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Anaerobic Degradation of Marine Algae, Seagrass and Tropical Climbing Vines to Produce a Renewable Energy Source and the Analysis of Their Anaerobic Microbial Communities.

机译：海藻，海草和热带攀缘藤的厌氧降解产生可再生能源及其厌氧微生物群落分析。

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Energy demand by contemporary societies and the excessive consumption of fossil fuels have impulsed research and the employment of renewable energy systems. It has been proposed, in terms of renewable systems, the use of biofuels generated by the degradation of organic matter, like bioethanol, biodiesel and methane, being this last one the more efficient one based on its calorific value. For this reason we propose the implementation of anaerobic reactors which degrade biomass that has relatively high growth rates, require low quantity of nutrients and eliminate any competition by its use, thus creating a cost-effective system. Tropical climbing vines provide biomasses with the previous characteristics; however, they contain high concentrations of cellulose and lignin that are polymers difficult to degrade. In contrast, biomass like marine algae contains low concentrations of both lignin and cellulose, which should make them an easier material for degradation. Finally, in comparison to marine algae another source of marine biomass, which can serve as biomass for the creation of these systems, is seagrasses. Nonetheless, seagrasses are more related to terrestrial plants than marine algae for which they could present the same difficulties towards degradation as climbing vines. This study aims to compare the efficiency of three different vegetation biomasses (marine algae, seagrass and tropical climbing vines) as primary substrate for anaerobic reactors. Moreover, to achieve what could be a highly cost effective system, the isolation and identification of anaerobic alginate degraders was studied. Alginate is a complex polysaccharide present in marine algae s cell wall, representing up to 40% of its dry weight. The study was completed creating anaerobic microcosms, which contained 0.016 g/mL (0.5 g total biomass) of each biomass. Methane and intermediaries produced were determined for each microcosm.

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Marquez-Nogueras, K. M.; Rios-Hernandez, L.;
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年度 2013
页码 1-101
总页数 101
原文格式 PDF
正文语种 eng
中图分类工业技术;
关键词
Algae; Anaerobic processes; Aquatic plants; Biomass conversion; Microbiology; Chemical analysis; Deoxyribonucleic acids; Electrophoresis; Genes; Methane; Morphology; Renewable energy; Ribonucleic acids; Theses; Anaerobic microbial communities; Molecular analysis; Dna(deoxyribonucleic acids); Rna(ribonucleic acids); Dna extraction; 16s rrna genes; Gel electrophoresis; Alginate degraders; Methane production; Marine algae; Seagrasses; Tropical climbing vines; Pe206022;

机译：藻类;厌氧过程;水生植物;生物质转化;微生物学;化学分析;脱氧核糖核酸;电泳;基因;甲烷;形态学;可再生能源;核糖核酸;论文;厌氧微生物群落;分子分析; Dna（脱氧核糖核酸）; Rna（核糖核酸; Dna提取; 16s rrna基因;凝胶电泳;藻酸盐降解;甲烷生产;海藻;海草;热带攀缘藤蔓; pe206022;

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专利

1. Evaluation of marine algae as a source of biogas in a two-stage anaerobic reactor system [J] . Alberto Vergara-Ferndndez, Gisela Vargas, Nelson Aarcon, Biomass & bioenergy . 2008,第4期

机译：在两级厌氧反应器系统中评估海藻作为沼气的来源
2. Using an anaerobic digestion tank as the anodic chamber of an algae-assisted microbial fuel cell to improve energy production from food waste [J] . Water Research . 2020,第Mara1期

机译：使用厌氧消化池作为藻类辅助微生物燃料电池的阳极室，以改善食物垃圾产生的能量
3. Green energy from marine algae: biogas production and composition from the anaerobic digestion of Irish seaweed species [J] . C.H. Vanegas, J. Bartlett Environmental Technology . 2013,第13a14期

机译：海藻的绿色能源：爱尔兰海藻物种厌氧消化产生的沼气和组成
4. BIOGAS, AS A RENEWABLE ENERGY SOURCE, PRODUCED DURING THE ANAEROBIC DIGESTION OF ORGANIC WASTE [C] . H. Greben, L. M. Burke, S. Szewczuk ISES Solar World Congress . 2009

机译：沼气，作为可再生能源，在厌氧消化的有机废物中产生
5. Developing Protocols to Facilitate the Enrichment and Characterization of Hydrocarbon-degrading Anaerobic Microbial Communities. [D] . Moore, Eve. 2009

机译：制定协议，以促进降解烃的厌氧微生物群落的富集和表征。
6. Microbial Anaerobic Digestion (Bio-Digesters) as an Approach to the Decontamination of Animal Wastes in Pollution Control and the Generation of Renewable Energy [O] . Christy E. Manyi-Loh, Sampson N. Mamphweli, Edson L. Meyer, 2013

机译：微生物厌氧消化（生物消化器）作为污染控制和可再生能源产生中动物粪便去污的一种方法
7. Start-up Method of Anaerobic Digestion by Anaerobic Self-Degradation of Waste Activated Sludge and Microbial Community Shift during Self-Degradation [O] . Takuro KOBAYASHI, Daisuke YASUDA, Yu-You LI, 2008

机译：厌氧自我降解废物活性污泥的厌氧消化的启动方法及自我降解期间的微生物群落

Anaerobic Degradation of Marine Algae, Seagrass and Tropical Climbing Vines to Produce a Renewable Energy Source and the Analysis of Their Anaerobic Microbial Communities.

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