Provides an accessible and relatable approach for understanding how much energy we use in our day-to-day lives Daily Energy Use and Carbon Emissions enables readers to directly evaluate their energy use, estimate the resulting carbon emissions, and use the information to better appreciate and address the impact their activities have on climate change. Using quantities and terms rooted in everyday life, this easy-to-understand textbook helps readers determine the energy they consume driving a car, preparing a meal, charging electronic devices, heating and cooling a house or apartment, and more. Throughout the text, clear explanations, accurate information, and numerous real-world examples help readers to answer key energy questions such as: How much energy does your house use in a month? What impact will turning off lightbulbs in your home have on energy conservation? Which car emits more CO2 into the atmosphere per mile, a 50 MPG gasoline car or a 100 MPG equivalent electric car? Demonstrating the relation between daily energy use, carbon emissions, and everyday activities in a new way, this innovative textbook: Examines daily activities within the context of the basic needs: energy, food, air, and water Covers topics such as daily water use, renewable energy, water and energy sources, transportation, concrete and steel, and carbon capture and storage Includes discussion of energy and CO2 emissions relative to infrastructure and population growth Provides supplemental teaching material including PowerPoint slides, illustrative examples, homework assignments, discussion questions, and classroom quizzes with answers Daily Energy Use and Carbon Emissions: Fundamentals and Applications for Students and Professionals is a perfect textbook for students and instructors in Environmental Engineering programs, and an essential read for those pursuing careers in areas related to energy, environment, and climate change.

The theory, design, construction, and operation of microbial fuel cells
Microbial fuel cells (MFCs), devices in which bacteria create electrical power by oxidizing simple compounds such as glucose or complex organic matter in wastewater, represent a new and promising approach for generating power. Not only do MFCs clean wastewater, but they also convert organics in these wastewaters into usable energy. Given the world's limited supply of fossil fuels and fossil fuels' impact on climate change, MFC technology's ability to create renewable, carbon-neutral energy has generated tremendous interest around the world.
This timely book is the first dedicated to MFCs. It not only serves as an introduction to the theory underlying the development and functioning of MFCs, it also serves as a manual for ongoing research. In addition, author Bruce Logan, a leading pioneer in MFC research and development, provides practical guidance for the effective design and operation of MFCs based on his own firsthand experience.
This reference covers everything you need to fully understand MFCs, including:
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Key topics such as voltage and power generation, MFC materials and architecture, mass transfer to bacteria and biofilms, bioreactor design, and fundamentals of electron transfer
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Applications across a wide variety of scales, from power generation in the laboratory to approaches for using MFCs for wastewater treatment
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The role of MFCs in the climate change debate
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Detailed illustrations of bacterial and electrochemical concepts
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Charts, graphs, and tables summarizing key design and operation variables
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Practice problems and step-by-step examples
Microbial Fuel Cells, with its easy-to-follow explanations, is recommended as both a textbook for students and professionals interested in entering the field and as a complete reference for more experienced practitioners.