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1	Hybridization between native and introduced populations of cattail and big bluestem: conservation implications Selbo, Sarena Marie January 2002 (has links) No description available. CRP angustifolia BIG BLUESTEM
2	Evaluation of Nitrogen Fertilization in C4 Grasses Grown for Bioenergy Engbers, Heather M 09 May 2012 (has links) Nitrogen fertilization has the potential to significantly affect yield, nutrient concentration and removal and overall stand longevity of C4 grasses grown for bioenergy production. While most studies report that these grasses need little to no fertilizer inputs to maximize yield, no specific recommendations have been given for fertilizer requirements across a wide range of C4 perennial grass species, cultivars, harvest timings and N application rates. Two field trials were established in the summer of 2008 in Ridgetown and Elora, Ontario to compare 4 Miscanthus (M. sinensis and M. sacchariflorus crosses; Nagara-116 and Amuri-114, and Miscanthus x giganteus; M1 Select and Polish), 2 switchgrass (Panicum virgatum L.; Cave-in-rock and Shelter) and 2 big bluestem varieties (Andropogon gerardii Vitman; Prairie view and Southlow), 4 nitrogen fertilization rates (0, 40, 80, and 160 kg N ha-1) and 2 harvest timings (fall vs. spring harvest). Plots were harvested in the fall of 2009 and spring and fall of 2010. Yield response to N fertilization varied by location, species and year. In general, increasing N fertilization rates generated an increased yield response in all tested species. Different rates of N fertilization resulted in variable responses to N, P and K tissue concentrations and removal in switchgrass and Miscanthus. Tissue N concentrations and removal both increased with added N fertilization at both locations. In most cases N removal was the highest at the highest N application rate. Nitrogen concentrations were highest in the leaves and seed heads across species, N rates and locations. P and K concentrations and removal with increasing N fertilization in the whole plant and in individual plant parts did not follow clear trends in either Miscanthus or switchgrass in both locations. Delaying harvest to spring reduced yield at both locations by 35-42% and 62-65% for Miscanthus and switchgrass, respectively. Yield losses by delaying harvesting to the spring were increased with higher rates of N fertilization. Delaying harvesting decreased N, P and K concentration and removal in most grasses and locations. bioenergy Miscanthus switchgrass N fertility big bluestem
3	Analysis of torrefaction of big bluestem and mixed grass from the Conservation Reserve Program Linnebur, Kyle Henry January 1900 (has links) Master of Science / Department of Biological and Agricultural Engineering / Donghai Wang / Biomass torrefaction is an important preprocessing step in improving biomass quality, specifically in terms of physical properties and chemical composition. The objective of this research was to study effects of torrefaction as a pretreatment method on chemical and elemental compositions and thermal properties of Conservation Reserve Program (CRP) biomass. Most CRP grasslands are a mixture of native grasses, and in the state of Kansas, species including indiangrass, big bluestem, little bluestem, sideoats grama, and switchgrass comprise a majority of CRP grounds. Pure forms of big bluestem biomass were analyzed and compared with a mixture of the species that make up CRP lands. Two strategies for torrefaction were tested: one with a pre-dry step and one without. After torrefaction, big bluestem and CRP biomass showed an increase in energy density, making the biomass more attractive as a biofuel source than raw biomass. Big bluestem also showed slightly higher calorific values than that of CRP biomass. The torrefaction process had a significant effect on chemical composition and elemental composition of the biomass. Carbon content increased and oxygen content decreased as torrefaction temperature increased. Glucan and xylose decreased and lignin increased as torrefaction temperature increased. Pre-drying biomass before torrefaction is beneficial to torrefaction of biomass with high moisture content because moisture removal leads to less dry matter loss while maintaining the same calorific value. Torrefaction Big bluestem Conservation Reserve Program Alternative Energy (0363) Energy (0791) Engineering, Agricultural (0539)
4	The effect of ecotype and planting location on properties and biofuels yield of big bluestem Zhang, Ke January 1900 (has links) Doctor of Philosophy / Department of Biological & Agricultural Engineering / Zhijian Pei / Donghai Wang / Renewable fuels derived from lignocellulosic biomass could reduce our dependence on fossil fuel resources and reduce greenhouse gas emissions. Big bluestem is an ecological-dominant warm-season (C4) perennial native grass that comprises as much as 80% of the plant biomass in prairies in the Midwestern grasslands of North America. Its high cellulosic content and low agricultural input recently have made big bluestem a promising feedstock for ethanol production. The overall goals of this study are to evaluate the potential of big bluestem in terms of ethanol production comparing with other native grasses by diluted sulfuric acid pretreatment and simultaneous sacchariﬁcation and fermentation and to understand the effects of ecotype and planting location on the chemical and elemental compositions and thermal properties as well as fermentable sugar yield of big bluestem along the Great Plains precipitation gradient. A total conversion efficiency of 79.2% and an ethanol concentration of 9.4 g/L were achieved after 72 h fermentation. About 0.262 kg (~0.332 Liters) ethanol could be produced from one kilogram dry mass of big bluestem under the present condition. Planting location had significant effects on chemical and elemental as well as specific heat, thermogravimetric parameters, high heating value and glucan mass yield. Ecotype had significant effects on glucan, xylan, lignin, and ash contents, and C, O, and H elemental fractions as well as specific heat, high heating value and glucan mass yield, whereas planting location significantly affected all measured variables. The ecotype-location interaction had significant effects on glucan, lignin, hydrogen contents and specific heat. Up to 97%, 88% and 80% of the variation in compositions can be explained by annual precipitation, growing degree days and potential evapotranspiration in 2010 respectively. Among all environmental factors, potential evapotranspiration had the most significant effect on thermal properties. Planting location had a stronger influence than ecotype and interaction between location and ecotype. Precipitation in 2010 possibly played a more significant role in divergence of glucan mass yield of the big bluestem. Big bluestem Ecotype Chemical composition Elemental composition Thermal properties Ethanol Biochemistry (0487)
5	Hydrothermal conversion of lignocellulosic biomass to bio-oils Gan, Jing January 1900 (has links) Doctor of Philosophy / Department of Biological and Agricultural Engineering / Wenqiao Yuan / Donghai Wang / Corncobs were used as the feedstock to investigate the effect of operating conditions and crude glycerol (solvent) on bio-oil production. The highest bio-oil yield of 33.8% on the basis of biomass dry weight was obtained at 305°C, 20 min retention time, 10% biomass content, 0.5% catalyst loading. At selected conditions, bio-oil yield based on the total weight of corn cobs and crude glycerol increased to 36.3% as the crude glycerol/corn cobs ratio increased to 5. Furthermore, the optimization of operating conditions was conducted via response surface methodology. A maximum bio-oil yield of 41.3% was obtained at 280°C, 12min, 21% biomass content, and 1.56% catalyst loading. A highest bio-oil carbon content of 74.8% was produced at 340°C with 9% biomass content. A maximum carbon recovery of 25.2% was observed at 280°C, 12min, 21% biomass content, and 1.03% catalyst loading. The effect of biomass ecotype and planting location on bio-oil production were studied on big bluestems. Significant differences were found in the yield and elemental composition of bio-oils produced from big bluestem of different ecotypes and/or planting locations. Generally, the IL ecotype and the Carbondale, IL and Manhattan, KS planting locations gave higher bio-oil yield, which can be attributed to the higher total cellulose and hemicellulose content and/or the higher carbon but lower oxygen contents in these feedstocks. Bio-oil from the IL ecotype also had the highest carbon and lowest oxygen contents, which were not affected by the planting location. In order to better understand the mechanisms of hydrothermal conversion, the interaction effects between cellulose, hemicellulose and lignin in hydrothermal conversion were studied. Positive interaction between cellulose and lignin, but negative interaction between cellulose and hemicellulose were observed. No significant interaction was found between hemicelluose and lignin. Hydrothermal conversion of corncobs, big bluestems, switchgrass, cherry, pecan, pine, hazelnut shell, and their model biomass also were conducted. Bio-oil yield increased as real biomass cellulose and hemicellulose content increased, but an opposite trend was observed for low lignin content model biomass. Hydrothermal conversion Lignocellulosic biomass Bio-oil Corn cob Big bluestem Energy (0791) Engineering, Agricultural (0539)
6	Herbicide Safening to Aid in the Establishment of Three Native Warm Season Grass Species Smith, Jesse Spencer 17 May 2014 (has links) Difficulties with stand establishment are a major factor limiting further agronomic use of native warm season grasses. One significant cause of stand failure is competition with rapidly growing annual weed species during the early development of the perennial native grass. Broad spectrum preemergent herbicides can provide the needed weed control, but only if tolerance exists in the desired grass. Herbicide safeners, synthetic compounds that protect crops from herbicide injury, applied as seed treatments offer a potential strategy to achieving the needed herbicide tolerance where it does not naturally occur. This study tested the efficacy of five herbicide safeners (benoxacor, fenclorim, fluxofenin, naphthalic anhydride, and oxabetrinil) in protecting three native warm season grass species (big bluestem, Andropogon gerardii Vitman; little bluestem, Schizachyrium scoparium (Michx.) Nash; indiangrass, Sorghastrum nutans (L.) Nash) from herbicidal injury caused by preemergent application of S-metolachlor and quantifies this establishment method’s impact on early stand performance. metolachlor benoxacor fenclorim fluxofenin oxabetrinil naphthalic anhydride big bluestem little bluestem indiangrass
7	Genomic differentiation of big bluestem (Andropogon gerardii) along the Great Plains’ environmental gradient Gray, Miranda M. January 1900 (has links) Master of Science / Department of Plant Pathology / Eduard D. Akhunov / Loretta C. Johnson / Big bluestem (Andropogon gerardii Vitman) is an ecologically dominant grass of the North American grasslands with precipitation-dependent productivity. However, climatic predictions for big bluestem’s dominant range in the Great Plains include increased periods of drought. The main objectives of this research were to determine the extent of neutral and non-neutral genetic differentiation and diversity among putative big bluestem ecotypes using amplified fragment length polymorphism (AFLP) markers. This is the first study of both neutral and non-neutral genetic diversity of big bluestem which also includes source populations of well-described ecotypes studied in reciprocal common gardens. A total of 378 plants were genotyped from 11 source prairies, originating from one of three ecoregions (Central Kansas, Eastern Kansas, and Illinois). Using two AFLP primer sets, 387 polymorphic markers (error rate 9.18%) were found. Un-rooted neighbor joining tree and principle-component analyses showed continuous genetic differentiation between Kansas and Illinois putative ecotypes, with genetic overlap occurring between Kansas ecotypes. Analysis of molecular variance showed high diversity within-prairie sites (80%) relative to across-prairies (11%), and across- ecoregions (9%) (p<0.001). Within-prairie genetic diversity levels were similar among ecoregions (84-92%), with the highest genetic variation maintained in Illinois prairies (92%). Population structure analyses supported K=6 genetic clusters across the environmental gradient, with Kansas prairies belonging to three main genetic groups, and Illinois prairies having largely divergent allele frequencies from Kansas prairies. Interestingly, BAYESCAN analysis of the three putative ecotypes identified eight F[subscript]ST-outlier AFLP loci under potential diversifying selection. Frequency patterns of loci under diversifying selection were further linked to geo-environmental descriptors including precipitation, temperature severity, diurnal temperature variation, prairie location, and elevation. The observed allele frequency divergence between Kansas and Illinois ecotypes suggests tallgrass restorations should consider possible maladaptation of non-local ecotypes and genetic swamping. However, high within-prairie genetic variation may help individual big bluestem populations withstand climatic variability. Big bluestem Tallgrass prairie Ecotype Genome scan Amplified fragment length polymorphism Genomic differentiation Biology (0306) Conservation Biology (0408) Genetics (0369)
8	Growth Response of Mixed Native Grass Stands to Simulated Grazing In Mississippi: Forage Yield and Species Dynamics Temu, Vitalis Wilbald 06 August 2011 (has links) Some native warm-season forage grasses [indiangrass (IG, Sorghastrum nutans), big bluestem (BB, Andropogon gerardii) and little bluestem (LB, Schizachyrium scoparium)] are gaining popularity for improving summer forage production and wildlife habitat in the southeastern USA. Paucity of information about appropriate harvest management limits their restoration success. An experiment was conducted to assess effects of harvest intervals (30-, 40-, 60-, 90 or 120-d) and harvest duration on forage yield and quality, plant growth, sward structure and botanical composition of their mixed stands at Bryan Farms, Clay County, MS. Total season forage was greatest for 30-d and more from first (8472 kg ha-1) than second year plots (7627 kg ha-1). Yield was reduced by up to 43% in the second harvest year. Forage quality (crude protein content and in vitro digestibility) decreased with lengthening of harvest interval and across the harvest season. Tiller weight increased while specific leaf area and relative growth rate decreased with lengthening of harvest interval in first and second year plots. Harvesting reduced sward heights the following May, but treatment did not affect sward heights. Season mean sward heights were shorter for short harvest intervals. Light interception was greatest in the control and decreased with shortening of harvest intervals. Continuous harvesting controlled Solidago canadensis, increased herbaceous forbs, and LB, but decreased IG without substantial effect on BB. Rotational harvesting at 30- or 40-d intervals may improve forage production without compromising breeding cover during recovery. Studies on other management practices including fertilizer application and timing of harvest are needed. cover composition digestibility fiber crude protein growth rate Forage warm-season grass defoliation frequency harvest sward stand height. leaf area assimilation ground-nestig wildlife habitat recovery summer harvest little bluestem big bluestem indiangrass canopy

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