Understanding the Niche of Bioelectrochemical Systems for Water and Energy Sustainability

了解生物电化学系统在水和能源可持续性方面的应用

• 批准号: 1419938
• 负责人: Zhiyong Ren
• 金额: $ 20.93万
• 依托单位: University of Colorado at Boulder
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-01-13 至 2016-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1419938&HistoricalAwards=false
• 关键词: Understanding; Niche; Bioelectrochemical; Systems; Water

1235848 (Ren). Simultaneous wastewater treatment and energy generation has been a primary focus in bioelectrochemical systems (BES) research, but system performance is significantly reduced when using wastewater as the substrate compared to refined chemical substrates. BESs use microorganisms to catalyze the oxidization of organic and inorganic electron donors in the anode chamber and deliver electrons to the anode. The electrons can be captured directly for electricity generation (microbial fuel cells, MFCs) or supplemented by external power input for producing hydrogen, methane, or value-added chemicals (microbial electrolysis cells, MECs). The electrons can also be used in the cathode chamber to remediate contaminants such as uranium, chlorinated solvents, and perchlorate. The potential across the electrodes can also drive desalination (microbial desalination cells, MDCs). This project will use a systems approach to gain fundamental understanding of the unique features and mechanisms involved in various BES functions. The project team will also characterize, assess, and develop reactor systems to improve the applicability of the technology. Specifically, the team will: 1) Systematically characterize the interactions of different but complementary features for systems such as desalination and energy production from wastewater (treatment efficiency, electrochemical performance, ion transfer behavior, and microbial activity); 2) employ fundamental principles and findings to guide the development of BES configurations that can be integrated with current infrastructures for on-site wastewater treatment, energy production, and desalination; and 3) establish a life cycle assessment framework to provide quantitative analysis of the environmental impacts and energy footprint of BES technology as compared to existing technologies and direct system optimization and integration. Outcomes of this research should not only provide quantitative guidelines to facilitate the transformation of BES into a viable technology for wastewater infrastructure, but also advance the understanding and development of this technology for other applications such as bioremediation and biosensing. The work is targeted to address two crucial challenges facing our society - water and energy. In addition to the advancement of scientific understanding and development of bioelectrochemical systems, the proposed work provides an attractive platform for educating students and society to understand the Water-Energy Nexus and teaching them about interdisciplinary tools available for science and technology exploration. The project will academically and financially support graduate students focusing on the engagement of underrepresented groups. Partnerships with local TV stations and Denver Zoo have been established and will continue to be developed to educate and demonstrate environmental sustainability technology to the general public. The team will also use the research findings and system developments as education tools to capture K-12 students' interests in energy and environmental issues and encourage them to pursue careers in STEM areas.

1235848（任）。 同时废水处理和能量产生一直是生物电化学系统（BES）研究的主要焦点，但与精制化学基质相比，使用废水作为基质时，系统性能显着降低。 BES使用微生物来催化阳极室中有机和无机电子供体的氧化，并将电子传递到阳极。电子可以被直接捕获用于发电（微生物燃料电池，MFC）或通过外部电力输入补充以产生氢气，甲烷或增值化学品（微生物电解电池，MEC）。 电子也可以用于阴极室中，以修复污染物，如铀，氯化溶剂和高氯酸盐。跨电极的电势也可以驱动脱盐（微生物脱盐电池，MDC）。 该项目将采用系统方法，从根本上了解北京谱仪各种功能所涉及的独特特征和机制。该项目小组还将表征、评估和开发反应堆系统，以提高该技术的适用性。具体而言，该小组将：1）系统地表征系统的不同但互补的特征的相互作用，例如脱盐和从废水中产生能量（处理效率、电化学性能、离子转移行为和微生物活性）; 2）采用基本原理和发现来指导BES配置的开发，BES配置可以与现场废水处理、能源生产、和海水淡化;以及3）建立生命周期评估框架，与现有技术相比，对BES技术的环境影响和能源足迹进行定量分析，并指导系统优化和集成。这项研究的成果不仅应提供量化的指导方针，以促进将BES转化为废水基础设施的可行技术，而且还应促进对生物修复和生物传感等其他应用技术的理解和开发。 这项工作的目标是解决我们社会面临的两个关键挑战-水和能源。除了推进生物电化学系统的科学理解和发展外，拟议的工作还为教育学生和社会了解水-能源关系提供了一个有吸引力的平台，并向他们传授可用于科学和技术探索的跨学科工具。该项目将在学术和财政上支持研究生，重点是参与代表性不足的群体。与当地电视台和丹佛动物园的伙伴关系已经建立，并将继续发展，以教育和向公众展示环境可持续性技术。 该团队还将利用研究成果和系统开发作为教育工具，以捕捉K-12学生对能源和环境问题的兴趣，并鼓励他们在STEM领域从事职业。