfalfa underseeded to canola.
TREFLAN was recently registered for stand establishment of alfalfa under the
"Minor Use of Pesticides Program". Also if alfalfa is underseeded to flax,
trifluralin (TREFLAN, RIVAL) can be used for control of annual grassy and
broadleaf weeds. If alfalfa is underseeded to cereals, the farmer has a
somewhat greater choice of broadleaf herbicides to choose from (See Table
17).
Table 16. Registered Herbicides for Alfalfa
Seedling
Established
Annual Grass Weeds Only
Avadex BW
X
Avenge 200C
X
Basfapon/Dowpon
X
Hoe-Grass
X
Mataven
X
Annual + Perennial Grasses
Kerb 50-W
X
Broadleaf + Grass Weeds
Eptam 8E
X
Princep
X
Sinbar
X
Treflan
X
Velpar
X
Broadleaf Weed Only
Embutox/Cobut ox/Butyric
400 X
X
34
Table 17. Registered Herbicides For Seedling Alfalfa and
Companion Crop
Companion Crops
Wheat Barley Canola
Flax
For Annual Grass Weeds
Avadex BW
Avenge 200C
Basfapon/Dowpon
Hoe-Grass
Mataven
X
X
X
X
X
X
X
X
X
Broadleaf + Grass Weeds
Treflan
X
Broadleaf Weeds Only
Embutox
X
X
For details on range of weeds controlled by registered herbicides and
rates of application, the reader is referred to the most recent publication
of "Chemical Weed Control in Cereal, Oilseed, Pulse and Forage Crops",
published annually by Saskatchewan Agriculture.
RESIDUAL HERBICIDES IN ESTABLISHED ALFALFA FOR SEED
Beaver alfalfa was sown in rows, 30 cm apart, into Melfort silty clay
loam soil on May 22, 1985. Half of the plots were designated for fall
applications, and the other half for spring applications. The fall
applications were made on October 22, 1985 after the crop had been mowed down
to 10 cm and a chilling frost had been experienced. The treatments were
applied with a tractor-mounted shielded sprayer at a volume of 125 L/ha of
water and a pressure of 275 kPa. The spring applications were made on
April 25 when alfalfa was just beginning active growth. Crop tolerance and
weed control ratings recorded on June 3, 1986 are compared in paired columns
for the fall 1985 and spring 1986 applications (Table 18).
35
Table 18.
Crop
Vigor
Weed
Control
(June
3, 86)
Rate
(June
3/86)
Dandelion
Stin
kweed
Herbicides
kg a. i . /ha
Fall
Spring
Fall
Spring
Fall
Spring
Hexazinone
0.5
8.3
8. A
2.3
7.1
8.7
8.5
Hexazinone
1.0
8. A
8.1
3.2
7.2
9.0
8. A
Chlorsulfuron
0.011
8.9
7.8
9.0
8.8
9.0
8.1
Chlorsulfuron
0.022
8.5
6.2*
9.0
9.0
6.8
9.0
Mets. methyl
0.01
6.8*
A.0*
9.0
9.0
9.0
9.0
Mets. methyl
0.02
3.0*
1.8*
9.0
9.0
9.0
9.0
Metribuzin
0.5
8.4
8.8
A. 5
6.6
8.6
8.1
Metribuzin
1.0
8.2
8.2
A. 3
7. A
9.0
9.0
Check
8.9
8.0
0.0
0.0
0.0
0.0
LSD (0.05)
Significance of season
of applicaton
0.9
1.1
2.0
1.2
1.9
NS
0.7
*Values significantly different from check (P < 0.05)
Crop tolerance ratings (0-9) where 0 = no effect, 9 = complete kill.
Weed control ratings (0-9) where 0 = no control, 9 = complete control.
In general, alfalfa was more tolerant to fall than to spring
applications of the residual herbicides. The differences in crop vigor due
to spring and fall applications of hexazinone (VELPAR), and metribuzin
(SENC0R) were not significant. Alfalfa was tolerant to fall applications of
chlorsulfuron (GLEAN), however, the crop was injured with the spring
application at 0.022 kg/ha. Spring as well as fall applications of
metsulfuron-methyl (ALLY) resulted in crop injury. The injurious effect of
the spring applications was more severe and resulted in stunting, delayed
maturity and delayed flowering. In general, the spring applications resulted
in better control of dandelion. Both spring and fall applications of
chlorsulfuron and metsulfuron-methyl were equally effective, completely
controlling dandelion and were superior to most other herbicides. Control of
dandelion was poor with the fall applications of hexazinone, DPX M6316 and
metribuzin and fair with the spring applications. Satisfactory control of
dandelion was achieved with the spring applications of AC 263 A99. Fall as
well as spring applications of the various herbicides were equally effective
in controlling stinkweed. DPX M6316 was inferior to all other herbicides
tested in controlling stinkweed.
36
FXPF.RTMF.NTAI. AND UNRF.GTSTF.RED HFRBTCTDES
A large number of herbicides have been tested on seedling and
established legumes, in particular alfalfa, in western Canada. Some of these
herbicides are already in use in other major crops but are not registered for
use in forage legumes. Others are completely new herbicides that are still
under research and development. Efficacy, selectivity, toxicology,
environmental fate and environmental impact studies may still be in progress
for these chemicals. One of the promising herbicides that has shown
excellent selectivity in seedling alfalfa and established alfalfa, and a
large number of other forage legumes is imazethapyr (PURSUIT). In Canada,
the Expert Committee on Weeds (ECW) is responsible for compiling and
documenting research data generated by federal and provincial research
establishments, universities, producer groups and the agrichemical industry.
Applications currently under review by Agriculture Canada include
ethalfluralin (EDGE 50 DF) for stand establishment of alfalfa, bentazon
(BASAGRAN) for seedling alfalfa and spot applications in established alfalfa,
metribuzin (SENCOR 75 DF) and hexazinone (VELPAR) for dormant established
alfalfa grown for forage or seed production. Producers should keep abreast
of developments in registering herbicides for use in forage crops and use
only those registered for the purpose desired.
Seedling clovers and sweetclover
Control of annual grass weeds is not a problem in clovers. For
broadleaf weed control, however, there are no herbicides registered for
sweetclover as indicated in Table 19.
Table 19. Registered Herbicides for Seedling Clovers
Alsike
Red
Sweet
White
Clover
Clover
Clover
Clover
Annual Grass Weeds Only
Avadex BW
X
X
X
X
Avenge 200C
X
X
Hoe-Grass
X
X
Mataven
X
Broadleaf Weeds Only
Embutox/Cobutox/Butyric 400 XX X
Tropotox Plus XX X
Research at Melfort (silty clay loam, 0.M.=11%) on soil-incorporated
herbicides, triflualin (1.1-2.2 kg/ha) , ethalfluralin (1.1-2.2 kg/ha) an(
EPTC (3.6-4.4 kg/ha) from 1983 to 1987 demonstrated that seedling clovers
37
were tolerant to these herbicides. Seedling red clover and sweetclover were
also tolerant to imazethapyr (PURSUIT) at the rate of 0.075 kg/ha, adequate
for control of stinkweed, shepherd's-purse, wild mustard, flixweed and
pigweed. Research in Alberta has demonstrated that alsike clover and white
clover are also tolerant to imazethapyr. Bentazon (BASAGRAN) tested at 1.08
kg/ha caused slight injury to red clover and severe injury to sweetclover,
however, forage dry matter yields obtained the following year indicated that
the legumes had recovered successfully. Diclofop/bromoxynil (HOE-GRASS II)
tested at 1.08 kg/ha injured red clover and killed sweetclover. Forage dry
matter yields obtained the following year indicated that red clover had
recovered. Post-emergence applications of metribuzin (SENCOR) at 0.15 kg/ha
severely injured seedling red clover and sweetclover, however, no adverse
affect on forage yield was observed the following year. Since these tests
were intended for forage production, we do not know the effects of herbicide
injury, sustained by clovers in the seedling stage, on seed production in the
following year. Research is still needed to determine residue levels if any,
in the crop.
Seedling Birdsfoot trefoil
At Melfort it was demonstrated that seedling trefoil was tolerant to
trifluralin (1.1 kg/ha), ethalf luralin (1.1-2.2 kg/ha), trifluralin +
triallate (0.84+1.4), EPTC (3.3-6.7 kg/ha) and sethoxydim (P0AST) tested at
0.35-0.80 kg/ha. Trefoil was injured at 2.2 kg/ha rate of trifluralin.
Trefoil was severely injured by bentazon and propanil (STAMPEDE 360) tested
at 1.0 kg/ha, and sustained moderate injury from 2,4-DB (1.08 kg/ha)
treatment. Forage dry matter yield obtained the following year indicated
that trefoil had successfully recovered from the initial injurious affects of
the postemergence treatments. Research in Alberta has demonstrated that
trefoil is also tolerant to imazethapyr.
FORAGE GRASSES GROWN FOR SEED
TOLERANCE OF SEEDLING GRASSES TO HERBICIDES
Grass seed producers have a choice of three herbicides (AVENGE 200C,
HOE-GRASS, MATAVEN) for control of annual grass weeds and four herbicides
(BUCTRIL-M, MCPA, PARDNER/TORCH DS, 2,4-D amine) for control of broadleaf
weeds. For Kentucky bluegrass, AVENGE 200C is the only registered product,
Research at Melfort during 1985-1987 has demonstrated that
MCPA/mecoprop/dicamba (TARGET) and bentazon were safe on seedling crested
wheatgrass, timothy, Altai wild ryegrass, meadow bromegrass and smooth
bromegrass. All five species exhibited tolerance to chlorsulfuron (GLEAN)
tested at 10 g/ha but timothy was slightly injured at 20 g/ha. All forage
grasses exhibited tolerance to metsulfuron (ALLY) tested at 3 and 4.5 g/ha.
3
All rates are in kg of active ingredient per ha.
38
Only timothy was not tolerant to DPX M6316 (HARMONY) tested at 15 and 30
g/lia. Sethoxydim (POAST) tested at 0.25 kg/ha killed timothy and severely
injured the other grasses. Forage dry matter yields obtained the following
year indicated that crested wheatgrass, meadow bromegrass and smooth
bromegrass had partially recovered. Fenoxaprop (EXCEL) tested at 0.18 kg/ha
killed timothy and severely injured crested wheatgrass, but was safe on other
forage grasses. Addition of 2,4-D amine improved the selectivity of
fenoxaprop on crested wheat but not on timothy. Addition of 2,4-D amine did
not decrease the efficacy of fenoxaprop against green foxtail and wild oats.
With the exception of timothy, diclofop/bromoxynil (HOE-GRASS II) was safe on
all forage grasses. However, addition of bromoxynil reduced the
effectiveness of diclofop against the annual grass weeds.
EFFECTS OF GRAMINICIDES ON SEED PRODUCTION
The effects of difenzoquat (AVENGE 200C), diclofop (HOE-GRASS), flamprop
(MATAVEN), propanil (STAMPEDE 360) and dichlobenil (CASORAN), applied at the
recommended and twice the recommended rates each spring 1979-81 at Melfort,
were studied on seed production of established bromegrass, crested wheatgrass
and timothy (Waddington 1982). There were no grass weeds present at the
experimental site. The grasses were swathed at the soft-dough stage, and
threshed when mature. The 3-year average seed yield of bromegrass and
crested wheat in the untreated plots were, respectively, 190 and 282 kg/ha.
The 2-year average seed yield of timothy for the check plots was 159 kg/ha.
Seed yields were very low in 1980 because a very dry spring reduced the
number of seed heads.
Crested wheatgrass showed no visible signs of herbicide damage during
the growing period in any year. Bromegrass treated with diclofop in 1979
lodged in a windstorm two days before swathing; the other treatments showed
no lodging. No evidence of weakened straw appeared in later years. The
higher rates of diclofop and flamprop reduced the number of timothy heads and
also delayed their emergence and maturity in both years. The stand was
thinned and dandelions invaded the plots. Propanil caused the same effect
only in 1980.
Overall, seed yields either were not affected or were reduced by
applications of herbicides. Flamprop at 1.0 kg/ha reduced seed yields of
timothy in both years, and reduced bromegrass and crested wheatgrass yields
in 1980, a year with a very dry spring. Diclofop and flamprop at both rates
reduced timothy seed yield in 1981. This effect was probably in part a
cumulative one resulting from stand thinning in 1980 and damage to the
surviving plants in 1981. Difenzoquat had the least effect over the course
of the experiment.
EFFECTS OF BROADLEAF HERBICIDES ON ESTABLISHED GRASSES
The effects of 2,4-d, tested at 0.5 and 1.0 kg/ha in the autumn, before
39
stem elongation in spring and at shot blade stage, were determined on seed
production of established bromegrass (Carlton) at Beaverlodge Research
Station (Darwent 1985). The mean seed yield for the untreated plots for the
period 1983-1985 was 438 kg/ha. At the 0.5 kg/ha rate of 2,4-D, seed yields
were not affected by any of the treatments but at the 1.0 kg/ha rate (applied
at the shot blade stage), the mean seed yield was 348 kg/ha, significantly
less than that of the untreated plots.
Dicamba (BANVEL) was tested at 0.15, 0.30 and 0.60 kg/ha in the autumn,
and in the spring before stem elongation and at the shot blade stage of
bromegrass. At the 0.15 kg/ha rate, seed yields were reduced only when the
herbicide was applied at the shot blade stage. At the 0.30 and 0.60 kg/ha
rates, the herbicide was safe only when applied in the autumn.
In another test near Dawson Creek, B.C., the effects of clopyralid
(L0NTREL) alone and with 2,4-D, mecoprop (MEC0TURF), chlorsulfuron (GLEAN),
mecoprop + clopyralid and 2,4-D/picloram (T0RD0N 202C) were investigated on
seed yield of established Climax timothy (Darwent 1984). Timothy exhibited
tolerance to clopyralid (0.2 kg/ha) and 2,4-D/picloram (0.45 kg/ha).
Chlorsulfuron at 0.02 kg/ha or more and mecoprop (1.0 kg/ha) treatments
caused serious seed yield reductions. Slight yield reductions were observed
with 2,4-D and clopyralid + 2,4-D even though no crop injury was observed.
THE ROLE OF FERTILIZERS IN FORAGE PRODUCTION
Critics of modern agriculture technology point to the increasing use of
fertilizer, herbicides and other pesticides as a cause, rather than a
necessary result of poor farming practices. Many farmers, because of
economic necessity and the effect of some agricultural policies, have been
encouraged to produce annual crops on poor or problem soils that should have
been used for the production of perennial forages. Because of excessive
tillage, the use of too much summerfallow, the clearing of bush, trees and
even shelterbelts, breaking of land on steep slopes, the draining of sloughs
and "pot holes", and the failure to include soil improving crops such as
perennial grasses and legumes in the crop rotation, considerable damage to
the soil by wind and water erosion and the development of salinity has
occurred in all areas of Western Canada including the Aspen Parkbelt.
In order to sustain levels of production required both for economical
survival of the farmer and to feed a growing world population, it is
imperative that the nutrient and organic matter lost from the soil as a
result of marketing crops off the farm be replaced. Table 20 shows the
estimated amounts of soil nutrients removed from the soil by various crops at
the yields shown.
Several management practices can be employed to reduce these losses, and
thus reduce the amount of inorganic fertilized required for optimum crop
production.
40
These are summarized as follows.
1. Proper inoculation of legume crops (alfalfa, sweet clover, faba
beans, etc.) will permit symbiotic rhizobia to fix a large proportion of the
plants' nitrogen requirement from the atmosphere (70-100%).
2. Feeding farm grown crops to livestock on the farm and returning the
manure to the soil will markedly reduce the loss of soil nutrients. (Table
21). If manure is managed to minimize seepage and volatilization (NH~)
losses, purchases of commercial fertilizers could be reduced by an estimated
65-70%.
3. Including perennial forage crops, (particularly legumes) in the crop
rotation will reduce or eliminate soil erosion and thus avoid loss of fertile
soil and the nutrients contained in it. Plowing down legumes as green manure
crops will add appreciable organic matter and nitrogen to the soil (Table
22).
4. Returning crop wastes to the soil will increase organic matter
content of soils. This will have many beneficial effects including the
enhancement of microbial activity.
5. Adopting better soil management practices to reduce or eliminate the
susceptibility of soil to erosion (minimum tillage, control of weeds by
herbicides, contour tilling, and seeding, and not producing annual crops on
steep hillsides, etc.).
6. Many additional management practices: establishing shelterbelts,
snow trapping techniques, etc., will protect the land from erosion and reduce
the need to replace lost soil nutrients with chemical fertilizers.
The technology is available to protect the soil from deterioration and
produce high yields of good quality food for mankind, either directly in the
form of cereals, oilseeds and pulse crops, or indirectly by converting forage
crops, damaged or unmarketable crops to high quality food by feeding to
ruminant livestock.
41
Table 20. Estimated Nutrients Contained in Various Crops* (kg/ha)
Crop Yield Nitrogen Phosphorus Potassium Sulfur
Alfalfa (16% CP)
Sweetclover (13% CP)
Bromegrass (12% CP)
Wheat (16% CP)
Barley (12% CP)
Canola (21% CP)
Flax (21% CP)
*Seed only, in the case of cereal and oilseed crops. Return of crop residues
to the soil is assumed.
Note: Alfalfa and sweetclover, if properly inoculated with the appropriate
rhizobia, can obtain from 80-90% of their nitrogen requirements from
the atmosphere under favorable soil and growing conditions.
Table 21. Estimated Plant Nutrient Losses When Crops are Sold Off the Farm
vs Marketed Through Steers*
4500
115
11.0
89
11
5000
104
10.0
65
20
4500
86
14.4
90
13
3000
77
11
11
5
4000
77
13
16
6
2200
74
15
18
13
1600
54
8.5
12.6
3.7
Nitrogen (N) Phosphorous (P«0c)
Grain sold off the farm
1090 kg (40 bu) wheat (16% CP) 61 22
1527 kg (70 bu) barley (12% CP) 65 31
Hay produced for sale
1818 kg (2 tons) alfalfa (16% CP) 102* 22
Crops marketed through farm-finished steers
(Manure returned to soil)
(a) Grain
1090 kg wheat = 145 kg beef 9 5.9
1527 kg barley = 191 kg beef 11.5 7.7
(b) Alfalfa
1818 kg = 182 kg beef 10.9 7.3
*Assuming no N~ fixed from air and not including ammonia lost is rumen gases
or volatilization of manure. (If properly inoculated 90-100% of N could be
fixed. )
42
Table 22. Yield of Dry Matter and Nitrogen from Sweetclover, Alfalfa and
Redclover on a Degraded Black Loom at White Fox, Saskatchewan in the Second
Year After Establishment
Growth Stage
Crop
Dry Matter
(kg/ha)
Nitrogen
(kg/ha)
(Date)
Tops
Roots
Total
Tops
Roots
Total
Early Bud
(June 15)
Full Bloom
(July 15)
Alfalfa
Redclover
Sweetclover
Alfalfa
Redclover
Sweetclover
2280
1830
2280
3700
3390
4830
930
720
620
1560
1020
910
3210
2550
2900
5260
4410
5740
66
49
66
71
62
83
16
13
10
30
19
11
82
62
76
101
81
94
Source: K.E. Bowren
NUTRITION OF PERENNIAL FORAGES
ALFALFA
Most research on the nutrition of perennial legumes has been done with
alfalfa, but the principles also apply to crops such as clover, trefoil, and
sainfoin.
Alfalfa is an ideal cultivated crop for maintaining and improving the
quality and productivity of soils, while producing high quality feed,
particularly for ruminant livestock. Today, Canada grows 4-5 million
hectares of alfalfa in pure and mixed stands (grass-alfalfa).
Alfalfa seed should be inoculated with Rhizobium meliloti bacteria
immediately prior to seeding. The bacteria infect the root hairs of the
plant and form nodules, enlarged plant cells filled with bacteria, in which
the bacteria convert atmospheric nitrogen into nitrogen forms that the plant
can use. Other legumes, require their own specific strain of Rhizobium.
Under ideal conditions, an established stand of alfalfa will be provided with
all of its nitrogen through symbiotic nitrogen fixation. The alfalfa roots
should be checked periodically for the presence of nodules. Large nodules
that are bright pink when cut open are a good indication that nitrogen
fixation is occurring.
Alfalfa commences growth early in the spring and grows throughout the
summer into the late fall. An understanding of climatic as well as soil
factors must be considered when recommending fertilization of alfalfa swards.
Alfalfa can be grown on all soils except those that are poorly drained or too
43
coarse textured to retain moisture. However, coarse textured soils
associated with a high water table can be as productive as fine textured
soils if fertility is adequate. Alfalfa tolerates moderate salinity.
Because soil acidity interferes with nitrogen fixation by Rhizobium bacteria,
it is very difficult to establish alfalfa on highly acidic soils.
Consequently, soils with a pH of 6.5 or lower should be limed to a pH of 7.0.
Most prairie soils have a pH of 7.0 or higher and are suitable for alfalfa
production.
NUMBER OF HARVESTS ANNUALLY
Three harvests of alfalfa can be taken annually without any adverse
effects on stand density and longevity, provided that the crop is supplied
with an adequate supply of nutrients and moisture. Under normal moisture
conditions in the Aspen Parkbelt a two cut system is normal, unless
harvesting for "dehy". Under a three harvest system, yields can be in excess
of ten tons per hectare of forage with protein content in excess of 18%. For
optimum yield and protein, harvesting should occur at 'full bud' and not
later than the 5% bloom stage of growth (Fig 2.). Delaying harvest beyond
this time will result in minimum increase in forage yield but a significant
reduction in protein. Between the 2nd and 3rd harvest, it is recommended
that there be at least a six-week period of growth so that the crop can
prepare for over-wintering by accumulating and storing carbohydrates in its
roots. If a third harvest is taken it should be in October after the first
killing frost.
NUTRIENT REMOVAL
Table 23 shows that under a three-cut management system at Brandon, a
high-yielding crop of alfalfa uses a tremendous amount of the four major
plant nutrients. In comparison, a 2690 kg/ha crop of wheat uses
approximately 1/4 as much nitrogen, 1/2 as much phosphorus and sulfur and 1/6
as much potassium as a 12 t/ha crop of alfalfa. This large removal of
nutrients makes it essential to annually monitor the soil fertility and
forage nutrient composition by soil and plant analysis.
RESPONSE TO FERTILIZER
Alfalfa is very responsive to applications of fertilizer. Forage yield
increases of 39, 27, and 38% for the 1st, 2nd and 3rd cuts respectively, have
been obtained on clay loam soils. On sandy loam soils, with adequate
fertility, increases in the order of 300% for the 1st and 2nd cuts are
possible. Without fertilizer there was no 3rd cut (Table 23). Protein
content increased on the clay loam soils by 25 to 38% and by greater than
120% on the sandy loam soils with the addition of fertilizer (Table 23).
Despite the fact that alfalfa responds to fertilizers only 15 to 25% of
44
14
12
0)
u
■a
u
u
\
gg
0)
c
c
o
4->
10
^
•^
,. 1 Yield ,
^^v
*
%
_^-J^",*
m 2 Yield
^r
**
Vi
^
■
^» 1 Protein
^| 2 Protein
^^
i
2
- Clay
- Sandv
loams
' loams
•
-
1
. _L
■
.
30
24
18
12
Prebud Fullbud 10% bloom Full bloom
GROWTH STAGE
Source: L. Bailey - Brandon Research Station
Fig. 2. Yield of herbage and protein content of alfalfa grown on clay
and sandy loam soils at different growth stages (fertilized
treatments) .
the total alfalfa cropped area in Canadian prairies receives fertilizer.
FERTILIZING AT ESTABLISHMENT
Because it has a small seed, alfalfa needs a readily available supply of
phosphorus and other plant nutrients right after emergence. By the time a
young plant reaches 25% of its total dry weight, it may have accumulated as
much as 75% of its total phosphorus. High rates of fertilizer placed with
the seed will damage the seedlings. When potassium and sulfur are
recommended, they should be broadcast and worked into the soil or drilled to
a depth of 7.5 to 10 cm prior to seeding. The best response to phosphorus
fertilizer is obtained when it is placed 2.5 cm directly below the seed.
Good response is also obtained when the phosphorus is placed 2.5 cm below and
2.5 cm to the side of the seed. Placing the phosphorus greater than 2.5 cm
to the side of the seed, or broadcasting and incorporating it into the soil,
reduces its effectiveness. If machinery for specific placement of phosphorus
fertilizer is not available, the fertilizer may be broadcast and incorporated
7.5 to 10 cm into the soil.
45
Table 23. Annual Nutrient Removal by Alfalfa Forage Harvested at the Full Bud
Stage (kg/ha)
Fertilized* Unfertilized
Yield Element Protein Yield Element Protein
Cut t/ha N P K S (X) t/ha N P K S (%)
A. Clay Loam Soils
1st 5.0 185 13 175 12 23
2nd 3.3 116 8 100 8 22
3rd 3.6 122 8 90 8 21
Total 11.9 423 30 365 28
[Fertilizer (kg/ha) 0-60 P205 - 30 K20 - 30 S]
B. Sandy Loam Soils
3.6
108
7
86
8
19
2.6
83
5
52
6
16
2.6
55
5
42
6
16
8.8
256
17
180
20
1st
4.0
152
10
104
10
24
2nd
3.2
112
7
74
8
22
3rd
3.4
119
8
68
8
22
Total
10.6
383
25
246
26
1.0
18
2
11
2
11
0.8
13
1
6
2
10
0.0
1.8
3l
~3
17
~4
—
[Fertilizer (kg/ha) 0-60 P205 - 120 K20 - 30 S]
C. Fertilized Wheat (Include strav and grain)
Grain Yield _N _P _K _S
2690 kg/ha 95 14 60 12 (kg/ha removed)
Source: L. Bailey - Brandon Research Station
FERTILIZING ESTABLISHED STANDS
Increased use of fertilizer, use of improved varieties, herbicides,
insecticides, improved management and, in some areas, irrigation have
resulted in increased yield of alfalfa forage. This increased production of
high quality forage has resulted in increased removal of mineral nutrients
from the soil. Most experiments on alfalfa fertilization have been conducted
at yield levels that are low by present-day standards, making the results of
questionable value and possibly misleading when making current fertilizer
recommendations.
Nitrogen
Nitrogen is required for protein synthesis. Properly inoculated alfalfa
will fix large quantities of atmospheric nitrogen and under optimum
conditions needs no additional fertilizer nitrogen. Application of nitrogen
46
at the time of seeding may encourage weeds and adversely affect stand
establishment. Where a response to nitrogen on established stands has
occurred, it may indicate a low efficiency of nitrogen fixation. On acid
soils, where nodulation and nitrogen fixation may be poor, alfalfa responds
well to nitrogen application. The nitrogen content of alfalfa forage
harvested at the full bud to 5% bloom stage is generally in excess of 3%. If
little or no nitrogen fixation was occurring, the cost of applying nitrogen
requirements as fertilizer could be prohibitive.
Phosphorus
Phosphorus plays a key role in many life processes such as
photosynthesis, carbohydrate and protein synthesis, and transfer of heredity.
A 14 year study shows that 75% of prairie soils tested were moderatley
or severely deficient in available phosphorus. Determining the phosphate
requirement of alfalfa is difficult due to the complexity of soil and
environmental factors governing the availability of soil phosphorus to
plants, the low recovery of phosphorus from fertilizer (35% to 50%), and the
low concentration of phosphorus in the forage (0.2 to 0.4%). This low
concentration of phosphorus is indicative of the relatively small amount of
phosphorous removed from the soil by a crop of alfalfa forage. It is
sometimes found that alfalfa does not respond to phosphorus fertilizers.
Table 24, however, shows that alfalfa will respond in both yield and protein
content, to applications of phosphate fertilizer at rates in excess of 60 kg
P„0c per ha, probably on a P deficient soil. In Manitoba, fall broadcast
application of phosphorus fertilizer on established stands of alfalfa was
economical.
Potassium
It is generally believed that the majority of prairie soils contain
sufficient plant available potassium for alfalfa production. However, recent
studies have shown that soils with low potential for supplying potassium and
low exchangeable potassium, required an annual application of 100 kg of K/ha
to produce maximum yields (Table 25) and to optimize protein content (Table
26). There was also a significant response to potassium application on soils
that tested in the medium and high ranges of exchangeable potassium. At
maximum yield, taken at full bud, concentration of potassium in the forage
was in excess of 2.0% and represented a large removal of soil and fertilizer
potassium. Annual application of potassium maintained and increased yield of
alfalfa over an eight-year period by improving winter hardiness (Table 24).
Without potassium, the number of plants in the stand rapidly decreased due to
winter kill.
Broadcast application of potassium on established alfalfa is effective
and efficient, with essentially all topdressed potassium recovered by the
crop. The element may be applied at anytime during the growing season with
good efficiency. This is particularly so when it is applied immediately
after a harvest or when irrigated.
47
Table 24. Effect of Phosphorous Fertilizer on the YipIH, Phosphorous
Content and Protein Composition of Alfalfa at the Full Bud Stage.
Rate of
P20
0
Yield forage
Pho
sphorous
Protein
(kg/he
(t/ha)
<%)
m
0
5.0
0.08
11.3
23
6.1
0.15
12.5
45
10.2
0.20
13.8
67
12.5
0.22
20.0
112
11.2
0.25
18.8
Table 25. Total Alfalfa Forage Harvested Over a 5-yr Period from Five Soils
Fertilized with K.
Annual
rate of
K
(kg/ha)
Soils
0
50
75
100
200
-Tonnes/ha-
Souris (50)+
9.1
20.8
26.8
34.8
41.4
Miniota (1250)
17.3
27.1
32.0
35.1
46.3
Waitville (310)
23.7
32.0
34.8
38.2
49.0
Carroll (695)
57.6
57.4
57.5
58.0
57.9
Newdale (972)
44.8
51.7
52.8
52.6
52.7
Numbers in parentheses represent initial exchangeable K (kg/ha).
Table 26. Effect of Potassium Fertilizer on the Yield, Potassium
Content and Protein Content of Alfalfa, Grown on Low-Medium K Soils*
Rate of K?0
(kg/ha)Z
Yield
(t/ha)
Potassium
(%)
Protein
m
0
56
84
112
224
3.3
6.4
8.3
10.6
10.0
0.8
1.2
1.8
2.5
3.2
9.4
12.5
17.5
20.0
21.2
^Initial potassium levels in the soil ranged from 30 kg/ha (27
lb/acre) to 360 kg/ha (321 lb/acre).
- 5 Station years on three Manitoba soils.
- The plots also received an annual application of 67 kg/ha (60
lb/acre) PoOt- and 34 kg/ha (30 lb/acre) of sulfur.
48
Stand
Yield***
Stand
Yield***
Density**
(t/ha)
Density**
(t/ha)
98
2.6
102
2.2
102
3.2
90
2.5
97
A. 5
82
2.5
98
A. 2
51
1.4
102
4.6
35
0.9
100
4. A
15
0.5
95
4.0
15
0.5
Table 77. The Effect of Potassium Fertilizer in Protecting Alfalfa from
Winterkill on a Sandy Loam Soil
With Potassium* Without Potassium
Stc
Year
1970 (seeded)
1971
1972
1973
1974
1975
1976
1977
*Received an annual application of 112 kg/ha K„0.
**Number of plants in 3 one meter row lengths taken in May and expressed as
a percentage of the same count taken in the previous September.
•••First cut only.
- Initial soil test: 260 kg/ha exchangeable potassium (0-15 cm).
Sulfur
Plant protein contains about 1.0% sulfur and 17.0% nitrogen. There is a
close relationship between the nitrogen and sulfur nutrition of alfalfa. For
optimum forage yield, the ratio of total nitrogen to total sulfur in the
plant is 14:1. For maximum yield of forage, the concentration of sulfur in
the herbage at full bud should be in excess of 0.20%. Thus, the annual
broadcast application of sulfur not only increases herbage yield, but also
increases herbage protein (Table 28).
Micronutrients
Micronutrients play an important physiological and metabolic role in the
nutrition of forage crops. Apparent response to boron, copper and manganese
has been reported in Saskatchewan and Manitoba, but research has not verified
this. It is important however, to continue to monitor forages and to
investigate claims of micronutrient problems. These elements, although
required by plants in very small quantities, may cause severe economic losses
to producers when they are either deficient or present in excessive amounts.
49
Rate of S
Yield
(kg/ha)
(t/ha)
0
3.6
17
6.2
34
9.6
51
12.0
67
11.7
Table 28. Effect of Sulfur Fertilizer on the Yield, Sulfur
Content and Protein Content of Alfalfa
Sulfur Protein
(%) m
0.10 8.8
0.16 11.3
0.21 18.8
0.23 20.6
0.23 21.3
- 5 station years on a gray-wooded soil.
- Initial sulfur content of the soil was 15 kg/ha.
- The plots also received an annual application of 67 kg/ha PoOc
and 34 kg/ha K20.
GRASSES
Nitrogen is the major nutrient required for the production of quality
grass for both hay and pasture. Unfortunately only about 7% of the
fertilizer used in Manitoba is used for forage production. Perhaps the most
important argument for increasing the use of nitrogen on grasses is its yield
and protein-increasing effects, which enable more livestock to be kept per
unit of land. While nitrogen is usually the most effective plant nutrient in
increasing yield and protein content of grasses, other plant nutrients may
become limiting as yields are increased by the use of N fertilizer. Stand
life, regrowth, efficiency of protein production and high forage mineral
content are obtained only when the crop receives adequate amounts of the
essential plant nutrients. Soil testing will indicate the possibility that
various soil nutrients are limiting production.
Nutrition
Grasses for hay or pasture, are generally established on summerfallow or
partial fallow, but may also be seeded into clean stubble. The fertilizer
requirements of the grass at seeding are determined by soil analysis as for
cereals. However, grass seeds are not as tolerant of high rates of nitrogen
fertilizer placed with the seeds as are cereals. Rates of phosphorus up to
30 kg P^Oc/ha can be safely placed with the seeds, but it is recommended that
all other fertilizers be broadcast and worked into the soil 5 to 10 cm deep
immediately prior to seeding.
Nitrogen
The available nitrogen under an established grass sward is generally
very low, often zero. Response to nitrogen depends on the time and rate of
50
application, the source of nitrogen and on the age and species composition of
the sward.
All nitrogen should be broadcast on established grass swards prior to
commencement of regrowth. The closer the application is to the commencement
of regrowth, the more effective is the applied nitrogen in increasing yield.
Consequently, spring-applied nitrogen is more effective in increasing herbage
yield than fall applied nitrogen (Table 29). Also, a split-rate application
of nitrogen (applying equal increments of nitrogen in the spring and
immediately after each harvest except the final) is comparable to a single
spring application where moisture supply is adequate. The split-rate
technique has the added advantage of equalizing the production of herbage
with a relatively higher protein content throughout the growing season when
compared to the single spring application and is particularly useful for
pasture production where rotational grazing is practiced.
Annual applications of nitrogen are required for high yields of quality
herbage. Yield of forage and the protein content of grasses will increase
with increased rates of annually applied nitrogen fertilizers (Fig. 3).
There is usually a negligible residual effect on forage yield and protein
content in the year after fertilizer nitrogen application unless there has
been a poor growing season the previous year or higher than required rates of
nitrogen were applied. It has been found that the response of old grass
stands was greater than that of new stands when fertilized for the first time
with nitrogen. With continued annual application, however, similar responses
were obtained on all stands. In general, the amount of nitrogen annually
required for optimum production of high quality forage is in the range of 60
to 200 kg N/ha. The exact amount required is dependent on the plant
available nitrogen in the soil, and the required yield and protein content of
the herbage produced (influenced to a large degree by moisture conditions).
Under eastern prairie conditions, urea (46-0-0) and ammonium nitrate
(34-0-0) are more efficient sources of nitrogen for quantity and quality of
grass production than is solution-nitrogen (28-0-0) (Table 29). For early
season hay-type grasses, ammonium nitrate is the most effective source of
nitrogen in increasing yield. For late season hay-type grasses, urea and
ammonium nitrate are equally effective in increasing yield. Urea, however,
is the best source of nitrogen for increasing yield of pasture-type grasses
and for increasing the protein content of all grasses. The yield advantage
obtained with urea on hay and pasture type grasses is due to the good
regrowth and excellent second cut yields obtained when this compound is used.
Phosphorus
Most soils are deficient in phosphorus for optimum crop production.
Consequently, it is essential that adequate levels of phosphorus be applied
to optimize yield of quality forage. The yield increases obtained when
phosphorus is applied are not generally as great as those obtained for
similar units of applied nitrogen, however, phosphorus prolongs stand life,
particularly when the stand is subjected to intensive grazing. The element
51
Table 29. Effect of Type of N Fertilizer and Time of Applanation on the Yield
(kg/ha) and Protein Content (%) of Bromegrass and Russian Wild Rye for Each of
Three Cuts
Source of
Ni trogei
T
Check
NH, N0Q
Urea
Soluble
Yield
N
Yield
CP
Yield
CP
Yield
CP
CP
Bromegrass
Time of application <
[120 kg N/ha)
April
Cuts - June
2530
9
4150
18
3540
19
3300
18
- August
400
6
1150
13
1050
14
850
8
- October
600
7
1650
16
2000
17
1070
8
Total
3530
6950
6590
5220
October
Cuts - June
2530
9
4130
18
3500
19
3000
18
- August
450
6
1100
13
1000
14
600
8
- October
600
7
1490
16
1800
17
1100
8
Total
3580
6720
6300
4700
Split Application*
Cuts - June
2500
9
3500
19
3000
19
2700
18
- August
450
6
1530
16
1340
17
1200
9
- October
600
7
1900
18
2250
18
1400
11
Total
3550
6930
6590
5300
Russian Wild Rye
Time of application I
;i20 kg N/ha)
April
Cuts - June
650
7
2330
15
2010
16
1830
13
- August
400
6
1100
12
1830
14
900
8
- October
650
7
1200
13
1900
16
1000
9
Total
1710
4630
5740
3730
October
Cuts - June
650
7
2400
15
1790
16
1500
12
- August
400
6
1100
13
1520
14
650
7
- October
600
7
1300
13
1730
16
1100
9
Total
1650
4800
5040
3250
Split Application*
Cuts - June
650
7
2200
15
1930
16
1600
12
- August
400
6
1050
12
1850
14
900
8
- October
600
7
1350
14
1850
16
1120
9
Total
1650
4600
5630
3620
*120 kg split in equal applications at beginning of season and following each
cut (except final cut).
52
CRESTED WHEAT (4 Locations)
Urea
NH4NO3
Solution-N
0
60
120
TIMOTHY (4 Locations)
RUSSIAN WILD RYE (4 Locations)
130 240 0 60
kg N/ha Applied in April
120
180
240
Fig. 3. The effect of rates of spring applied Urea, NH NO and Solution-N
on the crude protein content of Crested Wheat, Timothy, Brome and
Russian Wild Rye. (Bailey, L.D. , Brandon Research Station).
53
also increases the efficiency of plants in utilizing other nutrients and
water, and thus promotes rapid regrowth.
Unlike nitrogen, phosphorus can be applied in the spring and/or fall
with equal effectiveness. In the Aspen Parkbelt of Western Canada, 30 to 50
kg P„0c/ha is considered adequate for annual production of hay and pasture.
The objective is to produce herbage containing at least 0.2% phosphorus or
greater.
Potassium
Coarse textured and well-drained soils are generally deficient in
potassium for optimum production of high quality forages. The quantity of
potassium required by various grasses differs. However, for grasses
recommended in the Aspen Parkland, a level of 2.0 to 2.5% potassium in the
forage should be the goal of any fertilizer program. When forage is grown
without potassium fertilizer, on soils low or deficient in potassium, stand
life and forage quality decrease, particularly when grazing is practiced;
further, the element has been shown to increase carbohydrate accumulation in
the roots thus enhancing winter hardiness and early spring regrowth.
An annual (spring and/or fall) broadcast application of 60 to 200 kg
K„0/ha is adequate for production of grass forage on soils low in potassium.
Although application of potassium fertilizer may not result in large yield
increases, the benefit obtained from crop quality, winter hardiness (stand
longevity), disease resistance and water use efficiency generally more than
compensates for the cost of the fertilizer, according to studies at Brandon.
Sulfur
Recent studies have shown that this element is limiting crop production
on several coarse-textured and well-drained soils. Sulfur is used by the
plants for the manufacture of certain essential amino acids in proteins. The
level of soil available sulfur should be higher than is required for optimum
plant growth, since the increased uptake of sulfur by the plants is
beneficial to ruminant animals. The use of sulfur fertilizer may not result
in dramatic yield increases, but rather in increased protein and increased
efficiency in the use of nitrogen and other plant nutrients.
The objective of a sulfur fertilizer program is to produce forage with a
sulfur concentration of 0.20 to 0.25%. The element can be broadcast in the
spring and/or fall with equal effectiveness. In general 20 to 35 kg S0,-S/ha
applied annually is adequate to maintain production on most soils that may be
low of deficient in the element.
54
Micronutrients
The need for micronutrients is best diagnosed by leaf or tissue
analysis. Deficiencies are corrected by either foliar sprays or soil
incorporation of the deficient element(s). Micronutrients may be applied
to forages not only to correct deficiencies but also to increase the levels
of the nutrient(s) in the forage to meet the requirement of livestock feed,
although this may be more costly than supplementing the ration with
appropriate mineral supplement.
NUTRITION OF FORAGE LEGUME-GRASS MIXTURES
Fertilizer recommendations for legume-grass mixtures must take into
account the relative proportions of legume and grass in the stand. In
general, if the stand has less than 25% grass in the stand it is recommended
to follow the fertilizer practices outlined for pure legume stands.
Similarly, if the stand has less that 25% legume then it is recommended to
treat the stand as a grass stand.
A general rule for fertilizing mixed stands is (1) determine the
percentage of grass in the stand, (2) determine the quantity of nitrogen that
would be added if the stand was 100% grass, (3) multiply the percentage of
grass in the stand by the nitrogen required for a 100% grass stand, this is
the nitrogen that is required for the mixture.
For other elements, proportional cuts in rates are not suggested.
Grasses and legumes are effective and efficient feeders of broadcast
fertilizers applied either is late fall or early spring. A general
recommendation for grass-legume mixtures is 40 N, 40 PoO,-, 30 K~0 per hectare
applied in late fall or early spring. It must be remembered that the
previous discussion for pure stands of grasses and legumes with respect to
secondary and micronutrient requirements apply equally to mixed stands.
DETERMINING OPTIMUM LEVEL OF NITROGEN (N) FERTILIZER FOR SEVERAL GRASSES
Researchers in Alberta and Saskatchewan have shown that economic optimum
N fertilizer rates are considerably higher than rates used by producers.
Some estimates show that the rate of fertilizer N used on grasslands in
Western Canada is as low as 13 kg N/ha.
At the Brandon Research Station*, the economics of applying N fertilizer
to smooth bromegrass (SBG), intermediate wheat grass (IWG), crested
wheatgrass (CWG) and Russian wild rye (RWR) grown for hay on two soil types,
a clay loam and a sandy loam was determined, taking into account the age of
the stand, N fertilization and precipitation data.
Total available N included soil nitrate N plus applied fertilizer N.
55
The economic optimum application rate was obtained at the point where the
last dollar spent of N fertilizer returned one dollar in additional value of
the standing hay crop.
The total available N required to maximize dry matter yields under
average spring precipitation conditions for a three year old stand are shown
in Table 30. These data indicate that both precipitation and soil type had
considerable effect on both maximum yields and on the quantity of fertilizer
N needed to produce them. Clay-loam soils were potentially more productive
than sandy-loam soils and required larger amounts of N fertilizer to maximize
dry matter yields. Both dry matter yield and N rate for maximum yield on
both soil types were strongly dependent on spring precipitation.
The economic optimum level of fertilizer N will always be less than that
needed to produce maximum yields. Fig. 4 shows how the price ratio of
fertilizer N/standing hay affects the economic optimum nitrogen level for
four grass species, on two soil types, under average April, May and June
precipitation (168 mm). The inset precipitation adjustment table on each
graph in Fig. 5, indicates how much more or less N to apply under moist (mean
+ 54 mm) or dry (mean - 54 mm) conditions. An example is smooth bromegrass
on sandy-loam soil (Fig. 4). In this graph the precipitation adjustment is
represented graphically. If the fertilizer N/standing hay price ratio was
approximately 10:1 (eg. N, $460/tonne, hay, $46/tonne) then the economic
optimum N would be approximately 130 kg/ha on sandy-loam soil under average
precipitation conditions. The graph shows that economic optimum available N
on sandy-loam soil would vary from 62-196 kg N/ha, depending on
precipitation. A producer can then subtract the quantity of N indicated by
soil test results to determine application rates. This information will help
producers to maximize profits. On other types of soils the figures would
differ, although the principles would be similar.
The value of standing hay, in contrast to baled hay must be used to
determine the price ratio. This is because harvesting costs per tonne vary
with yield since cutting is performed on a per hectare basis, while baling
and hauling are on a per bale basis. These costs must be subtracted from the
price of baled hay to determine the value of standing hay. Alberta studies
indicated that the total costs for handling hay (cutting, baling and hauling)
ranged from $15-$21/tonne. It is expected that these costs would be similar
in Manitoba.
The results of this analysis indicate that producers should increase
their use of N fertilizer if they wish to maximize profits. The economic
optimum quantity of N fertilizer to apply depends on both soil type and
spring precipitation.
*W.P. McCaughy, E.G. Smith and A.T.H. Gross
56
Table 30. Effect of Total Spring Precipitation and Soil Type on Forage
Productivity and Nitrogen Application Rates Necessary to Produce Maximum
Yields
Species
N rate for
maximum..yield
(kg ha"1)
Maximum
yield 1
(kg ha"1)
Sandy-loam
SBG
CWG
IWG
RWR
207 + 66*
280 + 90
265 + 85
228 + 83
4.3 + 2.1*
3.8 + 1.7
3.8 + 1.6
2.1 + 1.4
Clay-loam
SBG
CWG
IWG
RWR
362 + 116
520 + 166
350 + 112
312 + 76
9.2 + 3.0
9.3 + 2.9
9.0 + 2.1
7.5 + 2.0
Source: Brandon Research Station
*Note: In an average spring these precipitation adjustment values would be
ignored, in a moist spring they would be added to the mean values,
and in a dry spring they would be subtracted.
Producers should be aware that forage crops remove nutrients other than
nitrogen from the soil. In commonly grown grass hays, the ratio of
NrPhosphorus varies from about 6 to 10 parts of N to 1 of P. As hay
production is increased because of application of N other nutrients,
phosphorus, potassium and sulfur, and numerous trace minerals, are also being
removed from the soil and may in time be reduced to a level when they limit
production. Their levels should be periodically checked by soil analysis
and, if found to be low, corrected by use of fertilizer containing the
limiting nutrients.
At the Pathlow pasture project on a gray wooded soil in N.E.
Saskatchewan, responses to P and S fertilization have been excellent and
economically advantageous (see companion publication "Pasture Production and
Utilization in the Aspen Parklands of Western Canada".)
57
SANDY LOAM SOIL
PRECIPITATION
ADJUSTMENT
CMS 89
SB8 66
IMG 80
Rwn 73
0 2 4 6 8 10 12 14 16 18 20
PRICE RATIO (FERTILIZER N / STANDING HAY)
CLAY LOAM SOIL
PRECIPITATION
ADJUSTMENT
CHS 112
sbo lie
INS 166
RHR 76
0 2 4 6 8 10 12 14 16 18 20
PRICE RATIO (FERTILIZER N / STANDING HAY)
Fig. 4. Economic optimum available N vs price ratio
(fertilizer N / standing hay) for smooth
bromegrass (SBG) . intermediate wheatgrass
(IWG) . crested wheatgrass (CWG) and Russian
wildryegrass (RWR) on two soil types.
58
SANDY LOAM SOIL
WET
MEAN
0 2 4 6 8 10 12 14 16 18 20
PRICE RATIO (FERTILIZER N / STANDING HAY)
Fig. 5. Example showing the variabilty in economic
optimum available N due to precipitation
conditions for smooth bromegrass on sandy
loam soil .
EFFECT OF DATE OF FIRST CUT AND OF SPRING VS FALL APPLIED NITROGEN FERTILIZER
ON HAY PRODUCTION
For optimum hay production in the short growing season of the Aspen
Parkland, timing of the first cut for hay production is of vital concern.
The relative merits of spring vs fall application of nitrogen fertilizer is
also of considerable interest.
In 1985, an experiment was set up to investigate the effects of autumn
versus spring fertilizer application and timing of first cut on hay
production in northeastern Saskatchewan on Magna smooth bromegrass, Parkway
crested wheatgrass and Chief intermediate wheatgrass.
Magna smooth bromegrass (SB), Parkway crested wheatgrass (CWG) and Chief
intermediate wheatgrass (IWG) were seeded on June 13. Nitrogen fertilizer
(100 kg 34-0-0 kg) was applied either in October or spring (late April/early
May) of each year. The first cuts were taken on June 12, June 23, July 3,
July 16 or July 30, while the second cut was taken in late September for all
59
treatments in each year. The yields shown in Table 31 are the average total
annual production of the first and second cuts combined for each treatment
for 1987 and 1989. The crude protein values shown in Table 32 are for the
1989 growing season only.
Table 31. Averaged Total Annual Production (kg/ha) of First and Second Cut
Combined Yields for 1987 to 1989
Magna
Parkway
Chief
Treatment
Time of
Date of
SB
CWG
IWG
mean
fertilization
first cut
(kg/ha)
(kg/ha)
(kg/ha)
(kg/ha)
Fall
June 12
5018
4787
4871
4892
June 23
4886
4928
5102
4972
July 3
4622
4900
5452
4991
July 16
4395
4357
4751
4501
July 30
4250
4632
5127
4670
Average
4634
4721
5061
4805
Spring
June 12
4256
4241
4408
4302
June 23
4747
4852
4979
4859
July 3
5049
4381
4729
4720
July 16
4434
4108
5004
4515
July 30
3961
3982
4709
4218
Average
4489
4313
4766
4523
Source: P.R. Horton, Melfort Research Station
Table 32.
Crude
Protein (%)
for 1989
Magna
Parkway
Ch
ief
Date
of
SB
CWG
IWG
Time of
Cut 1
Cut 2
Cut 1
Cut 2
Cut 1
Cut 2
fertilization
first
cut
<%)
m
m
m
m
m
Fall
June
12
17.01
16.50
14.84
16.41
17.24
13.64
June
23
14.18
16.88
14.14
17.46
14.67
15.41
July
3
12.91
19.77
12.22
21.31
13.22
20.48
July
16
11.22
20.89
10.69
21.52
11.74
20.79
July
30
8.78
21.03
9.73
22.21
8.83
21.58
Spring
June
12
17.52
17.15
15.42
18.22
17.48
15.69
June
23
14.28
18.16
14.61
18.54
14.48
16.51
July
3
12.74
18.54
12.08
21.18
12.58
20.21
July
16
11.55
21.71
10.58
22.91
11.36
22.13
July
30
9.24
21.39
8.84
22.09
8.74
22.13
Source: P.R. Horton, Melfort Research Station
60
EFFECT OF FERTILIZER ON THE PRODUCTION OF ALFALFA RAY ON THREE SOTL TYPES
IN NORTHEASTERN SASKATCHEWAN
Various fertilizer treatments containing from 0 to 67 kg N/ha, 0 or 20
kg P/ha and 0, 22 or 46 kg S/ha were applied to Rambler alfalfa grown on
three different soil types, a Waitville loam, Melfort silty clay and Whitefox
fine sandy loam for 5 to 7 years. The initial fertility of the soil is
summarized in Table 33.
Table 33. Soil Analyses of Three Sites, Prior to Seeding Alfalfa (mg/kg)
Soil Type
Depth Nitrate N Soluble P Sulfate S pH
Waitville loam
Melfort silty clay
Whitefox fine sandy loam
0.0-0.3
10.4
6.7
3.9
7.4
0.3-0.6
5.6
3.1
5.3
8.0
0.0-0.3
25.6
28.4
11.5
6.7
0.3-0.6
3.2
4.0
11.5
7.4
0.0-0.3
5.7
16.5
4.9
6.7
0.3-0.6
12.3
9.8
3.4
7.0
The effect of fertilizer treatments on the yield of alfalfa three years
after establishment on the different soil types is summarized in Table 34.
61
Table 34 . Effect of N, P and S Fertilizers (kg/ha) on Yield of Alfalfa Hay
(tonnes/ha)* Three Years After Establishment
Soil Type
Nitrogen
Fertilizer
Phosphorus
Fertilizer
0
Sulfur Fertilizer
22
26
45
Waitville loam
0
10
22
10
10
45
67
Melfort silty
0
clay loam
10
22
10
10
45
67
Whitefox fine
0
sandy loam
10
22
10
10
45
67
0
5.18
--
0
0
10
6.33
—
6.33
20
5.03
7.52
20
6.90
7.73
20
5.53
8.77
0
7.80
0
0
10
7.58
—
7.88
20
7.51
7.19
20
8.33
7.34
20
7.56
7.72
0
4.34
0
0
10
4.26
—
4.85
20
5.35
4.69
20
5.47
3.69
20
5.32
5.91
8.14
7.99
4.89
6.22
9.48
6.73
8.10
9.09
8.21
4.70
4.77
5.91
*Total for 2 cuts
Source: W.F. Nuttall
If we value alfalfa hay at $70 per tonne, nitrogen at 55C/kg, P at
$1.15/kg and S at 32C/kg, the value of the additional hay produced by
applying fertilizer, less fertilizer cost per hectare, can be determined.
The results on the treatments shown in Table 34 are summarized in Table 35.
62
Table 35. Returns Over Fertilizer Costs of Applying Various Fertilizer
Treatments (kg/ha) to Alfalfa Grown on Three Soil Types ($/ha)
Soil Type
Nitrogen
Fertilizer
Phosphorus
Fertilizer
0
Sulfur Fertilizer
22
26
45
Waitville loam
0
10
22
10
10
45
67
Melfort silty
0
clay loam
10
22
10
10
45
67
Whitefox fine
0
sandy loam
10
22
10
10
45
67
0
0
—
0
0
10
75.
00
--
63.
50
20
-39.
00
128.
26
20
72
65
123.
71
20
-38.
35
184.
41
0
0
0
0
10
-20.
90
—
-11
40
20
-40
80
-78
24
20
-10
65
-86
99
20
-76
65
-72
49
0
0
0
0
10
-11
10
—
18
70
20
42
20
-11
.04
20
31
35
-100
29
20
8
75
43
01
186.78
-7.12
18.08
29.90
238.85
34.25
-21.90
28.15
-45.55
-17.70
-32.05
35.65
COMMENTS
1. In this project, the alfalfa was not inoculated. It should have
been, because soil cannot be counted upon to provide the required rhizobia.
2. Economic response of alfalfa to fertilizer was quite variable in
this test and difficult to interpret. On the Waitville soil there was an
excellent response to sulfur in the presence of nitrogen and phosphorus. On
the Melfort soil, response of alfalfa to fertilizer was, with one exception,
uneconomic. On the Whitefox soil there was a good response to nitrogen and
phosphorus combined, and a good economic response to S when used in
combination with high level of N (+P) or the intermediate level of N, without
P.
3. It would appear that the ratios of these three fertilizer elements
may be important and that imbalance will adversely affect yields.
63
USE OF BARNYARD MANURE
One tonne of manure contains about 5 kg nitrogen, 2 kg phosphorus, 5 kg
potassium, some sulfur and trace minerals, and a good supply of organic
matter. All these values vary according to the kind of animal, the kind of
feed fed, the kind and amount of bedding used and the method of handling the
manure. When spread on the land these ingredients become available for crop
production. Not only is the supply of plant nutrients increased, but the
added organic matter has a beneficial effect on the physical properties of
the soil and helps prevent or reduce erosion on sandy or other erodible
soils.
Research conducted by Bowren (Melfort Research Station) found that the
greatest response has been obtained when manure was applied to problem soils,
such as Gray Luvisol, which tend to bake and form a hard crust because they
lack organic matter. On such a soil at Snowden, Saskatchewan, manure applied
once every 3 years at 17 tonnes/ha increased the yield of wheat on
summerfallow from 1755 to 2902 kg/ha, annually, over an 11-year period. It
also increased the yield of the second crop (oats) from 1656 to 2340 kg/ha.
At Star City, a similar rotation (on a lighter-textured Gray Luvisol soil,
higher in organic matter) showed a 405 and 216 kg/ha annual increase of wheat
and oats, respectively, over an 8-year period. The manure was even more
effective when used in conjunction with alfalfa as a green manure crop.
On a degraded Black soil at Parkside, manure at 34 tonnes/ha applied
every 5 years over a 37-year period, increased the average yield of wheat in
the first and second crops by about 470 kg/ha and increased the yield of each
of two hay crops in the same rotation by about 1.1 tonnes of dry matter/ha.
The manure also improved the chemical and physical properties of the soil,
particularly the phosphorus content, water-stable aggregate, organic matter
content and water-holding capacity.
Removing manure from the feedlot and spreading it directly onto the land
is the most economical and practical disposal method; however, this may
create a weed problem, so piling the manure to allow further rotting may be
desirable. Because of its fibrous nature, fresh manure greatly improves the
physical structure of heavy-textured soils. Rotted manure, on the other
hand, tends to make sandy soils more compact and this often improves their
moisture-holding capacity. Manure should be worked into the soil as soon as
possible after it is spread, and preferably at the time that forage stands
are broken or during the summerfallow year of the rotation. If it is applied
before the sod is broken, it can be hauled by manure spreaders even in fairly
wet weather. A timely breaking operation allows excellent incorporation and
thus reduces nutrient loss by runoff or volatilization.
Spreading manure directly onto forage land has some obvious
disadvantages: for example, harrowing may be required to break up and spread
large lumps, which tend to foul or smother the herbage; and water runoff,
particularly in the spring, may carry considerable nutrients away and pollute
waterways. If it must be done, spread the manure on the forage stand in the
64
late fall or early spring, or on areas that have been grazed down and from
which the cattle have been temporarily removed. Set the spreader to deliver
a relatively low rate of manure and the beaters to pulverize it as much as
possible, so that rain will wash the material off the plants and into the
soil before the next grazing. Similarly, when applying manure to hayland,
spread it immediately after removal of the hay crop so that rain will work
the manure into the soil before the aftermath is grazed or a second hay crop
removed.
Applying manure on summerf allow is also a good practice provided it is
immediately incorporated into the soil to prevent contamination of runoff
water. Spreading it in early spring or even late summer provides sufficient
time to eradicate weed growth before a crop is seeded. Manure applied at
this time increases the organic matter content of the soil and assists in
controlling erosion on the summerfallow. Manure spread in the summerfallow
year has longer to decompose than that applied during the sod fallow year and
it can contain a higher percentage of undecomposed straw and raw material.
In a tilled summerfallow system, manure can be spread and incorporated
into the soil quickly to avoid loss of nutrients. In a zero-till system,
applied manure would have to be carried into the soil by precipitation, which
of course could lead to nutrient losses, and pollution of waterways.
Spreading manure on frozen soil is not recommended because it may
pollute water sources during the spring thaw and, also, nutrients may be lost
through volatilization and runoff.
COMMON DISEASES OF FORAGE CROPS
Diseases are caused by fungi, bacteria, mycoplasmas, viruses, viroids,
nematodes, mineral deficiencies, toxicities, and chemical injuries. The
fungi are the most common cause of plant diseases. They grow as microscopic
tubes or hyphae, and produce spores, or single celled, microscopic "seeds".
The spores are distributed by wind, water, insects, etc., and infect healthy
plants, usually during wet weather, cause disease and produce more spores to
infect more plants.
Good management of forage crops usually reduces disease, and always
increases yield. Avoiding a harvest in the fall before dormancy will allow a
build-up of root reserves which will help to reduce winter injury, whether
caused by low temperatures, snow mold or other diseases. Removal of infected
hay reduces the number of spores produced by the disease causing fungi and
thereby reduces disease losses.
In the Parkland, diseases usually cause less that 12% loss, but some can
cause complete losses when weather conditions favor the disease and inoculum
is available, for example Winter Crown Rot, Cottony Snow Mold, Brown Root Rot
and Northern Anthracnose.
65
Disease (Crop)
Symptoms
Control
Winter Crown Rot
(Forage legumes)
Cottony Snow
Mold
(Cereals, forage
grasses)
Damage appears in the spring as
dead patches. In older stands
single plants are killed.
Sometimes a cottony growth can be
found just as the plants are
uncovered by melting snow. This
disease is difficult to differentiate
from winter killing, but usually is
not associated with areas with poor
snow cover.
Do not harvest
during the
critical period
(Aug. 15 -
Sept. 25), to
allow the crop
to enter the
winter with
good root
reserves.
Yellow Leaf
Blotch
(Alfalfa)
Yellow blotches between the veins on
the leaves appear early in the season
and later become orange to brown.
This disease causes the leaves to
drop and lowers the quality of hay.
Cut early to avoid
leaf loss and
reduce
reinfection.
Anik and Rambler
are resistant.
Black Stem
(Alfalfa and
Clovers)
Dark brown to black areas appear on
the stems and can completely cover
the lower stem. The same fungus
also causes angular brown-black leaf
spots.
Remove all crop
material cleanly
to reduce
reinfection.
Verticillium
Wilt
(Alfalfa)
Infected plants wilt, the leaves
turn yellow and die to a light tan
color, but stems remain green even
after leaves are dead. This disease
is only serious in irrigated areas.
Rotate to cereal
or grass crops,
and control all
broad leaved
weeds. Resistant
varieties are
being bred.
Common Leaf
Spot
(Alfalfa)
Dark brown circular lesions appear
on the leaves, later small brown
fungal bodies appear in the lesions.
Harvest cleanly to
remove inoculum.
Bacterial Wilt
(Alfalfa)
Scattered plants in a stand show
stunted growth with a yellow-green
color. A cut through the taproot
shows a yellowish brown discolored
ring.
Usually serious
only in irrigated
areas. Newer
varieties are
resistant.
Brown Root Rot
(Forage legumes)
Dead or weakened plants in the spring
show brown lesions on the roots.
Gray, later black, spheres of the
fungus form on, or are imbedded in
the dead areas of the roots. This
disease appears erratically and can
Varieties
developed in the
Parkland show
resistance, ie.
Yukon sweetclover
and Peace alfalfa,
66
be absent from previously severely
diseased fields the following year.
Downy Mildew
(Alfalfa)
The upper surface of leaves becomes
yellowish, and on the lower surface
a gray downy growth appears. The
shoots become distorted and leaves
curl down.
Algonquin, Angus,
Anik and Thor are
resistant
varieties.
Powdery Mildew
(Red and Alsike
Clovers)
A white powdery growth spreads over
the upper surface of the leaves.
At present, there
are no reliable
control measures.
Northern
Anthracnose
(Red Clover)
Elongate, dark marginal lesions form
on the stems and petioles. The
leaves above the lesions die and
during wet weather masses of spores
are produced on the infected areas.
Norlac is a
resistant variety
Root Rot-Spot
Blotch
(Most grasses,
cereals)
Roots show a brownish discoloration
and later die. Brown, usually
elongate spots on leaves and stems,
sometimes with a yellow ring around
the lesions.
Rotation with
broad leaved crops
reduces disease
levels.
Ergot
(Most grasses
and cereals)
Seeds are replaces by fungus bodies
two to five times larger than the
seed, which can be seen sticking out
of the head. They are brown with a
purplish tint outside and white
inside. Before seed formation,
honeydew is formed on infected
heads.
Ergot bodies are
toxic and must
not be allowed in
food or feed.
Mowing the plants
before heading
prevents their
formation.
Silver top,
Whitehead
(Many grasses)
Dead dried heads on healthy green
shoots appear variably in stands of
grasses. The heads are easily
pulled out of the sheath, and show a
shrunken discolored base of the stem
Damage is only to
seed yield.
Spring burning is
sometimes
effective.
Brown Leaf Spot
(Bromegrass)
Brown spots, usually oval with a
yellow halo, appear on the leaves.
When heavily infected, the leaves
die.
Harvest cleanly,
fertilize to
recommended
levels.
Selenophoma
Leaf Spot
(Bromegrass)
Brown margined, irregular spots with
gray centers speckled with black
tiny fungal bodies.
Harvest cleanly to
remove crop
residue from
field.
67
Purple Eyespot Small, oval, purple spots with light North American
(Timothy) centers appear on the leaves. varieties are more
resistant than are
foreign varieties.
Maintain good
fertility.
Source: W.B. Berkenkamp, Melfort Research Station
FORAGES IN CROP ROTATIONS
Perennial forage crops, both grasses and legumes, improve soil quality
and help to protect the soil from erosion when included in crop rotations in
the Aspen Parkland of Western Canada. Research and producer experience have
demonstrated the value of such crops when they are included in the crop
rotation on a regular basis. A cropping system must be flexible to take
advantage of soil moisture, market prospects and other conditions, but on
many soils, perennial forages should be grown for up to 50% of the time for
best long-term land use. On the fertile silty clay loam at Melfort,
contained 0.55% N in the 0-15 cm layer in 1963. Subsequent research has
shown that with wheat prices greater than $163 per tonne, a six year rotation
containing two years of a grass-legume hay, provided high economic returns,
with or without the use of fertilizer. This rotation permitted a nutrient
buildup and had other benefits consistent with a sustainable agriculture. On
degraded soils the rotation was even more beneficial.
A COMPARISON OF GRAIN AND GRAIN-FORAGE ROTATIONS
Research comparing a commonly used straight grain rotation with a
grain-forage rotation on five different soil types has been on-going in
northeastern Saskatchewan for about 30 years to evaluate their long term
effects on crop production and soil characteristics.
Results show that on degraded soils there is an advantage for longer
term grain-forage rotations with reduced summerfallowing compared to straight
grain rotation (Tables 36 and 37). At all stations the yield of TDN (total
digestible nutrients) per hectare was higher in a six year grain-forage
rotation than in a 3-year straight grain rotation. Grain yields were higher
in the grain-forage rotation on the degraded soils at Somme and White Fox.
In addition, the nitrate content of the soil (Table 38) on both fallow and
stubble is considerably higher on fields in the grain-forage rotation at
Melfort and Somme. The protein content of wheat in the grain-forage rotation
is higher (0.4% on fallow and 0.6% on stubble, and 0.5% on fallow and 0.7% on
stubble) on average at Melfort and Somme , respectively, than for that from
the straight grain rotation.
68
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69
Table 37. Annual Production TON* kg/ha from Total Area of T.and in Rotations
Station: Melfort Archerwill Henribourg
Somme
*TDN of wheat, 89%; of hay, 55% (dry matter basis)
White Fox
Soil Type: Melfort Waitville Shellbrook Tisdale Whitefox
SCL L LL C FVL
Years Mean
Rotation**
27
20
15
26
28
- fallow, wheat
1243
873
971
- fallow, wheat,
1555
1003
1053
1736
693
wheat
- fallow, wheat,
1750
1397
1223
1968
1326
hay, hay, wheat,
wheat
Source: K.E. Bowren
RETURNS
The economic value of including forages in cropping systems varies from
farm to farm and from year to year, depending on the use that can be made of
the forage crop and the relative market value of forage and grain. The
relative value of hay to wheat (per unit of weight) required to provide equal
returns per hectare from the 6-year grain-forage rotation and the 3-year
straight grain rotation at each of the test sites is as follows:
Station
Archerwill
Henribourg
Melfort
Somme
White Fox
Ratio
0.31:1
0.032:1
0.43:1
0.17:1
0.00:1
This means that, if hay was worth at least 43% as much as wheat on an
equal weight basis, the 6-year rotation "paid off" at Melfort. At White Fox,
the forage crop did not have to be worth anything in order to justify its
inclusion in the rotation!
SOIL IMPROVEMENT
Rotations which included forages improved the chemical and physical
properties of the soils. This improvement is generally more pronounced on
the degraded and Gray Luvisol soils than on Black soils, which have a higher
organic matter content.
70
Table 38. Fall Nitrate Nitrogen in the 0-60 cm Soil Layer (kg/ha)
Rotation
Melfort (Msic)
(8 year average)
Fallow Stubble
Somme (Tic)
(11 year average)
Fallow Stubble
3-year straight grain
6-year grain/forage
86
114
37
58
61
83
19
29
Source: K.E. Bowren
Legume crops are particularly useful in improving not only nitrogen, but
organic matter content and tilth of soils. A year's growth of sweetclover
contains about 60 kg/ha of nitrogen. When sweetclover was added to a 3-year
grain rotation and worked down as a green manure crop at the bud stage,
during the summerfallow year, total grain production and net return per ha
were increased by 20%. In other studies, the amounts of dry matter and
nitrogen in legume crops were measured at various stages of growth. The
results are summarized in Table 39.
Table 39. Yield of Dry Matter and Nitrogen (kg/ha)
Stage of
growth
Dry matter
Nitrogen
Red
Sweet-
Red
Sweet-
Alfalfa
clover
clover
Alfalfa
clover
clover
1631
1524
1878
38
32
45
2434
1783
2725
69
48
81
4828
3897
5360
94
75
89
5248
4906
5478
99
92
64
Seedling
Early bud
Full bloom
Mature seed
Source: K.E. Bowren
If the alfalfa, red clover and sweetclover had been used as green manure
at the early bud to full bloom stages of growth, they would have returned
69-94, 48-75 and 81-89 kg of N per ha, respectively. Legumes also add a
large amount of dry matter to the soil which increases organic matter
content, promotes microbial activity, increases moisture holding capacity,
and improves tilth. If hay or seed is removed from the legumes after the bud
stage and only the roots and stubble worked into the soil, alfalfa and red
clover add proportionately more dry matter and nitrogen than does
sweetclover.
71
Experienced farmers agree that both sweetclover and alfalfa make good
green manure crops. Although herbicides can be used safely to control many
broadleaved weeds in seedling stands of alfalfa, they are not recommended in
sweetclover. While alfalfa stubble supplies more nitrogen and organic matter
than does sweetclover, it is usually more difficult to kill in a plow-down
operation.
In addition to providing a good source of feed for ruminant livestock,
grass crops help to prevent erosion by building up soil organic matter
content. In a 3-year period, bromegrass, crested wheatgrass, intermediate
wheatgrass or Russian wild rye contribute about 6 tonnes of root fibre per ha
in the top 25 cm of soil.
BREAKING GRASS SOD FOR CEREAL AND OILSEED CROP PRODUCTION
Research on working up bromegrass and intermediate wheatgrass sods,
revealed that methods of breaking tested, produced about the same clod
structure. Moldboard plowing produced the highest crop yields and retained
the least amount of root fiber in the surface soil on both grass sods (Tables
40 and 41).
Table 41. Wheat Yields (kg/ha)
Method of
breaking and
length of fallow
1st Crop After Breaking
Brome- Intermediate
grass wheatgrass Average
Total of 1st Two Crops
After Breaking
Brome- Intermediate
grass wheatgrass
Average
Full Fallow
Plow
Discer
Cultivate and spike
Rotary cultivator
Partial Fallow
Plow
Cultivate and spike
Rotary cultivator
Average full fallow
Average partial
fallow
2318
2385
2351
3825
3881
3853
2228
2070
2149
3735
3420
3578
3194
2126
2160
3791
3566
3679
2138
2036
2087
3701
3488
3594
1969
1969
1969
3431
3296
3364
1980
1688
1834
3319
3139
3229
1890
1676
1783
3263
3083
3173
2216
2160
2188
3769
3589
3679
1946
1778
1862
3341
3173
3257
Source: K.E. Bowren
72
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73
Full fallow treatments were broken on August 15 and summerfal 1 owed until
seeding 22 months later. Partial fallow treatments were broken on July 10,
after the hay was harvested, and fallowed until the next spring, then seeded.
The partial fallow treatments produced, on the average, 422 kg/ha less grain
in the first two crops after breaking.
In the above table, note that root fiber and water-stable aggregates in
the surface soil were greater at the end of the partial fallow than the full
fallow. The partial fallow produced more grain (about 1.5 tonnes) than the
full fallow. However, since two crops were grown on the partial fallow
(total average 3257 kg/ha) in the same period as one on the year long fallow
(average 2188 kg/ha). At the end of both periods, the area which had been in
bromegrass had less root material in the surface soil than that in
intermediate wheatgrass. This difference was greater after full fallow than
partial fallow, indicating that the bromegrass sod decomposed faster.
With grasses like crested wheatgrass and Russian wild ryegrass, which
have a bunchgrass root system, more time and tillage are required to break
down the sod and prepare a seedbed than with bromegrass or intermediate
wheatgrass in a partial fallow system.
Flax and oats are good crops to grow on a bromegrass-alfalfa sod fallow.
Table 42 shows the yields (10 year average) of various crops tested at
Melfort.
Table 42. Crop Yields on Sod (kg/ha)
Flax
Wheat
Oats
Barley
Argentine-type canola
Polish-type canola
heck
Fertilized*
Averag
1051
1078
1064
1574
1771
1673
2468
2655
2562
2052
2390
2221
965
1169
1068
892
1064
979
*Fertilizer supplied 34 kg nitrogen and 34 kg P^Oc/ha.
Source: K.E. Bowren
Note that fertilizer substantially increased yields of all crops except
falx. Soil tests should be used to determine nutrient requirements as these
vary, depending on the management and fertility program and the amount of
legume in the sward. If soil test information is not available, the
fertilizer required for stubble crops on the same farm should be used as a
basis for determining what should be added to sod fallow.
74
Tables 43 and 44 give 3 year average data for soil analysis of sod
fallows and of annual crop yields following grass sods. The annual crops
were fertilized at two levels of nitrogen.
Table 43. Soil Analysis of Sod Fallow
Russian
wild
ryegrass
Crested
wheatgrass
Bromegrass
Ease of breaking and preparing a seedbed difficult medium
Soil test data, fall after breaking
- NO. (0-60 cm), kg/ha 151 83
- P (0-15 cm), kg/ha 18 17
fairly easy
117
21
Soil moisture total (0-122 cm), cm
- at breaking time* (July)
- fall after breaking* (late October)
- spring at seeding time
28.2
40.4
37.3
31.0
42.2
40.1
31.8
42.9
43.7
Surface soil particles less than 0.84 mm, %
- fall after breaking* 50
- spring at seeding time* 48
47
51
43
49
*2 year average only.
Source: K..E. Bowren
75
Table 44. Crop Yields on Sod Fallow with Two Levels of Nitrogen, Both in
Combination with 34 kg P^O^/ha (kg/ha)
Crop
Wheat
Oats
Barley
Flax
Target rape
Echo rape
Russian
N level*
wild
Crested
(kg/ha)
ryegrass
wheatgrass
Bromegrass
8
2696
2414
2751
45
2734
2834
2864
8
3362
3446
3961
45
3600
3599
4105
8
2844
3000
3005
45
2851
2940
3111
8
1379
1566
1665
45
1573
1553
1698
8
1935
2229
2095
45
1974
2328
2213
8
1622
1650
1520
45
1526
1631
1572
^Fertilizer: 11-48-0 at 71 kg with the seed alone (8 and 34), plus 113 kg of
33.5-0-0 (45-34).
Source: K.E. Bowren
Because all the sod had a fairly high nitrate nitrogen content to begin
with, the additional nitrogen in the (45-34) fertilizer treatment did not
consistently affect the yield and often resulted in a reduction in the bushel
weight of the grain. The high nitrogen content of the grass sod was due
partly to the use of a nitrogen fertilizer (about 68 kg N/ha) for several
years before breaking.
A well-worked, firm seedbed into which seeds can be placed at a shallow,
uniform depth is very important, especially when seeding canola, flax or
barley and may be difficult to obtain from sod fallowed for only 6 months.
Also, weed control with herbicides may be more difficult in canola, than in
cereal crops.
ANNUAL CROPS FOR FORAGE
Annual crops provide a major source of fodder for livestock production,
whether in the form of pasture, silage, hay (greenfeed), soilage (zero
76
grazing) or straw. When annua] crops are damaged by hail, frost, drought or
during a feed shortage, most can be salvaged as forage and in some cases can
be more valuable as fodder than grain, for example Canola.
Perennial crops do not require cultivation and seeding operations each
year. In the Parkland of Western Canada, on the black and gray wooded soils,
growing conditions are quite different from those in the Southern Prairies
and Eastern Canada. A short cool season with insufficient heat units for
corn, is typical of this area, and only adapted species and varieties should
be grown.
SILAGE CROPS
Oats is usually the most productive silage crop in the Parkland, with
yields averaging 8100 kg/ha dry matter, but average protein content of 8.0%,
is lower than some of the other cereal crops. The highest yielding variety
is Foothill followed by Laurent, Frazer, Grizzly and Harmon in descending
order. The more recently released varieties have not been tested for their
forage yield.
Barley is the most commonly used silage crop in the Parkland, probably
due to producer familiarity, availability of seed and the choice of a grain
or silage crop. It is a satisfactory yielder, 6200 kg/ha dry matter, and
contains the highest protein (9.3%) of the cereal crops. Johnston is the
highest yielding variety, followed by Empress and Klages.
Wheat is as productive as barley, 6200 kg/ha, with a lower protein
content at 8.9%. Glenlea and Pitic are good yielding varieties in the
Parkland.
Spring rye is a low yielding crop, 5900 kg/ha, with a low protein
content (7.5%), and should not be used for silage production. Its only
advantage is that even under extreme drought it grows tall enough to harvest.
Triticale, a cross between wheat and rye, is a better silage producer
than either wheat or rye (6600 kg/ha @ 8.4% protein). Triwell and Carman are
high yielding varieties. Newer varieties have not been sufficiently tested.
Sunflowers are extremely variable in yield and this feature cannot yet
be related to any climatic factor. The average yield is 7200 kg/ha, with 10%
protein, but some years they yield less than half that of oats. Special
equipment is required to harvest sunflowers due to their height and large
stem diameter, so they are are rarely used as a silage crop.
Corn is not particularly productive is the Parkland, (5500 kg/ha at 10%
protein), due to a cool season and low heat units.
Faba beans produce more protein per ha than do peas due to their high
protein content (17.8% protein). Faba bean yields slightly better than peas
77
on black soils (5000 kg/ha) and about the same on solonetzic and gray wooded
soils. Faba beans make highly palatable, nutritious silage. Another
advantage of faba beans is their upright growth habit. Outlook, Aladin and
Herz Freya are good silage varieties.
Peas yield about the same as faba beans (5100 kg/ha) but have a slightly
lower protein content (16.6%). The smaller seed size of peas results in
lower seed costs. Tara, Century and Lenca are the better silage varieties.
Other crops, such as proso and foxtail millet, sorghum and
sorghum-sudangrass hybrids, soybeans and Jerusalem artichoke are not adapted
as silage crops in the Aspen Parkland.
MANAGEMENT
When operationally more convenient, cereals for silage production can be
seeded somewhat later than for grain production because cereals harvested for
silage (except corn) are at a less mature stage than when harvested for
grain. Early crops such as barley produce best when seeded in the last week
of May. Seeding rates somewhat higher than those recommended for grain
production should be used since thin stands affect yields more adversely with
silage than with grain.
Growing legumes (peas, sweetclover, etc.) in combination with cereals
such as oats and barley, will not increase overall yields over the average of
the two crops separately but will increase the protein content (and perhaps
palatability) compared to the straight cereal silage.
Delaying harvest time can reduce both quality and yield. During the
growing season, yield increases until the soft dough stage, then the energy
used to fill the seed is greater than that being produced by the plant, and
yield declines. The percentage protein decreases through the growing season
because the amount of stem increases in proportion to leaves. However, yield
of protein per ha increases until the soft dough stage. Protein content can
be increased by harvesting earlier but yield of forage is lower.
PASTURE
Oats is commonly used as pasture since it produces more regrowth than
other spring cereals, which produce a large amount of growth in the spring
and very little later. Spring seeded winter crops such as winter wheat, fall
rye, winter triticale and Italian ryegrass are slow to start but heavy
producers during mid and late summer. When planted in the spring, these
winter crops do not produce heads and continue to grow until late in the
fall, responding like perennial pastures to rotational grazing. A
considerable amount of pasture can be produced by seeding a mixture of spring
and winter crops, harvesting an early silage crop, then grazing the regrowth
until late fall.
78
Forage rape, and kales are highly productive if not grazed until late
fall. Animals should only be allowed access to small portions of the field
to avoid waste. These crops cannot be efficiently harvested as silage due to
their late maturity and high moisture content. The kale variety, Maris
Kestrel, is recommended for use in Canada.
HAY
Most annual crops harvested as whole plant material for livestock feed,
are used either for pasture or silage. Some can be put up as hay if
required. Oats is the most common cereal put up as hay. Peas, faba beans,
oilseeds, sunflowers and Jerusalem artichokes, are not amenable to putting up
as hay due to the physical nature of the plant and/or the difficulty in
drying the crop in the swath.
Most of the foregoing material is derived from Alberta and Saskatchewan
sources. Table 45 summarizes typical yields of annual crops grown in
Manitoba and Table 46 provides a summary of various management practices
involved in the production of annual crops in Manitoba.
Table 45. Typical Yields and Composition of Several Annual Crops Grown in
Manitoba for Fodder*
Dry Matter
Total Digestible
Crude Protein
(kg/ha)
Nutrients
(%)
(%)
5000-6000
58-63
10
5800-7300
62
12
2480
50-63
15-18
1500
62
22
4030
57
9
4600-4900
54-59
11-13
6170
—
—
5600-9800
52-58
10-11
5600
56
19
3100-5600
55-58
11-12
1300-4200
59
15
6000
56
11
4890
59
11
3200-5300
52-57
11
5900-6100
52-54
9-10
1200-2960
57
12
5630
45-57
10-13
3930
57
17
2600-6200
53-63
11-12
Crop
Barley
Corn
Fababeans
Fall rye
Foxtail millet
Italian ryegrass
Jerusalem artichoke
Oats
Peas
Proso millet
Rapeseed
Siberian millet
Sorghum
Sorghum/Sudangrass
Spring rye
Sunflowers
Tri ticole
Western ryegrass
Wheat
^Yields and composition are, of course, subject to wide variations in growing
conditions, stage when harvested, and harvesting and storage methods.
79
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80
Yields of selected perennial and annual crops at Brandon are summarized
in Table 47.
Table 47. Performance of Forage Crops at Brandon
Yield kg/ha
Long Term Years
Alfalfa
5092
Bromegrass
- check
3600
- fertilized
5954
- seed
210
Corn
- grain
3324
- silage
7320
Fescue
- hay
1870
- seed
24
Hay
- grass + legumes
4028
Oats
9766
Pasture
- clipping
3801
- grazing*
189
Rapeseed
1276
Russian wild ryegrass
- check
3417
- fertilized
3930
Sunflowers
1160
Sweetclover
- hay
4433
- seed
191
Timothy
1616
Trefoil (Birdsfoot)
3736
Wheatgrass - Crested
- check
3678
- fertilized
5555
Wheatgrass - Intermediate
- check
4511
- fertilized
6261
- seed
419
Wheatgrass - slender
3470
- tall
4491
27
26
11
13
26
30
8
2
28
5
27
19
25
12
5
17
18
10
4
3
15
5
21
5
2
9
4
*Animal Unit Days per Hectare
Source: A.T.H. Gross, Brandon Research Station
81
KOCHTA
Kochia is a fast growing annual that is well adapted to dry, saline
soils and prefers hot weather. It is tap rooted, but will produce shallow
roots under moist conditions. At Melfort it has produced yields of 2.6 and
7.2 tonnnes of dry matter per hectare for early and late cuts, respectively.
If cut before becoming too tall or stems becoming too coarse (usually at a
height of 1 meter in the Aspen Parkbelt) it can contain 12% crude protein and
60-61% digestible dry matter. However, it has a high mineral content, making
it unsuitable when fed at over 50% of the ration for ruminants. It has been
suggested that kochia might be grown along with another saline-tolerant crop
to produce a more acceptable feed. However, if the "other" crop produces
well, there is no point is growing the kochia. Alternating loads of kochia
with another crop (sweetclover or barley), when making silage would likely
provide a more acceptable feed for ruminants.
Because of its reputation as a weed, it is suggested that seed be
obtained from the southern U.S. (Texas or New Mexico). This strain will not
set seed under conditions in the Aspen Parkland. It should be sown
(broadcast) at the rate of 4-8 kg/ha (heavier rates encourage finer-stemmed,
more palatable feed) in October, and lightly harrowed in.
82
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