排序方式: 共有67条查询结果,搜索用时 46 毫秒
41.
Apurba K. Sutradhar Eric C. Miller Daryl B. Arnall Bruce L. Dunn Kefyalew Girma William R. Raun 《Journal of plant nutrition》2017,40(17):2382-2391
Information is limited on using winter legumes as a source of nitrogen (N) intercropped with switchgrass in the southern Great Plains of the United States. The objectives of this study were to evaluate N contribution of several winter legumes to switchgrass, and to determine the influence of winter legumes on biofuel quality and soil fertility status. Field experiments were conducted at two locations in Oklahoma in which six winter legumes and four rates of N fertilizer were studied over a 3-year period. Winter legumes did not increase switchgrass forage yield, cellulose, lignin, and hemicellulose concentrations at any location. Soil organic matter (OM), nitrate-N (NO3-N), soil test phosphorus (P), soil test potassium (K), and soil pH remained unchanged. In contrast, applying inorganic N only increased switchgrass yield. This study demonstrated that southern Great Plains may not be conducive to utilizing legumes as the primary N source for switchgrass. 相似文献
42.
Switchgrass (Panicum virgatum L.) is a perennial biofuel crop with a high production potential and suitable for growth on marginal land. This study investigates the long-term planting effect of switchgrass on the dynamics of soil moisture, pH, organic carbon (SOC), total nitrogen (TN), nitrate nitrogen (NO3–-N) and ammonium nitrogen (NH4+-N) for soils to a depth of 90-cm in a sandy wasteland, Inner Mongolia, China. After crop harvesting in 2015, soil samples were collected from under switchgrass stands established in 2006, 2008, and 2009, native mixture, and a control that was virgin sand. Averaged across six layers, soil moisture and pH was significantly higher under the native mixture than switchgrass or virgin sand. However, SOC and TN were significantly higher under the 2006 switchgrass stand when compared with all other vegetation treatments and the control. The SOC and TN increased from 2.37 and 0.26 g kg?1, respectively, for 2009 switchgrass stand, and to 3.21 and 0.42 g kg?1, respectively, for 2006 switchgrass stand. Meanwhile, SOC and TN contents were 2.51 and 0.27 g kg?1, respectively, under the native mixture. The soil beneath switchgrass and native mixture showed the highest NO3–-N and NH4+-N, respectively. The soil moisture increased with depth while SOC, TN, and NO3–-N decreased. An obvious trend of increasing moisture, SOC, TN, and mineral N was observed with increasing switchgrass stand age. Thus, growing switchgrass on sandy soils can enhance SOC and TN, improve the availability of mineral N, and generate more appropriate pH conditions for this energy cropping system. 相似文献
43.
44.
采用室内恒温(25℃)培养的方法,研究施用不同用量的柳枝稷茎、叶对土壤有机碳(SOC)和微生物量碳(MBC)的影响,柳枝稷茎、叶在土壤中分解特性。结果表明:柳枝稷茎、叶施入土壤培养90d后,随着柳枝稷茎、叶施入量的增加,SOC和MBC含量明显增加。在柳枝稷茎、叶施用量相同的条件下,施入柳枝稷叶后,土壤微生物量碳的含量高于施用茎的含量,而施用叶的土壤中有机碳的含量低于施入茎的土壤有机碳的含量。柳枝稷茎、叶在土壤中的分解率具有一定的差异,且与施用量有关。在相同的柳枝稷茎、叶施用量条件下,叶在土壤中的分解率高于茎的分解率,表明了茎中的有机碳在土壤中周转期比叶中的长,说明施用柳枝稷的茎可以有效地促进土壤有机碳的累积。 相似文献
45.
为加速木质纤维素类生物质资源的能源转化,本研究以能源作物柳枝稷为基质材料,筛选可以高效产酶的微生物复合系。通过长期的限制性筛选,获得一组有效降解柳枝稷的复合系,进而对复合系的酶学特性及微生物多样性进行了研究。在连续2周的液体培养过程中,柳枝稷的干物质损失主要发生在前4d,且干物质损失率占总损失率的70%。在14d培养过程中,柳枝稷的纤维素及半纤维素的降解率分别达到了50%和60%。整个培养过程中的羧甲基纤维素酶活及木聚糖酶活结果显示,2种酶活的最高值分别达0.21和3.75IU。2种酶的优势作用pH分别为5.0和6.0,优势作用温度为60℃。克隆文库结果显示复合系由真菌和细菌共同组成,86%的细菌近缘种为Achromobacter xylosoxidans,91%的真菌近缘种为Fusarium sporotrichioides。 相似文献
46.
This study evaluated the reactions of seven common C4 grasses of the tallgrass prairie of the USA Great Plains to the economically important wheat pathogens Pyrenophora tritici‐repentis and Gaeumannomyces graminis var. tritici (Ggt) isolated from wheat. The P. tritici‐repentis isolates (race 1) were pathogenic on all grasses tested, but symptom severity was markedly low. Three of the grass species inoculated with Ggt were highly susceptible, while four species exhibited no symptoms. Because measures of connectedness can provide a proxy for population processes, connectedness was evaluated within and among the seven grass species in representative tallgrass prairie environments for all potential pathogen‐sharing patterns. Andropogon gerardii was ubiquitous, so all plant species were well connected to it. Andropogon scoparius (= Schizachyrium scoparium), Sorghastrum nutans and Panicum virgatum were fairly common but specialized to particular environments. Bouteloua curtipendula was uncommon but occurred in all environments, while Buchloë dactyloides and Bouteloua gracilis were uncommon and only occurred in upland sites. Co‐occurrence of plant species was generally not reciprocal in that, for many species pairs, species A rarely occurred without potential exposure to inoculum from species B, while species B commonly occurred without species A. The three grass species susceptible to Ggt may act as sources of inoculum for each other within tallgrass prairie, with the potential to influence fitness, and tallgrass prairie and commercial wheat ecosystems in the Great Plains also have the potential to share both pathogens. 相似文献
47.
《Communications in Soil Science and Plant Analysis》2012,43(15):2314-2326
Switchgrass and other perennial grasses have been promoted as biomass crops for production of renewable fuels. The objective of this study was to evaluate the effect of biomass removal on soil biogeochemical processes. A 3-year field study consisting of three levels of net primary productivity (NPP; low, medium, and high growing season precipitation) and two biomass crops (winter wheat and switchgrass) was conducted near Pendleton, Oregon. Switchgrass increased soil carbon (C)–nitrogen (N) ratio, but the effect varied with net primary productivity (NPP) and soil depth. In situ soil respiration (carbon dioxide; CO2) rate from switchgrass increased with NPP level but switchgrass had greater cumulative flux than wheat in medium and low NPP. Nitrogen mineralization and microbial biomass carbon were significantly greater under switchgrass than under wheat at high and medium NPP. Introduction of switchgrass initiates major changes in soil nutrient dynamics through organic-matter input. 相似文献
48.
《The Journal of Applied Poultry Research》2015,24(3):343-351
Chopped switchgrass (SG) and chopped bermudagrass (BG) were evaluated as alternatives to pine shavings (PS) for broiler litter over 3 flocks. Twenty-four pens were filled with the 3 litter types. Live performance parameters included mortality, BW, BW gain, feed consumption, and feed conversion. Mortality was not different for litter type or flock. All other live variables were different (P < 0.0001) for flock. Mean foot pad scores (FPS) were only different (P < 0.0001) for flock. Litter performance variables included litter and cake moisture content (MC), pH, litter ammonia concentration, and cake nutrient values [nitrogen, phosphorus, and potassium (N–P–K)]. Litter and cake MC differed by litter type and flock (P < 0.0001). Litter MC was 1% lower for SG than BG or PS. Cake depth observations were similar for litter type. Litter pH differed by flock (P = 0.008) while cake pH differed for both litter type (P = 0.05) and flock (P < 0.0001). Beginning and ending litter ammonia concentration were different for flock (P < 0.0001). Potassium was different for both litter type (P = 0.04) and flock (P < 0.0001) while nitrogen and phosphorus differed only by flock (P < 0.0001). Chopped SG and BG performed as well as PS as a litter material over 3 grow-out cycles. Based on the results of this study, chopped grass materials appear to be a viable alternative to PS for broiler bedding. 相似文献
49.
《Communications in Soil Science and Plant Analysis》2012,43(16):1959-1973
A root system has the plasticity to adapt to environmental change and species interaction. Root biomass and distribution were studied in three comparable stands in the fifth growth year (2005) in a semiarid region of northwest China: (1) pure switchgrass, (2) pure milk vetch, and (3) mixed switchgrass and milk vetch in 2:1 row replacement. The measurements were carried out three times (April, September, and November) in 2005 during the vegetation period using a soil core method (9 cm). For each species, the vertical distribution of root biomass (RB) was measured in six consecutive layers (0–20, 20–40, 40–60, 60–90, 90–120, and 120–150 cm deep) between rows, between plants, and at the center of the plant, respectively. Results indicated a flexible distribution strategy of switchgrass that tended to increase soil exploitation and space sequestration efficiency in soil layers. Milk vetch followed a more conservative strategy: its roots reached the same soil depth in the pure and mixed stands but showed greater root densities in shallower soil layers in the latter. Under intercropping, RB input and root/shoot ratio in switchgrass were reduced, while milk vetch put more photosynthate into root growth. The shift toward a more superficially distributed system of milk vetch in the mixture with switchgrass together with the high RB and wide vertical and horizontal distribution of switchgrass in the study indicates the greater belowground competitive ability of switchgrass in the mixture. 相似文献
50.