Effects of initial plant spacing and applied nutrients on stand development and productivity of Texas bluegrass in the Louisiana coastal plain

The native rhizomatous cool‐season perennial grass, Texas bluegrass (Poa arachnifera Torn), has recently been recognized again as a plant with considerable potential for range and pasture plantings. Throughout the first half of this century, sporadic efforts at evaluation and commercial use of Texas bluegrass were thwarted primarily by slow stand establishment and difficulties with seed processing. Subsequent advances in seed harvesting, processing, and planting equipment and selection of superior plant genotypes could reduce effects of these limitations. In much of the southern mid‐ and tall‐grass prairie regions and lower southeastern states where Texas bluegrass appears to have potential, there is no currently available sustainable cool‐season forage grass. Effects of initial plant spacing and lime, phosphorus (P), and nitrogen (N) application were evaluated in a field and a green house experiment on acid infertile Louisiana Coastal Plain soils. Stands from transplanting on 10‐ and 30‐cm spacings were comparable by the third growing season as the sparsely planted stand spread aggressively. The only consistent response to soil amendment was enhanced forage production from N fertilization in the spring. A plant photoperiodic response appears to limit potential to respond to N in autumn and winter. Forage production of dense stands and responses to spring application of N indicate that Texas bluegrass has considerable potential as a productive, sustainable cool‐season forage grass for at least some soils on the southeastern Coastal Plain as well as that recently reported for the southern mid‐ and tall‐grass prairie regions.     

Texas Bluegrass Responses to Seeding Rate and Fertilization

Texas bluegrass has potential as a cool-season perennial pasture grass for the south-central USA. Slow stand establishment in competitive environments is a limitation. Forage production of this grass increases with nitrogen (N), and rhizome growth increases with phosphorus (P). Stand responses by Texas bluegrass from three seed sources to seeding rate and a complete mixed fertilizer were assessed from 1997 through 2005 on a Louisiana Coastal Plain site. A linear response (R² = 0.39, P ≤ 0.0001) to seeding rate in March 1998 persisted through 2005, even though stands at all seeding rates improved over time. Stands did not differ (P > 0.05) among seed sources. At only the higher seeding rates, rhizome mass increased with fertilization. Soil pH decreased with fertilization, and pH was positively correlated with the final stand rating in 2005. Direct stand responses to fertilization were not detected. Lack of competitive advantage, despite growth responses, and soil acidification with fertilization indicate that increased seeding rates and delayed fertilization may enhance initial establishment of Texas bluegrass in humid environments.     

Nitrogen recovery by timothy from surface application of dairy cattle slurry

Abstract

Field experiments were conducted on a Buxton silt loam (fine, illitic, frigid Aquic Dystric Eutrochrepts) to determine the effect of surface application of dairy cattle slurry on nitrogen (N) recovery by timothy (Phleum pratense L.). Two experiments were conducted over two years. The experiments differed in the timing of both treatment application and forage harvest. This research indicated that the higher rates (supplying 186 and 267 kg N/ha) of slurry did not consistently increase total yearly yield or percent N recovery by timothy in Maine. The lighter rates (supplying 132 and 134 kg N/ha) had the advantage of less physical suppression of growth during the first cut following application and is, therefore, recommended. Spring application of slurry provided the greatest N recovery due to greater uptake by the cool‐season grass than later in the growing season in the spring and is, therefore, recommended over summer application. If spring application is not feasible, summer application of a moderate rate of slurry would allow more slurry disposal without a reduction of yield. Although N recovery from the slurry was relatively low, the potassium (K) concentrations in the forage indicate that the slurry supplied K to the crop at a relatively high level. The ability of the slurry to recycle K may be the major benefit to surface‐applied slurry in crop production.     

Effect of Nitrogen Fertilizer Rate and Harvest Season on Forage Yield,Quality, and Macronutrient Concentrations in Midland Bermuda Grass

Bermuda grass [Cynodon dactylon (L.) Pers.] is a major forage for grazing and hay production in the southern United States. The objectives of this study were to determine effects of nitrogen (N) fertilization rate (0, 112, 224, 336, and 448 kg ha^?1), split spring and summer applications of N at the 224 and 448 kg ha^?1 rates, and harvest periods (spring and summer) on forage yield, crude protein (CP), acid detergent fiber (ADF), neutral detergent fiber (NDF), total digestible nutrients (TDN), and concentrations of phosphorus (P), potassium (K), magnesium (Mg), and calcium (Ca in Midland Bermuda grass. Data were collected from 2002 to 2008 as part of an ongoing, long-term soil fertility experiment in southern Oklahoma. Repeated measures analysis of these long-term data showed that forage yield responses to N rate varied with year and harvest time with up to 2.5-fold yield differences among years. Nitrogen fertilization increased CP, TDN, and macronutrient P and Mg and decreased ADF and NDF. Crude protein was increased by ≥50%, and ADF and NDF dropped by up to 25% with the greatest N rate. In general, split N applications did not affect forage yield but produced low-quality forage compared to single N application in spring. Split application of 448 kg N ha^?1 gave forage with CP, TDN, ADF, and NDF similar to the Bermuda grass receiving 336 or 448 kg N ha^?1 as a single application. Spring forage had better forage quality than summer harvests. While N fertilization increased forage Mg and P concentrations by more than 50% during both spring and summer, it had no effect or slight increased K and Ca concentrations. In the southern Great Plains, despite the weather-dependent variability in forage yield of Bermuda grass, N application increase forage quality.     

Response of tall fescue to fertilizer placement at different levels of phosphorus,potassium, and soil pH 1

Fertilizer application, particularly nitrogen (N), is important in cool‐season grass forage production. Subsurface (knife) placement of N often has resulted in higher forage yield and N uptake of tall fescue (Festuca arundinacea Schreb.) compared to surface‐broadcast fertilization, but further studies were needed to indicate whether soil pH, phosphorus (P), or potassium (K) modifies the response. Experiment I tested responses of forage yield and N and P concentration to N, P, and K amount and placement. Two types of fertilizer placement ‐ broadcast and knife ‐ were used with 13, 112, or 168 kg N; 0 or 19 kg P; and 0 or 37 kg K/ha in a factorial arrangement. Yields increased by 53% as N fertilization went from 13 to 112 kg/ha and by 69% as N increased from 13 to 168 kg N/ha. Forage yield was increased 26% from knife compared to broadcast fertilizer placement. P application increased forage production by 13%, but K application had no effect on yield. Forage N concentrations increased by 25% as N fertilization went from 13 to 112 kg/ha and by 38% as N increased from 13 to 168 kg N/ha. Effects of added P and fertilizer placement on N concentration often resulted in interactions among factors. Forage P generally was increased by added P, with some effects of interactions among N rate, P rate, and placement. In Experiment II, fescue responses to N placement were tested where different soil characteristics had been established by previous lime and fertility treatments. Forage yield, N concentration, and N uptake were highest where 9.36 Mg/ha of lime were applied as compared to the control. Previous fertility treatments had no significant (P<0.05) effect. When N was knifed, forage yield was related positively to available soil P but not to pH or K. Yield and forage N concentration and uptake were increased by 20, 11, and 33%, respectively, as a result of knife versus broadcast N application.     

Alfalfa/grass response to nitrogen and phosphorus applications

Abstract

Alfalfa/grass (Medicago sativa/Dactylis glomerata, Bromus) yield and quality responses to nitrogen (N) and phosphorus (P) fertilizer applications are well documented. The magnitude of the P response and in turn N, may however, be limited by the relative immobility of P in the soil. A two‐year field study was conducted to determine the response of an established alfalfa/grass stand to combinations of a one‐time broadcast application of N, P, and sulfur (S) rates with fall or spring applications of P. Nitrogen and P applications increased forage production, nutrient concentration and nutrient content, particularly in the first production year. No S response was observed. Fall P applications were superior to spring applications only in the first year of production. If annual broadcast applications of P are made to existing alfalfa/grass stands in Intermountain areas, fall applications are recommended.     

Effects of White Clover Inclusion on Turf Characteristics,Nitrogen Fixation,and Nitrogen Transfer from White Clover to Grass Species in Turf Mixtures

Abstract

An irrigated field trial was conducted to test the effects of white clover in three turfgrass species (perennial ryegrass, Kentucky bluegrass, and creeping bentgrass) on color, clipping yield, and botanical composition and to estimate nitrogen (N)₂ fixation and N transfer from white clover to associated turfgrass species under different N‐fertilization conditions in 1999–2002.

Nitrogen fertilizers significantly increased color ratings in all observations. Grass–white clover mixtures had better color ratings than pure grass at all sampling dates and seasonal averages in unfertilized conditions. Fertilized pure grass plots yielded significantly more than control plots in all turfgrass species. Nitrogen fertilization did not affect clipping yield greatly in turfgrass–white clover mixtures. Nitrogen application significantly decreased white clover percentage in the harvested clippings in second and third year.

Nitrogen fertilization increased tissue N concentration positively in all turfgrass species grown alone. In contrast, N fertilization did not greatly affect tissue N concentration of either turfgrass species or white clover in the mixtures. Nitrogen fixation of white clover was estimated as 24.6, 30.7, and 33.8 g m^?2 year^?1 in perennial ryegrass, Kentucky bluegrass, and creeping bentgrass, respectively. The total estimated N₂ fixation gradually decreased with increasing N fertilization. Nitrogen transfer from white clover to the associated turfgrass varied from 4.2 to 13.7% of the total N that the white clover fixed annually.     

Effect of fertilization and harvest frequency on yield and quality of tall fescue and smooth bromegrass

Abstract

Fertilization and harvest frequency affect yield and quality of forages. The purposes of this experiment were to determine (i) the effects of fertilization and frequent harvesting on yield and quality of tall fescue (Festuca arundinacea Schreb.) and smooth bromegrass (Bromus inermis Leyss.) and (ii) the efficiency of N in animal waste as compared with inorganic N fertilizer for forage production of these cool season grasses. ‘Fawn’ tall fescue and ‘Southland’ smooth bromegrass were grown in the greenhouse on Pullman clay loam topsoil (fine, mixed thermic Torrertic Paleustoll) under eleven fertilizer treatments and two harvest regimes. Nitrogen fertilizer increased yields, N and K concentrations and K/(Ca + Mg) ratios and decreased P, Ca, and Mg concentrations. Phosphorus and K fertilizers did not affect yields but applied P increased P and tended to decrease N and Ca concentrations. Applied K tended to increase Ca concentrations. Recovery of N from feedlot manure ranged from 0.8 to 14%, whereas, recovery from NH₄NO₃ averaged 64%. Harvesting at 3‐week rather than at 6‐week intervals reduced yields 25%; however, N and P removal were higher under the 3‐week harvest regime. Even though forage production was reduced under heavy utilization, the grasses required more N fertilizer under heavy than under lighter utilization. The two grasses produced similar yields under the 3‐week cutting regime and at N rates through 340 kg/ha under the 6‐week cutting regime. Tall fescue yields were higher with the higher N rates under the 6‐week cutting regime. Smooth bromegrass forage was higher than tall fescue forage in N, K, and Ca, whereas tall fescue forage was higher in P and Mg.     

Coupling of dry matter and nitrogen accumulation in millet and ryegrass

Abstract

The logistic model has proven very useful in relating dry matter production of warm‐season and cool‐season forage grasses to applied nitrogen (N). A recent extension of the model coupled dry matter and plant N accumulation through a common response coefficient c. The objective of this analysis was to apply the extended model to both warm season pearl millet [Pennisetum typhoides (Burm.) Staph and C. E. Hubb.] and cool season ryegrass [Lolium multiflorum Lam.], and to establish a common response coefficient, c, between accumulation of dry matter and plant N for the two grasses in rotation. Analysis of variance established the validity of this hypothesis. The model accurately described response of dry matter, plant N removal, and plant N concentration to applied N, with an overall correlation coefficient of 0.9954. Furthermore, the model closely described the relationship between yield and plant N removal. The logistic equation is well behaved and simple to use on a pocket calculator. It can be used to estimate yield and plant N removal in evaluation of agricultural practices and the influences on environmental quality.     

Interactive Effect of Phosphorus and Nitrogen on Leaf Anthocyanins,Tissue Nutrient Concentrations,and Dry‐Matter Yield of Floralta Limpograss during Short Day Length

Abstract

A field trial was conducted during the short‐day period of 2004–2005 at Ona, Fl., to study the factorial effect of nitrogen (67, 90, and 134 kg N ha^?1) and phosphorus (0, 5, 10, 20, and 40 kg P ha^?1) rates on forage dry‐matter yield, quality, nutrient uptake, and leaf pigment concentration of limpograss (Hemarthria altissima). The N and P fertilizers were applied 45 days before each of two harvests. There was no interaction between N and P rates on any of the measured variables. Cool‐season forage yield increased curvilinearly from 137 to 350 kg ha^?1 in winter and 237 to 1389 kg ha^?1 in early spring, whereas crude protein (CP) concentration increased from 145 to 158 g kg^?1, as P was increased from 0 to 40 kg ha^?1, but yield and CP were not affected by N rate. There was a decreasing linear relationship between leaf concentration of anthocyanins and P rate of application such that forage obtained with 0 kg P ha^?1 had 61% more leaf anthocyanins and purple pigmentation than with 40 kg P ha^?1. There was no effect of N on anthocyanins content. It was concluded that increased level of leaf anthocyanins was due to the cumulative stress from cool weather and lower plant‐tissue P levels, which resulted in reduced growth and yield of limpograss. In cool weather, P played a critical role in controlling leaf purple pigmentation and forage yield.     

Diurnal patterns of nitrate assimilation in Kentucky bluegrass

Kentucky bluegrass (Poapratensis L.) is a major C₃‐type forage and turfgrass, but it is less efficient than many grasses in utilizing nitrogen(N). To determine how this grass can accommodate its greater N need, diurnal patterns of nitrate reductase activity (NRA) and nitrite reductase activity (NiRA) in its leaves and roots were examined and compared with those in barley (Hordeum vulgare L.). Plants were grown under greenhouse or growth room conditions and assayed for NRA and NiRA by optimized in vivo methods. The diurnal patterns of NRA and NiRA indicated that Kentucky bluegrass could assimilate nitrate during the night at rates greater than or similar to those during the day. Leaf NRA of Kentucky bluegrass was minimal approximately 4 and 10 h after illumination commenced and increased at night. The diurnal pattern of leaf NRA among Kentucky bluegrass cultivars did not differ significantly. In roots, NRA of Kentucky bluegrass was high in the morning and decreased sharply during the afternoon and evening, but increased again late at night. Unlike Kentucky bluegrass, barley exhibited greater leaf NRA during the day than during the night and exhibited the greatest activity 6 or 10 h after illumination commenced. In both species, the equilibrium leaf nitrate pool was 20 to 30 times larger than the ammonium pool and 3, 000 to 13, 000 times larger than the nitrite pool. Leaf nitrate pool size showed a diurnal pattern complementary to that of leaf NRA. Our results suggest that a nighttime N use strategy might exist in Kentucky bluegrass.     

Response of bermudagrass selections from the Appalachian region to N and P fertilization

Abstract

A greenhouse experiment was conducted to evaluate the influence of N and P fertilization on the yield and forage quality of six cold tolerant bermudagrass (Cynodon dactylon L.) selections from the Appalachian region. Midland bermudagrass and limpograss (Hermarthria altissima) were included for comparison purposes. Each grass was treated with a factorial combination of three N rates (112, 224, and 448 kg N.ha^‐1) and four P rates (0, 25, 75, and 225 kg P.ha^‐1) Two bermudagrass selections from the Appalachian region demonstrated greater dry matter production than Midland bermudagrass. Yields of Quicksand common exceeded those of Midland by 60% to 236% over the range of treatments. High yielding selections were not inferior to low yielding selections when mineral concentrations, neutral detergent fiber, acid detergent fiber and acid detergent lignin levels were considered. The results of this investigation suggest that Quicksand common and Selection 13 merit further study to determine their potential for summer forage production in the Appalachian region.     

Uptake and Distribution of Nitrogen in Perennial Ryegrass: Effect of Additional Applications at Vegetative Growth

Abstract

Nitrogen (N) fertilization rate, form, and timing in perennial ryegrass (Lolium perenne L.) vary according to the purpose of the grass. Double or triple spring N applications are required in forage production of perennial ryegrass. Whereas in perennial ryegrass grown for seed production the effect of more than one application has not received much attention. The hypothesis is that in perennial ryegrass grown for seed production the utilization of applied N depends on the current N status. Perennial ryegrass was grown in a hydroponic system with two N rates: low‐N (0.2 mM) and high‐N (6.0 mM). After 47 days of growth, additional N was applied as double‐labeled ¹⁵NO₃ ^{? 15}NH₄ ⁺ on four successive occasions in order to distinguish between the recoveries of the initial N applications and the additional N applied. Growth parameters and N content were analyzed on five harvesting occasions. Additional N applications to plants with low N status were primarily used to increase both N content in all organs as well as shoot number. By contrast, in high‐N treatments, the additional N supplied was primarily used to increase total‐N content in leaves. In all treatments, leaves were the preferable storage organs for N, however, the results from the high‐N treatments suggest a shift to pseudo‐stems as the preferable storage organ when additional N was supplied. It is suggested that the current N concentration in perennial ryegrass determines the potential of the plants to utilize additional applied N.     

EFFECTS OF NITROGEN APPLICATION TIMING ON GROWTH AND QUALITY OF A TURFGRASS MIXTURE

A 3-year field study was conducted to determine the influence of nitrogen (N) application timing on the growth and quality of a turfgrass mixture consisting of perennial ryegrass (Lolium perenne L.), Kentucky bluegrass (Poa pratensis L.), creeping red fescue (Festuca rubra var. rubra L.), and chewings fescue (Festuca rubra var. commutata Gaud.) under irrigated conditions. Nitrogen was applied annually at the rate of 30 g m^?2 year^?1, with six application regimes: control (no N), single spring (30 g m^?2), single fall (30 g m^?2), spring + fall (15 + 15 g m^?2), spring + summer + fall (10 + 10 + 10 g m^?2), and monthly from April through September (5 g m^?2).

Color, turf quality, clipping weights, and shoot density were correlated with fertilizer rates and application timing in this study. Fertilization monthly or every 2 months resulted in more uniform color and turf quality and less clipping weights than with comparable heavy spring and fall fertilizations. Heavy N applications in the fall did not cause winter injury and produced significantly darker color and more uniform appearance in early spring than other N applications. All N-fertilization regimes increased shoot density, but spring fertilization stimulated density the most. Nitrogen applied monthly or every 2 months was enough to enhance the color, turf quality, and shoot density of the turf during the growing season but did not greatly affect the growth rate.     

Leaf element concentrations of jojoba cuttings during vegetative propagation as related to nutrition and growth

Abstract

Response of jojoba [simmondsia chinensis (Link) Schneider] cuttings to fertilization during mist propagation was studied during two spring seasons and a summer season, using a soluble fertilizer (Peter's 20–8.6–16.5) and 3 controllled release fertilizers: Osmocote 19–2.6–10, Isobutylidene dlurea 20–2.1–4 and sulfur coated urea, 36–0–0.

Initial leaf concentrations of N, P and K were lower in spring than in summer and greater at lining‐out for fertilized cuttings. Leaf N and K content were positively correlated to root and shoot growth in spring and to shoot growth in summer. Leaf Zn and Mn were positively related to shoot and root growth in spring.     

Nitrogen Use Efficiency in an 11-Year Study of Conventional and Organic Wheat Cultivation

Abstract

Resource conservation with respect to nitrogen (N) was compared in organic and conventional cultivation of winter and spring wheat. Sustainability was measured in the nitrogen use efficiency of plant‐available N. The amounts of N entering each system and the amounts removed in the harvested crop and remaining as unused mineral nitrogen in the soil at harvest were determined. Net surpluses and losses during the growing season were also monitored, and the environmental variables influencing N harvest in the different cultivation systems were identified. The study was carried out in three different cultivation systems: conventional animal production (CONV), organic animal production (ORG1), and organic cereal production (ORG2). On average for all years and sampling occasions in winter wheat, there were approximately 60 kg more mineral nitrogen left in the soil during the growing season in CONV than in ORG1, and coefficients of variation were higher in CONV. The maximum values were considerably higher in CONV than in ORG1 (p=0.06–0.09), which increased the risk of leaching in the former, particularly in winter wheat cultivation. Nitrogen use efficiency in winter and spring wheat cultivation was 74% in whole crop conventional winter wheat and 81% in organic. Nitrogen use efficiency in harvested winter wheat grain was 44% for CONV and 49% for ORG1. ORG1 spring wheat was as efficient as ORG1 winter wheat, whereas ORG2 spring wheat used 73% of N in the whole crop and 39% in grain. Multivariate regression analysis showed that climate affected CONV and ORG1 winter wheat differently. High temperature in May increased grain yields in ORG1, but the converse was true for CONV. Large unused mineral N reserves at harvest coincided with large N harvest in CONV winter wheat. Residual fertility effects from the preceding crop produced high yields in ORG1 winter and spring wheat but had no effect in CONV. Generally, an increase in N reserves between plant development stages 13 and 31 was positive for both CONV and ORG1 winter wheat. Both winter and spring wheat require most N during this period, so the potential for improvement seems to lie in increasing mineralization (e.g., by intensified weed harrowing early in stage 13 in winter wheat and between stages 13 and 31 in spring wheat). Cultivation of winter wheat in ORG1 was a more efficient use of nitrogen resources than CONV. CONV efficiency could be improved by precision fertilization on each individual field with the help of N analysis before spring tillage and sensor‐controlled fertilization.     

Catch crop strategy and nitrate leaching following grazed grass-clover

Cultivation of grassland presents a high risk of nitrate leaching. This study aimed to determine if leaching could be reduced by growing spring barley (Hordeum vulgare L.) as a green crop for silage with undersown Italian ryegrass (Lolium multiflorum Lam.) compared with barley grown to maturity with or without an undersown conventional catch crop of perennial ryegrass (Lolium perenne L.). All treatments received 0, 60 or 120 kg of ammonium‐N ha^?1 in cattle slurry. In spring 2003, two grass‐clover fields (3 and 5 years old, respectively, with different management histories) were ploughed. The effects of the treatments on yield and nitrate leaching were determined in the first year, while the residual effects of the treatments were determined in the second year in a crop of spring barley/perennial ryegrass. Nitrate leaching was estimated in selected treatments using soil water samples from ceramic cups. The experiment showed that compared with treatments without catch crop, green barley/Italian ryegrass reduced leaching by 163–320 kg N ha^?1, corresponding to 95–99%, and the perennial ryegrass reduced leaching to between 34 and 86 kg N ha^?1, corresponding to a reduction of 80 and 66%. Also, in the second growing season, leaching following catch crops was reduced compared with the bare soil treatment. It was concluded that the green barley/Italian ryegrass offers advantages not only for the environment but also for farmers, for whom it provides a fodder high in roughage and avoids the difficulties with clover fatigue increasingly experienced by Danish farmers.     

Mineral composition of bermudagrass as influenced by maturity and nitrogen in a cool,temperate environment

Abstract

Warm‐season grasses contribute substantially to herbage supply during summer in cool‐temperate environments, when the productivity of cool‐season grasses declines. Herbage digestibility as well as mineral concentration may limit the amount of essential nutrients available to meet grazing animal requirements. A field study was conducted to determine the productivity and quality of a new selection of bermudagrass [Cynodon dactylon (L) Pers.], RSl, which is capable of growth and persistence in areas where other cultivars of bermudagrass are likely to winterkill. Concentrations and uptake of mineral nutrients in RSl bermudagrass were determined in response to N levels (0, 120, 240, and 360 kg N/ha) and delayed initial harvest (advancing maturity) at 2, 4, and 6 weeks after active growth began. Concentrations of P, Ca, K, Mg, and S in early season growth generally declined with advancing maturity. Concentrations of elements showed mixed response to N levels, and generally were not affected by treatments late in the growing season. Early in the growing season, mineral uptakes increased with advancing maturity. Increasing N levels early and late in the growing season enhanced mineral uptake. Mineral ratios, such as N:S and K (Ca + Mg), were within critical limits for adequate animal nutrition, but the Ca:P ratio was less than 2:1 and could contribute to known mineral‐related disorders in male sheep. Herbage mineral concentrations of RSl generally met or exceeded mineral nutrient requirements for sheep and cattle in growing or lactating physiological states.     

Foliar nutrient status in three boreal species for three years following hexazinone application

Abstract

Effects of hexazinone on the dynamics of macronutrients were studied in the foliage of trembling aspen, showy aster and marsh reed grass for three years after broadcast application of 10% granular formulation of hexazinone at 0, 2, and 4 kg ai/ha rates in August 1986 in a 3‐year‐old mixedwood cutover in a boreal forest. In untreated plots, nutrient concentrations followed normal patterns: calcium (Ca) increased from spring to late summer; potassium (K), phosphorus (P), sulfur (S), and nitrogen (N) peaked in early summer and declined towards fall; and magnesium (Mg) did not show any definite trends. At each sampling date, the coefficient of variation ranged from <10% for Ca, Mg, K and total N to 10–20% for P and S. Seasonal variations in the concentrations of each element were greater than the year‐to‐year variations. In treated plots, hexazinone application resulted in elevated concentrations of total Ca, Mg, K, P, S, and N during the first growing season, but these changes were only significant (P<0.05) at the 4 kg rate. The intensity of the effects declined by the end of the second growing season following herbicide application. In 1989, differences between nutrient levels in foliage from control and treated sites were significant (P<0.05) only for total N. Consequently, any changes in the nutrient status of hexazinone‐treated sites (beyond two years post‐treatment) are not expected to result from changes in foliar nutrient levels, but rather from changes in litter fall quantities, species dominance and total vegetation cover. Nutrient quality of forage for wildlife would not be affected beyond two years post‐treatment.     

The Effects of Sulphur Application on Yield,Sulphur Content and N/S-Ratio of Grasses for Silage at Six Sites in Finland

Abstract

The effects of sulphur (S) fertilization on forage production, sulphur content and N/S ratio of perennial timothy-meadow-grass (Phleum pratens L.- Festuca pratensis Hudson) and cocksfoot-dominant (Dactylis glomerata L.) swards cropped for one to three years were measured under a silage-cutting regime at six sites in Finland. Soil sulphur status ranged from poor/adequate (fine sand) to good (organic soils). Plant growth responses to supplementary sulphur were small, inconsistent and statistically insignificant. The supplementary S-fertilization increased the sulphur content of forage and decreased N/S-ratios at all sites. However, even in low-S fertilized plots the average sulphur content was very seldomly less than 0.2% on a dry matter (DM) basis, which has been assumed to be an adequate concentration in several foreign studies. High N/S ratios (> 14) were rare. The sulphur content of DM depended more significantly on growth stage and grass species than on supplementary sulphur. According to the results of these experiments, NPKS fertilizers contain sufficient amounts of sulphur to ensure both a good quality and a high yield of grass silage.