Relevant bibliographies by topics / Biomass energy production

Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Academic literature on the topic 'Biomass energy production'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 February 2022

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Journal articles on the topic "Biomass energy production"

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Sastry, S. V. A. R. "Harnessing Biomass Energy for the Production of Biodiesel." International Journal of Engineering and Technology 4, no. 3 (2012): 279–81. http://dx.doi.org/10.7763/ijet.2012.v4.365.

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PARMAR, RAGHUVIRSINH, ASEEM VERMA, RITU DOGRA, and URMILA GUPTA. "Energy production from biomass." INTERNATIONAL JOURNAL OF AGRICULTURAL ENGINEERING 10, no. 2 (October 15, 2017): 655–63. http://dx.doi.org/10.15740/has/ijae/10.2/655-663.

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A. Conesa, Juan, and A. Domene. "Synthesis gas production from various biomass feedstocks." AIMS Energy 1, no. 1 (2013): 17–27. http://dx.doi.org/10.3934/energy.2013.1.17.

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Malovanyy, Myroslav, Volodymyr Nikiforov, Olena Kharlamova, and Olexander Synelnikov. "Production of Renewable Energy Resources via Complex Treatment of Cyanobacteria Biomass." Chemistry & Chemical Technology 10, no. 2 (June 15, 2016): 251–54. http://dx.doi.org/10.23939/chcht10.02.251.

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The process of cyanobacteria complex treatment via obtaining of inedible fat, suitable for the production of biodiesel and biogas has been investigated. The prospective application of hydrodynamic cavitation to increase the efficiency of inedible fat extraction and biogas synthesis is shown. A comprehensive strategy for the cyanobacteria use in the energy and agricultural technologies is suggested.
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Nedjah, N., N. Laskri, D. Daas, and M. Baccouche. "Ethanol Production of Biomass Rich in Sugar: Energy and Environmental Opportunity." Journal of Clean Energy Technologies 6, no. 4 (July 2018): 320–23. http://dx.doi.org/10.18178/jocet.2018.6.4.482.

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Ratho, Bhuvnesh. "Biomass Extraction of Energy Transformation." Journal of Advanced Research in Power Electronics and Power Systems 07, no. 1&2 (May 13, 2020): 1–6. http://dx.doi.org/10.24321/2456.1401.202001.

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The focus of this is to make available clean energy, where there is a need for electricity production or energy infrastructure. An anaerobic digester contains an oxygen free environment that allows microorganisms to break down the organic material to harvest biogas (methane). Once the biogas is formed it can be used for different applications to aid the developing world. There are already millions of biogas plants in operation throughout the world. In Germany and other industrialized countries, power generation is the main purpose of biogas plants; conversion of biogas to electricity has become a standard technology. Biomass can become a reliable and renewable local energy source to replace conventional fossil fuels in local industries and to reduce reliance on overloaded electricity grids. The concept presented is to use manure from farms to produce methane gas using anaerobic digestion.
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Ciolkosz, D. "Torrefied biomass in biofuel production system." Scientific Horizons 93, no. 8 (2020): 9–12. http://dx.doi.org/10.33249/2663-2144-2020-93-8-9-12.

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Ukraine produces large amounts of crop residues every year, much which could be utilized to produce biofuel. However, efficient supply chains and system configurations are needed to make such systems efficient and cost effective. One option is to integrate torrefaction, power production and biofuel production into a single, coordinated system. This approach allows for high value product (i.e. biofuel), greater utilization of the energy content of the feedstock, and supply chain efficiency. Initial analyses indicate that revenues can be enhanced through this approach, and further analyses and optimization efforts could identify a sustainable approach to renewable fuel and power production for Ukraine. The question of scale and layout remains of interest as well, and a thorough logistical study is needed to identify the most suitable configuration. Agricultural operations often benefit from smaller scales of operation, whereas fuel production processes tend to operate profitably only at very large scale. Thus, a balance must be struck between the needs of both ends of the supply chain. The processing center concept helps to balance those needs. A system such as this also has potential to synergize with other agricultural production systems, such as the production of animal feed, fertilizer, and other bio-based products. The complexities of the Ukrainian agricultural market will need to be reflected carefully in any model that seeks to assess the system's potential. Presents a concept for coupling thermal pretreatment (torrefaction with biofuel and power production for the transformation of wheat straw into a value added product for Ukraine. Torrefaction provides supply chain savings, while conversion provides added value to the product. This paradigm has potential to utilize a widely produced waste material into a valuable source of energy and possibly other products for the country.
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Yoon, Hyungchul, Sungho Cho, Dock-jin Lee, Goyoung Moon, and Soonhaing Cho. "SNG Production from Wood Biomass with Dual Fluidized-Bed Gasifier." Journal of Energy Engineering 25, no. 4 (December 30, 2016): 214–25. http://dx.doi.org/10.5855/energy.2016.25.4.214.

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McKendry, Peter. "Energy production from biomass (part 1): overview of biomass." Bioresource Technology 83, no. 1 (May 2002): 37–46. http://dx.doi.org/10.1016/s0960-8524(01)00118-3.

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Patzek, Tad W., and David Pimentel. "Thermodynamics of Energy Production from Biomass." Critical Reviews in Plant Sciences 24, no. 5-6 (September 2005): 327–64. http://dx.doi.org/10.1080/07352680500316029.

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Dissertations / Theses on the topic "Biomass energy production"

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Hahn, John J. "Hydrogen production from biomass." Diss., Columbia, Mo. : University of Missouri-Columbia, 2006. http://hdl.handle.net/10355/4387.

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Thesis (Ph. D.) University of Missouri-Columbia, 2006.
The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Title from title screen of research.pdf file (viewed on August 1, 2007) Includes bibliographical references.
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Aleksic, Snezana. "Butanol Production from Biomass." Connect to resource online, 2009. http://rave.ohiolink.edu/etdc/view?acc_num=ysu1242762960.

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Hemstock, Sarah Louise. "Multi-dimensional modelling of biomass energy flows." Thesis, King's College London (University of London), 1999. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.313680.

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Li, Difu. "Fermentative hydrogen production from wastewater by immobilized biomass." Click to view the E-thesis via HKUTO, 2007. http://sunzi.lib.hku.hk/HKUTO/record/B39557728.

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Li, Difu, and 李迪夫. "Fermentative hydrogen production from wastewater by immobilized biomass." Thesis, The University of Hong Kong (Pokfulam, Hong Kong), 2007. http://hub.hku.hk/bib/B39557728.

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Gardner, Nick. "Assessment of methane production from refuse-infills." Thesis, Cranfield University, 1992. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.334751.

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Yang, Yang. "Energy production from biomass and waste derived intermediate pyrolysis oils." Thesis, Aston University, 2015. http://publications.aston.ac.uk/25356/.

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This study investigates the use of Pyroformer intermediate pyrolysis system to produce alternative diesel engines fuels (pyrolysis oil) from various biomass and waste feedstocks and the application of these pyrolysis oils in a diesel engine generating system for Combined Heat and Power (CHP) production. The pyrolysis oils were produced in a pilot-scale (20 kg/h) intermediate pyrolysis system. Comprehensive characterisations, with a view to use as engine fuels, were carried out on the sewage sludge and de-inking sludge derived pyrolysis oils. They were both found to be able to provide sufficient heat for fuelling a diesel engine. The pyrolysis oils also presented poor combustibility and high carbon deposition, but these problems could be mitigated by means of blending the pyrolysis oils with biodiesel (derived from waste cooking oil). The blends of SSPO (sewage sludge pyrolysis oil) and biodiesel (30/70 and 50/50 in volumetric ratios) were tested in a 15 kWe Lister type stationary generating system for up to 10 hours. There was no apparent deterioration observed in engine operation. With 30% SSPO blended into biodiesel, the engine presents better overall performance (electric efficiency), fuel consumption, and overall exhaust emissions than with 50% SSPO blend. An overall system analysis was carried out on a proposed integrated Pyroformer-CHP system. Combined with real experimental results, this was used for evaluating the costs for producing heat and power and char from wood pellets and sewage sludge. It is concluded that the overall system efficiencies for both types of plant can be over 40%; however the integrated CHP system is not economically viable. This is due to extraordinary project capital investment required.
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Schiener, Peter. "Bioethanol production from macroalgae." Thesis, University of the Highlands and Islands, 2014. https://pure.uhi.ac.uk/portal/en/studentthesis/bioethanol-production-from-macroalgae(d1c0fd4d-3a91-4d17-be4f-0b7b2af86e11).html.

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Seaweed biomass has been identified as a potential fermentation substrate for third generation biofuel processes due to its high carbohydrate content and its potential for mass cultivation without competing for agricultural land, fresh water and fertilisers. This thesis aimed to develop and advance existing processes to convert brown seaweeds into bioethanol. The main kelp species chosen as biomass candidates were Laminaria digitata, Laminaria hyperborea, Saccharina latissima and Alaria esculenta due to their abundance in Scottish waters and their identified potential for mariculturing. These kelp species were chemically characterised to identify seasonal variations, to recommend suitable seaweed candidates for bioethanol production and predict best harvest times. This has only been demonstrated before on one species - L. digitata. The chemical composition analyses were carried out over a 14 months sampling period, which focused on the storage carbohydrates laminarin and mannitol and the structural carbohydrates alginate, cellulose, fucoidan and xylose. In addition to carbohydrates the protein, nitrogen, carbon, polyphenol, ash and metal content was also profiled. Chemical profiling identified all four kelps as potential fermentation candidates, where maximum carbohydrate contents coincided with lowest ash and polyphenol content, usually seen in autumn. Biomass pre-treatment and saccharification are up-stream processes aimed at enhancing extraction of carbohydrates and converting those into fermentable substrates. Conversion of seaweed biomass into fermentation substrate evaluated acids and enzymes for seaweed pre-treatment and saccharification. Methodologies focused on optimising saccharification yields were developed to identify process critical parameters and develop methods for routine analysis of seaweed biomass. Results demonstrated that dilute acid hydrolysis was were less effective in releasing fermentable sugars, and also resulted in higher salinities compared to enzymatic hydrolysis using hemicellulosic and cellulosic enzymes, which were the preferred method of saccharification. All seaweeds in this thesis were assessed as fermentation substrates using the yeasts S. cerevisiae and P. angophorae, that principally ferment glucose or mannitol, respectively. Small-scale fermentation assays were developed for both yeasts to maximise ethanol yields and achieve process robustness. Both yeasts achieved a maximum ethanol yield of 0.17 g g-1 using Laminaria spp. On the basis of results, S. cerevisiae is recommended as the most useful yeast at this present point for ethanol fermentation from seaweed hydrolysates because of its tolerance to high salinity and ethanol concentrations. As salinity can negatively affect non-halotolerant enzymes, isolation of marine microorganisms was therefore carried out with the aim to highlight their enzymatic potential in seaweed saccharification. This was achieved through the isolation of two members of the genus Pseudoalteromonas, where saccharification yields using crude intracellular enzyme preparations exceeded those of dilute acids. In addition, the fermentative potential of microbial isolates as future ethanologenic strains was also evaluated. Understanding of the metabolic pathways is needed to fully assess the potential of those strains for genetic alteration. In conclusion, this thesis has demonstrated that up to ca. 20 g l-1 of ethanol can be produced from kelp species that grow on the west coast of Scotland. The procedure developed and used to produce ethanol requires further development, specifically the need for ethanol-fermenting microorganisms that can utilize mannitol and alginate; use of marine-adapted enzymes for saccharifiction; and the development of processes to achieve substrate concentration with reduced salinities. Comparison of theoretical ethanol yields from seaweed biomass with ethanol yields from terrestrial crops showed that the complete utilisation of all three major seaweed carbohydrates (laminarin, mannitol and alginate) from kelp species is needed for the process to be able to compete with 1st generation biofuel processes.
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Dutta, Baishali. "Assessment of Pyrolysis techniques of lignocellulosic biomass for Biochar production." Thesis, McGill University, 2010. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=95255.

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Biomass pyrolysis at temperatures above 300°C, with the biochar being returned to the soil is a possible strategy for climate change mitigation and reducing fossil fuel consumption. In this study, an attempt has been made to develop a finite element model (FEM) in order to couple thermal heating and heat and mass transfer phenomena during pyrolysis. This numerical modelling and simulation approach helped the visualization of the process and optimized the production of biochar. In this work, cylindrical sections of birch wood biomass were pyrolysed in a laboratory-scale thermal desorption unit. The influences of final pyrolysis temperature, heating rate, and pyrolysis atmosphere on the product yields were investigated. Results showed that the yield of pyrolysis products was reduced with increasing time and temperature. On the other hand, the char content in the wood increased together with increasing pyrolysis temperature as well as time for both slow and fast pyrolysis. A technique to maximize the amount of char in the product was also identified through this study and optimized along with the yield. The resulting biochar was tested through proximate analysis and differential scanning calorimetry to determine its thermodynamic qualities, which were analysed and compared according to their physical characteristics like porosity and reflectance.
La pyrolyse de biomasse à des températures excédant 300°C, suivi d'un retour au sol du produit de carbonisation de matériel biologique, s'avère une stratégie permettant de possiblement atténuer le changement climatique et réduire la consommation de combustibles fossiles. Dans la présente étude, nous tentâmes de créer un modèle d'éléments finis (MEF) permettant de coupler le réchauffement thermique et les phénomènes de transfert de chaleur et de masse opérant durant la pyrolyse. Cette démarche de modélisation et simulation numérique améliora notre habilité à visualiser le procédé et à optimiser la production de biochar. Des sections cylindriques de biomasse de bois de bouleau furent soumises à une pyrolyse dans un désorbeur thermique de laboratoire. L'influence de la température finale de pyrolyse, la vitesse d'élévation de température, et l'atmosphère de pyrolyse fut investiguée. Les résultants démontrèrent que tandis que le rendement en produits de pyrolyse diminua avec une augmentation de la température et du temps de la pyrolyse, le contenu en charbon du bois augmenta avec une augmentation ces paramètres, tout autant pour une pyrolyse lente qu'une pyrolyse rapide. A travers cette démarche, nous identifiâmes une technique permettant de maximiser la quantité de charbon dans les produits de pyrolyse ainsi que le rendement global du procédé. Le biochar ainsi généré fut testé par analyse immédiate et analyse calorimétrique à compensation de puissance afin de déterminer ses propriétés thermodynamiques, qui furent analysées et comparées selon les caractéristiques physiques des différents biochars, soit leur porosité et leur réflectance. fr
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Hall, Stephen. "Optimisation of biogas production from percolating packed bed anaerobic digesters." Thesis, University of South Wales, 1986. https://pure.southwales.ac.uk/en/studentthesis/optimisation-of-biogas-production-from-percolating-packed-bed-anaerobic-digesters(6825c6bf-4ee7-439e-832a-28aa8b7cd4d3).html.

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Percolating packed bed digesters were operated successfully in a batch mode using a wheat straw - dairy manure substrate of between 21 and 27% total solids. The vessels used had a nominal 10 1 volume and were constructed of perspex. Temperatures of 25-35°C were used, recirculation rates of 0-15 litres.hr-1 (the digesters having a diameter of 0.18 metres thus corresponding to superficial flow rates of between O and 0.382 l/m2 /hr), solid : liquid ratios of 1:1 to 4:1 and bed heights of 0.26 to 2.05 metres. The optima found were a temperature of 35°C, recirculation rate of 3 litres.hr1-, a solid: liquid ratio of 2:1 and a bed height of 1.5 metres. Experiments were conducted for periods of up to 70 days, though operation beyond a 40 day period was found to produce little extra biogas. The performance compared favourably with other high solids waste digesters with gas yields of 0.305 m 3 /kg VS added and solids losses of 47% volatile solids and 64% cellulose being obtained over a 40 day period. No major problems of inhibition or blocking occurred. Linking of digesters in series via their recirculation systems was found to be advantageous. Gas yields were found to be increased by approximately 18% and solids losses increased by approximately 20% when the waste was treated in this semicontinuous manner. These increases were found to be a result of the rapid transfer of well-adapted bacteria to the fresh digester. Lag phase in the fresh digester was reduced by three days and potentially inhibitory levels of volatile fatty acids were not present. Concentrations of up to around 5000 ppm VFAs were found during the start-up of batch digesters causing some inhibition of gas production. During semi-continuous operation however concentrations of around 2000 ppm were developed when fresh digesters were linked in, no inhibition occurred and in fact this concentration proved stimulatory to gas production. Experimentation into the optimum retention time of a maximum of three digesters in series was conducted, with retention times of 90, 60 and 30 days being considered. A 30 day retention period was found to depress gas production due to unstable conditions when fresh digesters were added by up to 32% compared with Batch Operation. Gas production was increased at both 60 and 90 day retention times by amounts similar to those previously stated. A retention time of 60 days was found to be optimum as little extra gas was produced after this time, with volatile solids losses being increased by only 9.3% by operating for a further 30 days. Colonisation of the solid substrate was shown to be rapid, by the use of adenosine 51 triphosphate analysis, gas production rate and electron microscope analysis. In addition a dynamic bacterial population appeared to be present in the solid phase with the rates of growth and attachment being approximately equal to the rates of decay and detachment. When digesters were operating in their steady phase, methanogens were present in the liquor at concentrations of between 10 6 - 10 7 /ml and non-methanogens at between 10 7 - 108 /ml showing a large population of bacteria to be present for the inoculation of fresh digesters.
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Books on the topic "Biomass energy production"

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Biofuels production. Salem, Massachusetts: Scrivenor Publishing, 2014.

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Philp, R. J. Methanol production from biomass. Ottawa, Ont: National Research Council of Canada, 1986.

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Garcia-Maraver, A., and J. A. Pérez-Jiménez. Biomass pelletization: Standards and production. Southhampton, UK: WIT Press, 2015.

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Haggerty, Alfred P. Biomass crops: Production, energy, and the environment. Hauppauge, N.Y: Nova Science Publisher's, 2010.

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Rommer, Thomas E. World biofuels production potential. Hauppauge, N.Y: Nova Science Publishers, 2009.

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Kerstetter, James D. Biomass resources. Portland, Or: Northwest Power Planning Council, 1989.

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Fuel production from non-food biomass: Corn stover. Oakville, ON Canada: Apple Academic Press, 2015.

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Helynen, Satu. Production and consumption potentials for bioenergy in Finland to the year 2010. Espoo [Finland]: Technical Research Centre of Finland, 1999.

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Gu, Tingyue. Green Biomass Pretreatment for Biofuels Production. Dordrecht: Springer Netherlands, 2013.

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Kaminsky, Jacob. Development of strategies for deployment of biomass resources in the production of biomass power: [final report]. Golden, CO: National Renewable Energy Laboratory, 2004.

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Book chapters on the topic "Biomass energy production"

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Ernst, Michaela, Achim Walter, and Ulrich Schurr. "Biomass biomass Production biomass production." In Renewable Energy Systems, 510–21. New York, NY: Springer New York, 2013. http://dx.doi.org/10.1007/978-1-4614-5820-3_242.

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Ryther, John H. "Marine Biomass Production." In Biomass Energy Development, 241–57. Boston, MA: Springer US, 1986. http://dx.doi.org/10.1007/978-1-4757-0590-4_22.

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Stover, Enos L., Reinaldo Gonzales, and Ganapathi Gomathinayagam. "Methane Production and Utilization at Fuel Alcohol Production Facilities." In Biomass Energy Development, 487–501. Boston, MA: Springer US, 1986. http://dx.doi.org/10.1007/978-1-4757-0590-4_39.

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Burton, Glenn W. "Biomass Production from Herbaceous Plants." In Biomass Energy Development, 163–71. Boston, MA: Springer US, 1986. http://dx.doi.org/10.1007/978-1-4757-0590-4_15.

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Soltes, Ed J. "Thermochemical Processes for Bioenergy Production." In Biomass Energy Development, 321–31. Boston, MA: Springer US, 1986. http://dx.doi.org/10.1007/978-1-4757-0590-4_27.

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Kocsis, K. "FAO/CNRE Research Cooperation on Biomass Production and Use for Energy." In Biomass Energy, 144–56. Dordrecht: Springer Netherlands, 1987. http://dx.doi.org/10.1007/978-94-011-7879-2_21.

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Di Palma, M., and G. Barbieri. "An Approach to the Economic Evaluation of Biomass Energy Production Projects." In Biomass Energy, 310–16. Dordrecht: Springer Netherlands, 1987. http://dx.doi.org/10.1007/978-94-011-7879-2_41.

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Takagi, Toshiyuki. "Energy Production: Biomass – Marine." In Yeast Cell Surface Engineering, 29–41. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-13-5868-5_3.

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Lisa, L. "Harvesting and Storage of Chipped Wood for Energy Production in Hill Areas." In Biomass Energy, 67–74. Dordrecht: Springer Netherlands, 1987. http://dx.doi.org/10.1007/978-94-011-7879-2_10.

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Gurjar, Rishi, and Manaswini Behera. "Biopolymer: Production from Biomass." In Clean Energy Production Technologies, 371–90. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-9593-6_14.

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Conference papers on the topic "Biomass energy production"

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Khumsak, Onarin, Weerapong Wattananoi, and Nakorn Worasuwannarak. "Bio-oil production from the torrefied biomass." In 2011 IEEE Conference on Clean Energy and Technology (CET). IEEE, 2011. http://dx.doi.org/10.1109/cet.2011.6041438.

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Kimura, Hiroki, Yuto Takeuchi, Yasushi Yamamoto, and Satoshi Konishi. "Hydrogen Production from Biomass using Nuclear Fusion Energy." In 21st IEEE/NPS Symposium on Fusion Engineering SOFE 05. IEEE, 2005. http://dx.doi.org/10.1109/fusion.2005.252960.

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Wang, Xiaoming, Tang Lan, Wang Huan, Haiqing Hao, Yunhe Wang, Chihui Zhu, and Haitao Huang. "Assessment of Biomass Energy Production Potential in China." In 2010 Asia-Pacific Power and Energy Engineering Conference. IEEE, 2010. http://dx.doi.org/10.1109/appeec.2010.5448178.

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Dražić, Nikola, Jela Ikanović, and Gordana Dražić. "Smart Sensor Monitoring in Energy Crop Biomass Production." In Sinteza 2021. Beograd, Serbia: Singidunum University, 2021. http://dx.doi.org/10.15308/sinteza-2021-102-106.

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Pilon, G., and J. M. Lavoie. "Biomass char production at low severity conditions under CO2and N2environments." In Energy and Sustainability 2011. Southampton, UK: WIT Press, 2011. http://dx.doi.org/10.2495/esus110101.

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Viar, Nerea, Jesus Requies, Ion Agirre, and Pedro Luis Arias. "2,5 DMF Production from Biomass Using Heterogenous Catalysts." In 10TH International Conference on Sustainable Energy and Environmental Protection. University of Maribor Press, 2017. http://dx.doi.org/10.18690/978-961-286-048-6.29.

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Tausova, Marcela. "ECONOMICAL ANALYSIS OF THE ELECTRIC ENERGY PRODUCTION FROM BIOMASS." In SGEM2011 11th International Multidisciplinary Scientific GeoConference and EXPO. Stef92 Technology, 2011. http://dx.doi.org/10.5593/sgem2011/s22.113.

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Yanti, Fusia Mirda, Novio Valentino, Asmi Rima Juwita, S. D. Sumbogo Murti, Astri Pertiwi, Nurdiah Rahmawati, Tyas Puspita Rini, et al. "Methanol production from biomass syngas using Cu/ZnO/Al2O3 catalyst." In INTERNATIONAL ENERGY CONFERENCE ASTECHNOVA 2019. AIP Publishing, 2020. http://dx.doi.org/10.1063/5.0000870.

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Zheng, Chaocheng. "Three generation production biotechnology of biomass into bio-fuel." In GREEN ENERGY AND SUSTAINABLE DEVELOPMENT I: Proceedings of the International Conference on Green Energy and Sustainable Development (GESD 2017). Author(s), 2017. http://dx.doi.org/10.1063/1.4992924.

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ANDRIES, J., W. DE JONG, and H. SPLIETHOFF. "PRODUCTION OF SUSTAINABLE HYDROGEN USING THERMOCHEMICAL GASIFICATION OF BIOMASS." In 2004 New and Renewable Energy Technologies for Sustainable Development. WORLD SCIENTIFIC, 2007. http://dx.doi.org/10.1142/9789812707437_0007.

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Reports on the topic "Biomass energy production"

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Morris, G. Biomass Energy Production in California 2002: Update of the California Biomass Database. Office of Scientific and Technical Information (OSTI), December 2002. http://dx.doi.org/10.2172/15002488.

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Morris, G. Biomass Energy Production in California: The Case for a Biomass Policy Initiative; Final Report. Office of Scientific and Technical Information (OSTI), December 2000. http://dx.doi.org/10.2172/772427.

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Taylor, Steve, Timothy McDonald, Oladiran Fasina, Tom Gallagher, Mathew Smidt, Dana Mitchell, John Klepac, et al. High Tonnage Forest Biomass Production Systems from Southern Pine Energy Plantations. Office of Scientific and Technical Information (OSTI), September 2014. http://dx.doi.org/10.2172/1341084.

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Charles Sink, Chugachmiut, and EERC Keeryanne Leroux. The Potential for Biomass District Energy Production in Port Graham, Alaska. Office of Scientific and Technical Information (OSTI), May 2008. http://dx.doi.org/10.2172/927962.

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Salk, M. S., and A. G. Folger. Characterization of the southwest United States for the production of biomass energy crops. Office of Scientific and Technical Information (OSTI), March 1987. http://dx.doi.org/10.2172/6730855.

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Sweeten, John, Kalyan Annamalai, Brent Auvermann, Saqib Mukhtar, Sergio C. Capareda, Cady Engler, Wyatte Harman, et al. RENEWABLE ENERGY AND ENVIRONMENTAL SUSTAINABILITY USING BIOMASS FROM DAIRY AND BEEF ANIMAL PRODUCTION. Office of Scientific and Technical Information (OSTI), May 2012. http://dx.doi.org/10.2172/1039337.

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Kalyan Annamalai,, John M. Sweeten,, Brent W. Auvermann,, Saqib Mukhtar,, Sergio Caperada, Cady R. Engler,, Wyatte Harman, Reddy JN, and Robert Deotte. RENEWABLE ENERGY AND ENVIRONMENTAL SUSTAINABILITY USING BIOMASS FROM DAIRY AND BEEF ANIMAL PRODUCTION. Office of Scientific and Technical Information (OSTI), May 2012. http://dx.doi.org/10.2172/1039414.

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John M. Sweeten,, Kalyan Annamalai, Brent Auvermann, Saqib Mukhtar, Sergio C. Capareda, Cady Engler, Wyatte Harman, et al. RENEWABLE ENERGY AND ENVIRONMENTAL SUSTAINABILITY USING BIOMASS FROM DAIRY AND BEEF ANIMAL PRODUCTION. Office of Scientific and Technical Information (OSTI), May 2012. http://dx.doi.org/10.2172/1039415.

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Sweeten, John M., Kalyan Annamalai, Brent Auvermann, Saqib Mukhtar, Sergio C. Capareda, Cady Engler, Wyatte Harman, et al. RENEWABLE ENERGY AND ENVIRONMENTAL SUSTAINABILITY USING BIOMASS FROM DAIRY AND BEEF ANIMAL PRODUCTION. Office of Scientific and Technical Information (OSTI), May 2012. http://dx.doi.org/10.2172/1039417.

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Perlack, R. D., J. W. Ranney, and L. L. Wright. Environmental emissions and socioeconomic considerations in the production, storage, and transportation of biomass energy feedstocks. Office of Scientific and Technical Information (OSTI), July 1992. http://dx.doi.org/10.2172/7256087.

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