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Item Composition analysis of canola and intermediate wheatgrass biomass and the effects of extraction(BioResources, 2023-01) Johnsrude, Lauren M.; Scheffel, Aidan J.; Allen, Brett L.; Wettstein, Stephanie G.Knowing the composition of biomass is critical for determining accurate yields of renewable chemicals and fuels; however, nonstructural components can affect the results of standard composition procedures, leading to inaccurate reactant amounts. To remove these nonstructural components, solvent extractions can be done, but the impact on composition values has not been well-reported. For this study, compositional analysis was performed on as-received canola (Brassica napus) and intermediate wheatgrass (Thinopyrum intermedium), as well as ethanol, water, and water/ethanol extracted biomasses. Water/ethanol extraction of the intermediate wheatgrass resulted in significantly lower xylose and both acid soluble and insoluble lignin amounts when compared to the as-received analysis. Since sugar was removed during the extractions, it is recommended to use the as-received composition values for glucuronoarabinoxylans; however, the extractives may interfere with the lignin analysis and therefore, the extracted lignin values are likely more reflective of the composition.Item Influence of pretreatment, lignin extraction, and chemical modification on lignin properties and the performance of lignin-formaldehyde resins and lignin-PLA composite materials(Montana State University - Bozeman, College of Engineering, 2022) Saulnier, Brian Keith; Chairperson, Graduate Committee: David Hodge; This is a manuscript style paper that includes co-authored chapters.Bio-ethanol can be produced from lignocellulosic biomass in a biorefinery as part of a three step process, a chemical or mechanical pretreatment, enzymatic hydrolysis of the cell wall, and fermentation of these sugars to ethanol. One of the byproducts of this process is lignin, a complex biopolymer composed of a heterogeneous aromatic structure. Lignin is often burned to provide energy for the biorefinery. Incorporating lignin into higher-value products is crucial to the viability of the biorefinery process and the full utilization of the renewable carbon contained in biomass. Challenges to the inclusion of lignin in value-added products include recalcitrance of the cell wall to deconstruction and lignin extraction, heterogeneity of the lignin chemical structure, polydisperse molecular weight distributions, and low reactivity. In this thesis we address these challenges by using feedstock selection, selection of pretreatment and lignin extraction process conditions, lignin fractional precipitation, and direct chemical modification of lignin. Chapter 1 provides an overall introduction and background of previous work. Chapter 2 uses a diverse panel of corn stover genotypes subjected to dilute acid pretreatment using a variety of process conditions. The response of the biomass to pretreatment was characterized with special attention given to glucose hydrolysis yields and p-coumarate (pCA) content. Chapter 3 uses a single corn stover source pretreated using a variety of dilute acid conditions followed by two different lignin extraction methods. The influence of pretreatment and lignin extraction conditions on lignin properties was characterized with focus on lignin pCA content. This study found that lignin-formaldehyde resins using lignin from optimized process conditions achieved lap shear strengths higher than conventional phenol-formaldehyde resins. Chapter 4 addresses lignin polydispersity and heterogeneity using the fractional precipitation of lignin from formic acid liquors to obtain differing molecular weight lignin fractions while allowing for successful enzymatic hydrolysis of cellulose. Chapter 5 uses fractional precipitation of corn stover alkali liquors along with modification using propylene carbonate to obtain a panel of multi-component biopolymer fractions for manufacture of biopolymer-PLA composite materials. These materials were fully characterized finding materials made with modified biopolymers exhibited better lignin dispersion, and improved thermal and mechanical properties.Item Conversion of biomass sugars to platform chemicals by homogeneous acid catalyst in organic water mixtures(Montana State University - Bozeman, College of Engineering, 2022) Scheffel, Aidan James; Chairperson, Graduate Committee: Stephanie Wettstein; This is a manuscript style paper that includes co-authored chapters.Lignocellulosic biomass could serve as an alternative to petroleum for the production of platform chemicals that can be upgraded to bio-based plastics, chemicals, and fuels. The polysaccharides present in the cellular structure of biomass can be hydrolyzed into common sugars, which can be further reacted into important chemical intermediates such as furfural, 5-hydroxymethylfurfural, and levulinic acid. However, current commercial processes typically result in low yields. This work aimed to study the conversion of model sugars (glucose, xylose, and arabinose) into platform chemicals using a homogeneous acid catalyst in a variety of organic-water mixtures, and compare those findings to reactions carried out using biomass under the same conditions. Reactions were performed in 50-50 solvent-water mixtures using sulfolane, tetrahydrofuran (THF), or gamma-butyrolactone (GBL) as the solvent and using a sulfuric acid catalyst. Intermediate wheatgrass was used in the biomass reactions and its composition was determined using standard NREL methods. Similar trends were observed in both pure sugar and biomass reactions in which the solvent choice had little effect on maximum yield of furfural, HMF, or levulinic acid. However, the THF/water solvent achieved maximum yields at lower severities than the other solvent mixtures indicating that a combination of less time, lower temperature, and/or less acid could be used in the THF reactions compared to the others. Compared to previously published research that found the solvent polarity correlated with product yields of furfural in reactions with no acid present, the effects of solvent properties may be minimized by the presence of the acid catalyst. Higher yields were achieved in biomass reactions than in pure sugar reactions, possibly due to unaccounted for reaction pathways or lowering of degradation reaction rates due to a lower initial reactant weight percent.Item Influence of lithogenic energy on subglacial microbial community composition(Montana State University - Bozeman, College of Agriculture, 2021) Dunham, Eric Corwin; Chairperson, Graduate Committee: Eric Boyd; John E. Dore, Mark L. Skidmore, Eric E. Roden and Eric S. Boyd were co-authors of the article, 'Lithogenic hydrogen supports microbial primary production in subglacial and proglacial environments' in the journal 'Proceedings of the National Academy of Sciences of the United States of America' which is contained within this dissertation.; K. Rebecca Mitchell, Mark L. Skidmore and Eric S. Boyd were co-authors of the article, 'Influence of ferric iron on community composition in a basaltic glacial catchment' which is contained within this dissertation.Chemosynthesis, the generation of biomass using chemical energy, supported life on early Earth and continues to sustain contemporary light-independent ecosystems. The mechanisms of nutrient release from the geosphere are critical to understanding the present and historical distribution and diversity of life. Glaciers release such nutrients through comminution of bedrock, continuously resurfacing reactive minerals that can be colonized and exploited by chemosynthetic microorganisms. Bedrock mineralogy influences the nutrients available in these environments, but little is known about which nutrients are most important or how they affect microbial community composition, particularly in catchments overlying igneous bedrock like basalt. Iron and silicate minerals, common in basalt, readily generate both reductants such as H 2 and oxidants such as Fe(III) through interactions with water. Abundant H 2 in meltwaters of the basalt-based Icelandic glacier Kotlujokull (KJ) were found to support sediment microbial communities better adapted to use H 2 in chemosynthetic metabolism than those found beneath the carbonate-based Robertson Glacier (RG), Canada. KJ communities exhibited shorter lag-times and faster rates of net H 2 oxidation and dark carbon dioxide (CO 2) fixation than those from RG. A KJ sediment enrichment culture provided with H 2, CO 2, and Fe(III) produced a chemolithoautotrophic population related to Rhodoferax ferrireducens, which was also detected using molecular techniques in sediments from Kaldalonsjokull (Kal), another basalt-based Icelandic glacier. The abundance and composition of microbial communities that colonized defined minerals incubated for 12 months in Kal meltwater streams were examined by extracting DNA and sequencing PCR-amplifiable 16S rRNA genes. DNA quantities and the composition of 16S rRNA genes recovered from Kal sediments were most similar to those recovered from incubated Fe(III)-bearing minerals hematite and magnetite, with putative Fe(III) reducers dominating all three communities. These findings point to the importance of bedrock mineral composition in influencing the supplies of nutrients like H 2 and Fe(III) that, in turn, influence the diversity, abundance, and activity of microbial communities in subglacial environments. They further indicate the potential for subglacial habitats to serve as refugia for microbial communities in the absence of sunlight, such as during Snowball Earth episodes, or on icy planets without photosynthetic life.Item Long term multispecies cover crops in semi-arid Montana: soil response and aboveground biomass(Montana State University - Bozeman, College of Agriculture, 2020) D'Agati, Kristen Mary; Chairperson, Graduate Committee: Catherine A. Zabinski; Perry Miller (co-chair); Perry R. Miller, Clain A. Jones and Catherine Zabinski were co-authors of the article, 'Soil biological effects of herbicide-terminated multi-species cover crop mixes, in semi-arid Montana' which is contained within this thesis.; Catherine Zabinski, Clain A. Jones and Perry R. Miller were co-authors of the article, 'Aboveground biomass quality and quantity of long-term multispecies cover crop mixes, in the semi-arid Montana' which is contained within this thesis.; Maryse Bourgault, Perry R. Miller, Clain A. Jones and Catherine Zabinski were co-authors of the article, 'Soil biological response to spraying, grazing, or haying of long-term multispecies cover crops in semi-arid Montana' which is contained within this thesis.Low and variable annual precipitation (250-350 mm) make management strategies that conserve soil moisture imperative for wheat producers in semi-arid Montana. A wheat-fallow rotation was historically the most common dryland cropping system in semi-arid Montana, due to its ability to conserve soil water; however, summer fallow has negative environmental impacts (Campbell et al., 1991). There is interest to incorporate cover crops into a rotation as a partial replacement for summer fallow to enhance soil quality. An eight-yr study explored the effect of cover crops on biological soil properties through aboveground biomass inputs of four plant functional groups: brassica (BC), fibrous root (FR), tap root (TR), and nitrogen fixers (NF) grown as two-species mixes, six-species mixes (three functional groups), a full eight-species mix, and two controls--chemical fallow and sole pea. Cover crops grew for about 60 days, were terminated with glyphosate, then soil samples were taken nine months after termination at wheat seeding. The only difference in biological parameters based on functional group was that mycorrhizal colonization in wheat was higher following FR than BC at one site. Potentially mineralizable nitrogen (PMN) was 1.6-1.7 times higher and microbial biomass was 1.4 times higher in soils from cover crop treatments relative to fallow at one of two sites. PMN was 1.2-1.3 times higher in soils from six-species mixes than two-species mixes at both sites, and six-species mixes produced 1.4 times more biomass at one site. Nitrogen fixers had the lowest C:N ratio of the functional groups at both sites, while FR had the highest at one site. In a second study of cover crop termination, cover crops were grown about 90 days and terminated with one of three strategies: chemically, grazing, or haying. Soils were sampled nine months after termination at the time of wheat seeding. Few enzyme differences and no PMN differences or meaningful patterns were discovered among termination strategies. Minimal differences in biological parameters, even when shoot biomass was removed, may mean grazing or haying could improve net revenue without detracting from soil health. In semi-arid annual systems, water limitations may be the main concern with growing cover crops.Item Spatial and temporal variations of phytoplankton populations in Lake Bonney, Antarctica(Montana State University - Bozeman, College of Agriculture, 2003) Tursich, Nicole LeaItem Grasslands of the Missouri Coteau and their relationship to environment(Montana State University - Bozeman, College of Letters & Science, 2003) Plaggemeyer, John Bernard; Chairperson, Graduate Committee: Theodore W. WeaverItem Near real-time satellite and ground based radiometric estimation of vegetation biomass, and nitrogen content in Montana rangelands(Montana State University - Bozeman, College of Agriculture, 1998) Thoma, David P.Item Using Advanced Very High Resolution Radiometer (AVHRR) satellite images to map snow cover and green biomass in Yellowstone National Park(Montana State University - Bozeman, College of Letters & Science, 2000) Hanson, Donay