Global ETD Search

101	Enhanced Microbial Respiration of Photodegraded Leaf Litter at High Relative Humidity is Explained by Relative Water Content Rather Than Vapor Uptake Rate or Carbon Quality January 2019 (has links) abstract: There is a growing consensus that photodegradation accelerates litter decomposition in drylands, but the mechanisms are not well understood. In a previous field study examining how exposure to solar radiation affects decomposition of 12 leaf litter types over 34 months in the Sonoran Desert, litter exposed to UV/blue wavebands of solar radiation decayed faster. The concentration of water-soluble compounds was higher in decayed litter than in new (recently senesced) litter, and higher in decayed litter exposed to solar radiation than other decayed litter. Microbial respiration of litter incubated in high relative humidity for 1 day was greater in decayed litter than new litter and greatest in decayed litter exposed to solar radiation. Respiration rates were strongly correlated with decay rates and water-soluble concentrations of litter. The objective of the current study was to determine why respiration rates were higher in decayed litter and why this effect was magnified in litter exposed to solar radiation. First, I evaluated whether photodegradation enhanced the quantity of dissolved organic carbon (DOC) in litter by comparing DOC concentrations of photodegraded litter to new litter. Second, I evaluated whether photodegradation increased the quality of DOC for microbial utilization by measuring respiration of leachates with equal DOC concentrations after applying them to a soil inoculum. I hypothesized that water vapor sorption may explain differences in respiration among litter age or sunlight exposure treatments. Therefore, I assessed water vapor sorption of litter over an 8-day incubation in high relative humidity. Water vapor sorption rates over 1 and 8 days were slower in decayed than new litter and not faster in photodegraded than other decayed litter. However, I found that 49-78% of the variation in respiration could be explained by the relative amount of water litter absorbed over 1 day compared to 8 days, a measure referred to as relative water content. Decayed and photodegraded litter had higher relative water content after 1 day because it had a lower water-holding capacity. Higher respiration rates of decayed and photodegraded litter were attributed to faster microbial activation due to greater relative water content of that litter. / Dissertation/Thesis / Masters Thesis Biology 2019 Ecology Biogeochemistry Biology litter decomposition photodegradation plant litter respiration water sorbtion water vapor
102	Impacts of leaf litter diversity and root resources on microorganisms and microarthropods (Acari, Collembola) during early stages of decomposition in tropical montane rainforest ecosystems Sánchez Galindo, Laura Margarita 18 February 2021 (has links) No description available. 570 Litter decomposition Decomposer microarthropods Litter diversity Root-derived resources Microorganisms Tropical montane rainforests Biologie (PPN619462639)
103	Production and Biodegradation of Dissolved Carbon, Nitrogen and Phosphorous from Canadian Forest Floors Turgeon, Julie January 2009 (has links) No description available. Forest litter -- Canada.
104	Production and biodegradation of dissolved carbon, nitrogen and phosphorus from Canadian forest floors Turgeon, Julie. January 2008 (has links) No description available. Forest litter -- Canada.
105	Effects of Litter Reuse on Performance, Welfare, and the Microbiome of the Litter and Gastrointestinal Tract of Commercial Broiler Chickens Cressman, Michael David 02 June 2014 (has links) No description available. Animal Sciences broiler litter reuse ammonia moisture welfare litter composting Illumina sequencing
106	Interactive Effects of Litter Quality and Invertebrates on Litter Decomposition Rates Across a Successional Gradient Baroudi, Robby Hassan 14 July 2016 (has links) No description available. Ecology Biology terrestrial succession litter decomposition litter quality nutrients detritivore disturbance
107	Nutrient Availability from Poultry Litter Co-Products Middleton, Amanda Jo 03 August 2015 (has links) Phosphorus (P) is a nutrient of concern in the Chesapeake Bay watershed due to nutrient imbalances in areas with confined animal feeding operations. By converting poultry litter to an ash via thermal conversion, nutrients are concentrated and are economical to ship out of nutrient surplus watersheds to nutrient deficient regions, such as the corn-belt. We initiated incubation and field studies on sandy loam soils to test P and potassium (K) availability from poultry litter ash (PLA). Four PLA products, derived from different sources using different combustion techniques, and 2 biochar products were characterized. Poultry litter (PL) co-products were compared to a no-fertilizer control and inorganic P (triple super phosphate; TSP) and inorganic K (muriate of potash; KCl) fertilizer at similar rates. In the incubation study, standard fertilizers (TSP and PL) had the greatest initial availability for P (55.50% TSP; 9.13% PL) and K (97.99% PL), respectively. The PL co-products varied in availabilities based on thermo-conversion system from 1.60- 8.63% for P to 8.14- 88.10% for K. One ash co-product (ASH4) produced similar availabilities to the industry standard fertilizers after 56 days. In conclusion, co-products from combustion thermo-conversion systems were found be superior to gasification and pyrolysis systems when the desire was to produce the most plant available P and K dense PL co-products. In the field studies, yield, Mehlich-I extractable soil nutrients, plant tissue and grain samples, and organic matter content was used to compare treatments. Poultry litter ash co-products were highly variable due to the thermo-conversion system and feedstock of formation. If all ideal combustion criteria are met, then PL co-products are feasible to use as fertilizer sources, but will need to be individually analyzed for nutrient content before making application recommendations. A greater amount of the co-products will have to be applied to meet the same nutrient availability of the standards due to their lower availability. Fresh PL tends to be the better fertilizer due to its added N content, which is lost in thermo-conversion systems and would have to be supplemented with the ash co-products. Biochars tend to be less available than their ash counter parts. More research using the water soluble availabilities instead of the total concentration nutrients of the co-products are needed to be able to identify stronger relationships with standard fertilizers. / Master of Science poultry litter poultry litter ash thermo-conversion nutrient management Phosphorus potassium Water quality soil nutrient cycle
108	Evaluating the effects of poultry litter amendments on Escherichia coli populations, virulence genes, and antimicrobial-resistance genes in poultry litter during a live grow-out. Henson, Faith 10 May 2024 (has links) (PDF) Poultry litter can harbor pathogenic bacteria, including avian pathogenic Escherichia coli (APEC). Applying litter amendments is one strategy to improve bird health and potentially reduce pathogens. Biochar and PLT were applied as litter amendments in a live bird trial to study their effects on E. coli populations, APEC virulence genes (VAG), and antimicrobial resistance (AMR) genes. Samples were collected at days 0, 17, 29, and 41 to enumerate E. coli and store bacterial isolates for antimicrobial-resistance gene analysis. Data analysis showed litter amendments did not significantly affect overall E. coli populations. Grow-out time impacted E. coli populations, with reductions occurring over time. Litter treatment had no impact on the prevalence of VAG or AMR. Time showed VAGs were absent at d 0 while AMR genes were prevalent at d 0. This indicates chicks may have been the source of VAG, while AMR genes were prevalent in used litter.
109	Linking Microbial Community Dynamics to Litter and Soil Chemistry: Understanding the Mechanisms of Decomposition Herman, John E. 08 September 2010 (has links) No description available. Ecology Environmental Science Soil Sciences Litter decomposition extracellular enzyme lignin lignocellulose DGGE copiotrophic oligotrophic litter chemistry microbial community litter mixtures Amynthas agrestis urban-rural gradient Guild Decomposition Model
110	ECOSYSTEM IMPACTS OF THE INVASIVE SHRUB <i>LONICERA MAACKII</i> ARE INFLUENCED BY ASSOCIATIONS WITH NATIVE TREE SPECIES Poulette, Megan Marie 01 January 2012 (has links) Invasive species are significant drivers of global environmental change, altering the stability and functioning of numerous ecosystems. The exotic shrub Lonicera maackii is an aggressive invader throughout much of the eastern United States. While much is known about its population and community impacts, little is known about effects on ecosystem processes. This dissertation documents changes in ecosystem processes associated with L. maackii growing beneath three native tree species (Fraxinus quadrangulata, Quercus muehlenbergii, Carya ovata) in a savanna in Kentucky. Like many invasive plants, L. maackii litter decomposed and lost nitrogen (N) rapidly, especially in comparison with native tree litter. In comparison to the soils beneath the trees where the exotic shrub was absent, soils beneath L. maackii had a lower bulk density, elevated soil organic matter, C:N, and total soil N and a modified soil microbial community. Inorganic N deposition from spring throughfall was also altered by L. maackii, with higher NO3-N deposition beneath shrubs located beneath the tree canopy relative to canopy locations without L. maackii. While many exotic plant species have been shown to alter ecosystem processes, their impact is often not uniform. This variability is attributed to among-site differences (soil, climate, plant community): within site variability is often ignored. While many of L. maackii’s alterations to ecosystem processes were uniform across the site, several were dependent upon interactions between the exotic and the native tree species. Litter from L. maackii decomposed and lost N more rapidly under C. ovata than under the other native tree species. Soils beneath L. maackii shrubs located under C. ovata also had a greater fungal:bacterial ratio and a greater abundance of the saprophytic fungal lipid biomarker 18:1ω9c. These results demonstrate that L. maackii’s impact extends to ecosystem processes and suggests that invasive plants may have variable effects within a given environment depending on their interactions with the dominant native species. Identifying native species or communities that are more vulnerable to alterations of ecosystem function upon invasion may prove useful to land managers and foster a better understanding of the role that community dynamics play in moderating or enhancing invasive species impacts. Biological invasion litter decomposition Lonicera maackii nitrogen soil processes Biology

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