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We have come to know that our ability to survive and grow as a nation to a very large degree depends upon our scientific progress. Moreover, it is not enough simply to keep abreast of the rest of the world in scientific matters. 1 We must maintain our leadership. President Harry Truman spoke those words in 1950, in the aftermath of World War II and in the midst of the Cold War. Indeed, the scientific and engineering leadership of the United States and its allies in the twentieth century played key roles in the successful outcomes of both World War II and the Cold War, sparing the world the twin horrors of fascism and totalitarian communism, and fueling the economic prosperity that followed. Today, as the United States and its allies once again find themselves at war, President Truman’s words ring as true as they did a half-century ago. The goal set out in the Truman Administration of maintaining leadership in science has remained the policy of the U.S. Government to this day: Dr. John Marburger, the Director of the Office of Science and Technology (OSTP) in the Executive Office of the President made remarks to that effect during his confirmation hearings in October 2 2001.
Bioelectrochemistry is a fast growing field linking together electrochemistry, biochemistry, medicinal chemistry and analytical chemistry. The current book outlines the recent progress in the area and the applications in biological materials design and bioenergy, covering in particular biosensors, bioelectronic devices, biofuel cells, biodegradable batteries and biomolecule-based computing.
Nanobioelectrochemistry covers the modern aspects of bioelectrochemistry, nanoscience and materials science. The combination of nanostructured materials and biological molecules enables the development of biodevices capable to detect specific substances. Furthermore, by using the bioelectrochemistry approach, the interaction between bio-systems and nanostructured materials can be studied at the molecular level, where several mechanisms of molecular behavior are elucidate from redox reactions. The combination of biological molecules and novel nanomaterials components is of great importance in the process of developing new nanoscale devices for future biological, medical and electronic applications. This book describes some of the different electrochemical techniques that can be used to study new strategies for patterning electrode surfaces with enzymes, organelles, cells and biomimetic systems. Also, it focuses on how enzymes and microorganisms can be used as biological catalysts in fuel cells for green power generation. By bringing together these different aspects of nanobioelectrochemistry, this book provides a valuable source of information for many students and scientists.
This book highlights the importance of various emerging technologies that are used to clean up the environment from pollution caused by human activities. It assesses several existing applied and environmental microbiological techniques and introduces new technologies through applied aspects. Select topics covered include municipal wastewater treatment, environmental microorganisms, metal pollutants in the environment, and biogeochemical cycling.
Since four decades, rapid detection and monitoring in clinical and food diagnostics and in environmental and biodefense have paved the way for the elaboration of electrochemical biosensors. Thanks to their adaptability, ease of use in relatively complex samples, and their portability, electrochemical biosensors now are one of the mainstays of analytical chemistry. In particular, electrochemistry has played a pivotal role in the development of transduction methods for biological processes and biosensors. In parallel, the explosion of activity in nanoscience and nanotechnology and their huge success have profoundly affected biosensor technology, opening new avenues of research for electrode ma...
This book explores the production and applications of biochar. This material is used to remove contaminants from industrial effluent and to reutilize waste sludge in the production of biofuel/bioenergy. The treatment of wastewater and reuse of waste sludge in value added products manufacturing and environmental clean-up is explored. This book provides a roadmap for future strategies for pollution abatement and sustainable development.
This is a critical assessment of breakthrough biosensor technologies that will allow for the rapid identification of biological threat agents in the environment and human population. The book provides a comprehensive overview of the current state of biological weapons threat, and reviews biosensor technologies including detection platforms, networked alarm-type biodetector systems, implementation strategies, electro-optical and electrochemical biosensors.
Bioelectrochemistry is a fast growing field linking together electrochemistry, biochemistry, medicinal chemistry and analytical chemistry. The current book outlines the recent progress in the area and the applications in biological materials design and bioenergy, covering in particular biosensors, bioelectronic devices, biofuel cells, biodegradable batteries and biomolecule-based computing.
This is an interdisciplinary book for biomimetic nanotechnology, that correlates the biology on the molecular scale with nanotechnology mimicking human senses and movement. The introduction provides the background in life science, chemistry, material science, and engineering needed to understand sensors and movement on the molecular level. The chapters discuss human movement, vision, smell and taste, hearing, and touch. Each chapter explains the sense or movement on the molecular level, then discusses nanotechnology that uses the human molecules or mimics the function of the human sense and movement on the nanoscale. This is an excellent book for senior undergraduates and graduate students in the life sciences, chemistry, material sciences, and engineering. It will also appeal to any reader with an interest in life sciences and nanotechnology.