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Corn stalk as a bioenergy resource /Haney, Paul E., January 2003 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 2003. / Typescript. Vita. Includes bibliographical references. Also available on the Internet.
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Corn stalk as a bioenergy resourceHaney, Paul E., January 2003 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 2003. / Typescript. Vita. Includes bibliographical references. Also available on the Internet.
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Industrial sweetpotato a viable biofuel crop for Alabama /Monday, Tyler Anthony, Foshee, Wheeler G., January 2009 (has links)
Thesis--Auburn University, 2009. / Abstract. Vita. Includes bibliographical references.
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Energetické využití fytomasy / Energetical use of phytomassBLAHO, Milan January 2008 (has links)
The objective of the thesis is proposing types of crops suitable for the production of phytomass for power purposes in low favourite areas (LFA). The assignment was summarising the source data for a broader set of power crops obtained from multiple authors primarily from the Czech Republic, and assessing their suitability for growing in LFA in areas sorted by environment requirements (soil, pH, weather conditions, vegetation period, resistance to frost, resistance to pests and diseases,{\dots}) and by production capability and energy parameters (yield, height of plants, combustion heat, caloric value, humidity, ash content, {\dots}) Field tests with suitable power crops were established and economic models were generated based on the results of the cultivation to demonstrate the possibilities of utilisation in reality
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Utilization of upland phytomass for fuel陳榮均, Chen, Rongjun. January 1993 (has links)
published_or_final_version / abstract / toc / Botany / Doctoral / Doctor of Philosophy
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Jerusalem artichoke: a potential solar crop for food and energy suppliesLee, Chao-Chou. January 1978 (has links)
Call number: LD2668 .T4 1978 L43 / Master of Science / Chemical Engineering
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CONTRIBUTIONS OF WOODY BIOMASS TO ENERGY REQUIREMENTS IN ARIZONA.Tolisano, James Anthony. January 1984 (has links)
No description available.
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The potential of bio-energy crops to meet Europe's energy needs and reduce greenhouse emissionsHastings, Astley St. John January 2009 (has links)
This thesis focuses on determining the potential of bio-energy crops to contribute to Europe’s future energy needs and to reduce future greenhouse gas emissions. This requires an end-to-end (seed to exhaust gas) analysis of the crop production and enabling technology in terms of energy use and greenhouse gas emissions. The starting point of this research was to consider which energy crops had the potential to grow in future European climate scenarios and to determine those for which models did not exist to make this prediction. <i>Miscanthus</i> was identified as a relatively new crop with 15 years of European growing experience but with limited previous model development. MISCANMOD, a simple model of <i>Miscanthus</i> crop growth, was improved and rewritten in FORTRAN so that it could be interfaced to use climate scenario, soil property and land use data bases to predict energy yields for current and future climate scenarios. A greenhouse gas emissions and energy balance model was added to investigate the sustainability of <i>Miscanthus</i> as a bio-energy crop. This model was combined with data from other energy crop predictions to determine the energy yields and GHG mitigation of different crops for the various scenarios of future climate, each considering the soil conditions, land available and climatic conditions. We conclude that <i>Miscanthus</i> is the crop with the highest energy yield and largest carbon mitigation potential of all the available energy crops, and that the maximum amount of primary energy that could be produced by bio-energy crops in Europe would represent only 12% of EU 25’s primary energy needs. The carbon intensity of such energy is estimated to be 24% of that for gas. To achieve this level of energy production we show that it is necessary to develop drought and frost resistant hybrids to increase the range of the <i>Miscanthus</i> crop for current and future climate scenarios. This demonstrates that bio-energy is not a panacea but must be considered as part of the strategy to achieve sustainable energy whilst mitigating greenhouse gas emissions.
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Soil greenhouse gas emissions and soil C dynamics in bioenergy cropsBottoms, Emily L. January 2012 (has links)
The second generation bioenergy crops Miscanthus x giganteus and short rotation coppice (SRC) willow are the two main bioenergy crops in the UK and have become an integral part of legislation to provide an alternative to fossil fuels and to reduce national greenhouse gas (GHG) emissions. To reach emission targets, it is estimated that approximately 350,000 ha of land could be made available for bioenergy crops by 2020. Despite the promise of these crops, there have been very few field-studies regarding soil GHG (CO2, CH4 and N2O) emissions and many of the published studies are life cycle analyses or modelled fluxes from soils using default values from the IPCC. The first aim of this research was to quantify the in situ soil GHG budget and to establish the drivers of these GHG fluxes for Miscanthus and SRC willow. The second aim of this research was to provide a more in-depth understanding of C cycling under Miscanthus i.e. litter and roots through two field experiments. Overall, the results from this work confirm minimal emissions of CH4 and N2O from soil under Miscanthus and SRC willow. CO2 flux was found to be the major efflux from soils and it was found in Miscanthus, that the majority of this flux was derived from below ground respiration. Litter played an important part in providing nutrients to the soil, which is vital in systems that are not fertilised. Litter also contributed to SOM accumulation on the soil surface and may promote long-term C sequestration. The results from this work combined with other literature would suggest that these second generation crops offer advantages to first generation crops, but more field-based studies are required to say if they can offer the large-scale GHG savings needed to be a viable alternative to fossil fuels.
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Climate Suitable Energy Crops and Biomass Energy Potentials : Assessment of the Current and Future Prospects in EstoniaWiréhn, Lotten January 2010 (has links)
Development of biomass energy plantations is one approach to mitigate and adapt to climate change and the energy challenges related to it; however, climate change will affect the climate conditions and in turn the selection of crops and trees suitable for renewable energy sources. In Estonia, electricity is mainly based on oil shale but since their integration in the European Union they are required to increase the share of energy from renewable sources. In this study, the possible changes of suitable species are assessed by examining the current and the future prospects and potentials with biomass energy derived from energy plantations in Estonia, taking climate change into consideration. The biomass energy potentials for the species that are climate suitable in current and future time are manually estimated, using a case study approach when determining the yields. The study result suggests that biomass energy from crops and trees have great development possibilities and that climate is not a key limitation for the selection of suitable species; in addition, the energy crops and trees appear to suit the future climate conditions better than the current. The results indicate that the established national target of 25% of energy from renewable sources in gross final consumption of energy by 2020 could be achieved to a large extent by putting energy plantations into practice.
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