The response of grass-clover and pure-grass leys to irrigation and fertilizer nitrogen treatment. I. Irrigation effects

1965 ◽  
Vol 64 (2) ◽  
pp. 185-194 ◽  
Author(s):  
D. Reid ◽  
M. E. Castle
Keyword(s):  
Water Treatment ◽  
White Clover ◽  
Field Capacity ◽  
Fertilizer Nitrogen ◽  
Rye Grass ◽  
S 100 ◽  
Nitrogen Treatment ◽  
Irrigation Treatments ◽  
Nitrogen Treatments ◽  
Irrigation Effects

1. In an experiment conducted at the Hannah Institute the effects of irrigation and fertilizer nitrogen treatments on four sward types were studied for 3 years. The swards were S 23 perennial rye-grass with S 100 white clover, S 23 rye-grass alone, S 37 cocksfoot with S 100 white clover, and S 37 cocksfoot alone.2. The irrigation treatments were—a control (no water) treatment, and two treatments which were irrigated to planned deficit levels of 2 or 0·5 in. below field capacity.

The response of grass-clover and pure-grass leys to irrigation and fertilizer nitrogen treatment. II. Clover and fertilizer nitrogen effects

1965 ◽  
Vol 65 (1) ◽  
pp. 109-119 ◽  
Author(s):  
D. Reid ◽  
M. E. Castle
Keyword(s):  
White Clover ◽  
Nitrogen Application ◽  
Fertilizer Nitrogen ◽  
The Third ◽  
Rye Grass ◽  
Application Rates ◽  
Nitrogen Treatment ◽  
Irrigation Treatments ◽  
Nitrogen Treatments

1. The effects of irrigation and fertilizer nitrogen treatments on four swards were studied for 3 years in an experiment at the Hannah Institute. This paper describes only the effects of the fertilizer nitrogen treatments and their interactions with the presence or absence of clover in the sward, since those of the irrigation treatments have been reported previously.2. Annual applications of 0, 104, 208 or 312 lb. of fertilizer nitrogen per acre were made on swards of S 23 rye-grass or S 37 cocksfoot with or without S100 white clover.3. The yields of the grass + clover swards exceeded those of the pure-grass swards at all fertilizer nitrogen application rates in the first 2 years and at the 0 and 104 lb./acre rates in the third year.

Woburn irrigation, 1951–59 II. Results for grass

1962 ◽  
Vol 58 (3) ◽  
pp. 349-364 ◽  
Author(s):  
H. L. Penman
Keyword(s):  
White Clover ◽  
Dry Matter ◽  
Near Field ◽  
Field Capacity ◽  
S 100 ◽  
Grass Stand ◽  
Irrigation Treatments

A grass/clover ley (mainly S26 cocksfoot and S 100 white clover 3 years, 1951–53) and a pure grass stand (S 37 cocksfoot 6 years, 1954–59) on the same site had threefold replication of four irrigation treatments: O, unwatered control; C, kept near field capacity throughout; A and B, intermediate between O and C. All plots received the same basic P and K dressing, and half-plots got N dressings either as N1 and N2, or as N2 and N4, the nitrogen being applied in the spring and after every cut except the last at rates: N1 0·15; N2, 0·30; N4, 0·60 cwt. N/acre. Cuts were taken at about 3 or 4 week intervals in the summer, and yields expressed as dry matter.

scholarly journals Soil Nitrogen Treatment Alters Microbiome Networks Across Farm Niches

2021 ◽  
Author(s):  
XinYue Wang ◽  
Kerri Reilly ◽  
Ambarish Biswas ◽  
Linda Johnson ◽  
Suliana Teasdale ◽  
...  
Keyword(s):  
Soil Nitrogen ◽  
White Clover ◽  
Food Production ◽  
Network Connectivity ◽  
Nitrogen Enrichment ◽  
Rye Grass ◽  
Grass Root ◽  
Clover Root ◽  
Nitrogen Treatment ◽  
Nitrogen Treatments

Abstract BackgroundAgriculture is fundamental for food production, and microbiomes support agricultural through multiple essential ecosystem services. Despite the importance of individual (i.e. niche specific) agricultural microbiomes, microbiome interactions across niches are not well-understood. To observe the linkages between nearby agricultural microbiomes, multiple approaches (16S, 18S, and ITS) were used to inspect a broad coverage of niche microbiomes. Here we examined agricultural microbiome responses to 3 different nitrogen treatments (0 kg/ha/yr, 150kg/ha/yr and 300kg/ha/yr) in soil and tracked linked responses in other neighbouring farm niches (rumen, faecal, white clover leaf, white clover root, rye grass leaf, rye grass root)ResultsNitrogen treatment had little impact on microbiome structure or composition across niches, but drastically reduced the microbiome network connectivity in soil. Networks of 16S microbiomes were the most sensitive to nitrogen treatment across amplicons, where ITS microbiome networks were the least responsive.ConclusionsNitrogen enrichment in soil altered soil and the neighbouring microbiome networks, supporting our hypotheses that nitrogen treatment in soil altered microbiomes in soil and in nearby niches. This suggested that agricultural microbiomes across farm niches are ecologically interactive. Therefore, knock-on effects on neighbouring niches should to be considered when management is applied to a single agricultural niche.

Liquid manure as a grassland fertilizer. III. The effect of liquid manure on the yield and botanical composition of pasture, and its interaction with nitrogen, phosphate and potash fertilizers

1965 ◽  
Vol 65 (3) ◽  
pp. 333-340 ◽  
Author(s):  
A. D. Drysdale
Keyword(s):  
White Clover ◽  
Botanical Composition ◽  
Liquid Manure ◽  
Fertilizer Nitrogen ◽  
Rye Grass ◽  
Cow Urine ◽  
Split Plot ◽  
Nitrogen Treatments ◽  
Plot Design

1. In an experiment conducted for the 3 years 1961-63 on a perennial rye-grass and white clover sward a split-plot design was used to investigate the effects of liquid manure (cow urine + water) and its interactions with various levels of nitrogen, phosphate and potash fertilizers on the yield of herbage and on the botanical composition of the sward.2. On the average the liquid manure contained 0.26% N, 0.44% K and had a pH of 8.6.3. The liquid manure treatments supplied 0, 50, 100, 200 and 400 lb. N/acre/year and 0, 87, 174, 349 and 697lb. K/acre/year. The fertilizer nitrogen treatments were 0, 100 and 200lb. N/acre; the potash treatments 0 and 166 lb. P/acre and the phosphate treatments 0 and 66lb. P/acre.

The production of fattening cattle and extension of autumn grazing following three rates of application of nitrogenous fertilizer to a rye-grass/white clover sward

1960 ◽  
Vol 55 (1) ◽  
pp. 75-90 ◽  
Author(s):  
J. C. Tayler ◽  
J. E. Rudman
Keyword(s):  
Weight Gain ◽  
White Clover ◽  
Live Weight ◽  
Late Summer ◽  
Fertilizer Application ◽  
Control Treatment ◽  
Live Weight Gain ◽  
Nitrogenous Fertilizer ◽  
Rye Grass ◽  
Nitrogen Treatments

1. Three levels of a nitrogenous fertilizer, supplying 0,104 and 208 lb. N per acre were applied in 1955 and 1956 to a rye-grass/white clover sward in its fourth and fifth harvest years on a loam soil overlying chalk.2. Levels of animal production were measured using fattening cattle maintained on the plots at a stocking rate of 1⅓ per acre: excess herbage was conserved and fed back to them later.3. Low rainfall in 1955 seriously affected yields of herbage and response to fertilizer, and severely reduced the clover content in all treatments.4. Rate of live-weight gain per head was not reduced by the application of fertilizer at either level. Vigour of the sward was maintained by fertilizer application in a dry spring period in 1956, whereas, in the control treatment, which was low in clover, gains per head were markedly reduced because of inadequate dry-matter production.5. By applying two-thirds of the fertilizer in late summer, a considerable extension of grazing time was obtained, particularly when rainfall was adequate. At the highest level of fertilizer application in 1956 the grazing season was extended from 6 months to 7½, and the cattle continued on conserved feed to a total of 8½ months. Response to the medium and high levels of application on grazed herbage only was 12 and 15 bullock-days per acre, respectively, in 1955. In 1956 the response was 46, and 67/59 (the two high nitrogen treatments). In terms of total live-weight gain per acre the response in 1955 to medium and high levels was 23 and 32% above control, up to 427 lb. per acre: in 1956 it rose to 51 and 52/55% with the highest treatment reaching 657 lb. per acre. Greater financial returns than are indicated by live-weight gain should result from the rising price per pound of carcass as the supply of fresh beef dwindles in early winter.6. Carcass data indicated that both greater rate of gain and the extra time spent on fertilized herbage and conserved feed increased carcass weight and maturity in the normal pattern of development, fat most rapidly, muscle next and bone least. No significant differences in conformation due to treatment was detected by analysis of grouped joints.

The intensive production of herbage for crop-drying Part V. The effect of continued massive applications of nitrogen with and without phosphate and potash on the yield of grassland herbage

1954 ◽  
Vol 45 (2) ◽  
pp. 129-140 ◽  
Author(s):  
W. Holmes ◽  
D. S. Maolusky
Keyword(s):  
Protein Content ◽  
Crude Protein ◽  
Dry Matter ◽  
Soil Analysis ◽  
Latin Square ◽  
Mineral Fertilizer ◽  
Small Scale ◽  
Fertilizer Nitrogen ◽  
Nitrogen Treatment ◽  
Nitrogen Treatments

1. A small-scale plot experiment which had been carried out from 1947 to 1949 (Holmes, 1951) to study the effect of massive dressings of nitrogen, with and without phosphate and potash, on the yield of a ryegrass dominant sward was continued in 1950–2. A 4 × 4 Graeco-Latin square was used.The nitrogen treatments applied each year were:(1) no nitrogenous fertilizer, (2) 260 lb., (3) 520 lb. and (4) 416 lb. (312 lb. in 1951) nitrogen per acre per annum applied in four or five equal dressings, one for each cut. Treatments 1, 2 and 3 were cut each time they reached the long leafy stage (8–11 in. in height), treatment 4 was cut when 13–16 in. in height.The mineral treatments were (A) no mineral fertilizer, (B) 336–538 lb. K2O per acre per annum depending on nitrogen treatment, (C) 120–180 lb. P2O5 per acre per annum, (D) treatments B and C combined. Mineral applications were applied in four or five dressings each year, one for each cut.2. Applications of phosphate did not affect the yield or protein content of the herbage, but yields were severely restricted in the absence of potash. Where potash was applied the yields under each nitrogen treatment were maintained or increased over the 6-year period. Average yields of dry matter for the 6-year period when potash was present were 4760, 8050, 9620 and 9320 lb. per acre per annum for treatments 1, 2, 3 and 4. Without potash the corresponding average yields were 3980, 5610, 5190 and 5100 lb. Average crude protein yields with potash were 710, 1410, 1990 and 1640 lb. per acre per annum and without potash 550, 1090, 1190 and 1020 lb.3. The presence of potash resulted in earlier growth in each season through the maintenance of the earlier vigorous grasses in the sward. Although the growth curve was variable with treatment 1, treatments 2, 3 and 4 gave nearly uniform distribution of herbage production over the season.4. The weighted mean contents of crude protein for each year ranged from 13·9% for treatment 1 to 20·6% for treatment 3 when potash was given and from 12·9% for treatment 1 to 23·6% for treatment 3 when potash was absent. There was a gradual increase in protein content at the later cuts in each season, but the range was less where nitrogen was applied.5. The efficiency of utilization of fertilizer nitrogen was calculated. When the yield was compared with that of a no-clover sward the average response was 15·6, 10·8 and 11·8 lb. dry matter per lb. of nitrogen applied for treatments 2, 3 and 4 respectively. In terms of crude protein the percentage recovery was 53, 44 and 42 respectively. When the yields were compared with those of the clovery swards the nitrogen recovery figures were reduced by about one-third.6. The botanical composition of the plots was determined by the nitrogen and potash treatments. Where both were adequate a vigorous sward of ryegrass and timothy was maintained. Where nitrogen was absent but potash present a clovery sward developed. In the absence of potash with or without nitrogen the better grasses declined and were replaced by poor grasses.7. Provided potash was applied there were no marked changes in the soil analysis.8. The results are discussed with particular reference to the maintenance of high grass yields and the relative roles of clover and fertilizer nitrogen.

The combined use of fertilizer nitrogen and white clover as nitrogen sources for herbage growth

1983 ◽  
Vol 100 (3) ◽  
pp. 613-623 ◽  
Author(s):  
D. Reid
Keyword(s):  
White Clover ◽  
Nitrogen Fertilizer ◽  
Dry Matter ◽  
Nitrogen Sources ◽  
Application Rate ◽  
Fertilizer Nitrogen ◽  
Combined Use ◽  
S 100 ◽  
Grass Sward ◽  
Nitrogen Rates

SUMMARYAn experiment is described which investigated the combined effects of fertilizer nitrogen and a medium-large-leaved variety of white clover on the production from a mixed sward. Over a period of 3 years six rates of nitrogen fertilizer ranging from 0 to 750 kg/ha were applied annually on three different sward types cut five times per year. The swards consisted of S. 23 perennial ryegrass alone, S. 23 ryegrass plus Blanca white clover, and Blanca white clover alone. Averaged over the 3 years the nitrogen rate required on the pure-grass sward to give the same yield of dry matter as the grass plus Blanca clover sward with no fertilizer nitrogen applied was 265 kg/ha; the corresponding application rate to achieve equal crude-protein yield was 322 kg/ha. Blanca had an additive effect on the yield from the mixed sward at nitrogen rates up to at least 300 kg/ha. The results from this experiment are compared with those from experiments in which medium-small-leaved varieties of white clover were used. The role of white clover in providing savings in nitrogen fertilizer input on grassland is discussed. Estimates from the results indicate that the nitrogen rates required to produce an annual herbage dry-matter yield of 12 t/ha were 340 kg/ha on the pure ryegrass swards, and 140 kg/ha on the ryegrass plus Blanca sward. The nitrogen fertilizer saving due to the inclusion of Blanca white clover in the sward was, therefore, 43%. A similar estimate from the results of an earlier experiment with the medium-smallleaved variety Aberystwyth S. 100 suggests a nitrogen fertilizer saving of 21%.

The effect of varying the date of application of fertilizer nitrogen on the yield and seasonal productivity of grassland

1965 ◽  
Vol 64 (2) ◽  
pp. 177-184 ◽  
Author(s):  
M. E. Castle ◽  
D. Reid ◽  
R. G. Heddle
Keyword(s):  
White Clover ◽  
Nitrogen Fertilizer ◽  
Total Yield ◽  
Growing Season ◽  
Seasonal Distribution ◽  
The Other ◽  
Control Treatment ◽  
Fertilizer Nitrogen ◽  
Rye Grass ◽  
Small Plot

1. Two identical small plot experiments were done from 1961 to 1963, at the Hannah Dairy Research Institute, Ayr and at Boghall Farm, Midlothian to study the effects of applying nitrogen fertilizer at different times on total yield and its seasonal distribution.2. Two perennial rye-grass plus white clover swards, one containing S23 and the other S24, were used at each site. On both swards a total of 10 cwt. of ‘Nitro-Chalk’ (15·5% N)/acre, applied at varying dates over the growing season, and a control treatment which received no nitrogen fertilizer were tested.

Studies on the cutting management of grass-clover swards. I. The effect of varying the closeness of cutting on the yields from an established grass-clover sward

1959 ◽  
Vol 53 (3) ◽  
pp. 299-312 ◽  
Author(s):  
D. Reid
Keyword(s):  
Crude Protein ◽  
Dry Matter ◽  
Ground Level ◽  
Practical Significance ◽  
Fertilizer Nitrogen ◽  
Nitrogen Levels ◽  
Leaf Formation ◽  
Nitrogen Treatment ◽  
Nitrogen Treatments ◽  
Heavy Nitrogen

1. A 3-year experiment is described in which perennial rye-grass/white clover swards were cut to within either 1 in. of 2–2½ in. of ground level when the herbage had reached either the ‘grazing’ or the ‘silage’ stage of growth. Superimposed on the cutting treatments were several fertilizer treatments which involved application of varying amounts of nitrogen at different dates over the season.2. Throughout the experiment cutting to within 1 in. of ground level gave greater dry-matter and crude-protein yields of mixed herbage and of clover than cutting to within 2–2½ in. of ground level, the increase in dry-matter yield ranging from 39 to 49%.3. The response of clover to these ‘height of cutting’ treatments developed more slowly than the response of the sward as a whole, and was modified in the later stages by the particular fertilizer nitrogen treatment applied.4. It is suggested that the greater herbage yields obtained from close- than from lax-cut swards resulted from the differential effects of the two cutting treatments on stem and leaf formation in the grasses, but the need for further investigation is stressed.5. Discrepancies between the effects of the ‘height of cutting’ treatments in this experiment and those reported by other workers are indicated, and it is shown that these discrepancies probably result from the varying cutting frequencies adopted.6. Cutting the sward at varying stages of growth and increasing the rate of fertilizer nitrogen application had very similar effects on mixed herbage and clover yields in this experiment to those reported previously by other workers.7. Where the total amount of fertilizer nitrogen applied over the season was small (4 cwt. ‘Nitro-Chalk’/acre) delaying the first dressing until after the first or second cut reduced the dry-matter and crude-protein yields of mixed herbage, and had little effect on those of clover. A similar delay where greater total amounts of fertilizer nitrogen were used (8–12 cwt. ‘Nitro-Chalk’/acre) reduced the dry-matter yields of mixed herbage, and slightly increased the dry-matter and crude-protein yields of clover. Under these heavy nitrogen treatments the crude-protein yields of mixed herbage decreased only where the delay involved a reduction in the total amount of fertilizer nitrogen applied over the season.8. Although delaying the first dressing of the season reduced mixed herbage yields at all fertilizer nitrogen levels, it resulted in a more uniform distribution of production over the season. The practical significance of this is discussed.

scholarly journals Canopy Temperature Bias from Soil Variability Enhanced at High Temperatures

2020 ◽  
Vol 63 (1) ◽  
pp. 95-104
Author(s):  
Kendall C. DeJonge ◽  
Huihui Zhang ◽  
Saleh Taghvaeian ◽  
Thomas J. Trout
Keyword(s):  
Water Stress ◽  
Soil Texture ◽  
Irrigation Schedule ◽  
Canopy Temperature ◽  
Field Capacity ◽  
Soil Variability ◽  
List Type ◽  
Infrared Thermometry ◽  
Temperature Bias ◽  
Irrigation Treatments

HighlightMaize canopy temperature (Tc) was evaluated among four replicates of seven irrigation treatments.Individual replicates showed Tc bias correlated with soil electroconductivity and increasing Tc.At high Tc values (above 35°C), Tc bias was up to 5.0°C among plots with the same irrigation schedule.ABSTRACT. Maize canopy temperature was monitored on a continuous basis for two growing seasons in a limited-irrigation maize experiment with seven separate irrigation treatments and four replicates of each treatment. Soil electroconductivity (EC) was measured and mapped to quantify the variation in soil texture throughout the plots and was correlated with the average field capacity of the soil (R2 = 0.51). At lower canopy temperatures, indicating little or no water stress, very little difference was observed between replicates within the same treatment. However, at higher temperatures, soil texture had a greater influence on temperature, with soils having lower EC (and therefore lower water-holding capacity) showing more water stress. More specifically, at canopy temperatures above 29°C, the influence of soil texture biased the temperature by up to 2.0°C over the EC range of 16.9 to 40.2 mS m-1; at mean canopy temperatures of 35°C, this bias could be more than 5.0°C between field replicates. Results similar to the continuous infrared thermometry were found using nadir thermal images. This study demonstrates the importance of understanding the potential effects of soil variability on canopy temperature, which could have profound implications for spatially variable field-based management using thermal imaging or similar technologies. Keywords: Canopy temperature, Infrared thermometry, Limited irrigation, Soil variability.

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