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Electrochemistry of Porous Materials describes essential theoretical aspects of the electrochemistry of nanostructured materials and primary applications, incorporating the advances in the field in the last ten years including recent theoretical formulations and the incorporation of novel materials. Concentrating on nanostructured micro- and mesoporous materials, the highly anticipated Second Edition offers a more focused and practical analysis of key porous materials considered relatively homogeneous from an electrochemical point of view. The author details the use of electrochemical methods in materials science for characterization and their applications in the fields of analysis, energy production and storage, environmental remediation, and the biomedical arena. Additional features include: Incorporates new theoretical advances in the voltammetry of porous materials and multiphase porous electrochemistry. Includes new developments in sensing, energy production and storage, degradation of pollutants, desalination and drug release. Describes redox processes for different porous materials, assessing their electrochemical applications. Written at an accessible and understandable level for researchers and graduate students working in the field of material chemistry. Selective and streamlined, Electrochemistry of Porous Materials, Second Edition culls a wide range of relevant and practically useful material from the extensive literature on the subject, making it an invaluable reference for readers of all levels of understanding.
Porous materials continue to attract considerable attention because of their wide variety of scientific and technological applications, such as catalysis, shape- and size-selective absorption and adsorption, gas storage, and electrode materials. Both research and applications of porous materials-via electroanalysis, electrosynthesis, sensing, fuel
The papers included in this issue of ECS Transactions were originally presented in the symposium ¿Characterization of Porous Materials¿, held during the 213th meeting of The Electrochemical Society, in Phoenix, Arizona from May 18 to 23, 2008.
Providing the unique and vital link between the worlds of electrochemistry and nanomaterials, this reference and handbook covers advances in electrochemistry through the nanoscale control of electrode structures, as well as advances in nanotechnology through electrochemical synthesis strategies. It demonstrates how electrochemical methods are of great scientific and commercial interest due to their low cost and high efficiency, and includes the synthesis of nanowires, nanoparticles, nanoporous and layered nanomaterials of various compositions, as well as their applications -- ranging from superior electrode materials to energy storage, biosensors, and electroanalytical devices.
This thesis focuses on porous monolithic materials that are not in the forms of particles, fibers, or films. In particular, the synthetic strategy of porous monolithic materials via the sol–gel method accompanied by phase separation, which is characterized as the non-templating method for tailoring well-defined macropores, is described from the basics to actual synthesis. Porous materials are attracting more and more attention in various fields such as electronics, energy storage, catalysis, sensing, adsorbents, biomedical science, and separation science. To date, many efforts have been made to synthesize porous materials in various chemical compositions—organics, inorganics including metals, glasses and ceramics, and organic-inorganic hybrids. Also demonstrated in this thesis are the potential applications of synthesized porous monolithic materials to separation media as well as to electrodes for electric double-layer capacitors (EDLCs) and Li-ion batteries (LIBs). This work is ideal for graduate students in materials science and is also useful to engineers or scientists seeking basic knowledge of porous monolithic materials.
Among the nanomaterials, nanoporous materials occupy a special place as they represent macroscopic objects with unique 'nanoscopic' properties but typically produced top down approach. Their applications are quite broad, from filtration, catalysis, and energy materials, to sensors and adsorbents. Here, we discuss some of such applications in the field of biosensors, electrochemistry, and fuel cell technology. We illustrate how a simple sensor for viral particles (mimicked here by MS2 bacteriophage) based on ionic conductivity through nanopores can be realized using anodic aluminum oxide (AAO) membrane and a computer sound card as an input/output detector. With the current optimized system, we can achieve the low concentration detection of ~ 7pfu/mL with a working range up to ~ 2000 pfu/mL.
This four-volume handbook gives a state-of-the-art overview of porous materials, from synthesis and characterization all the way to manufacturing and industrial applications.
Making innovative products for energy generation that decrease carbon footprints are the need of the hour. This book describes innovations in porous materials for energy generation and storage applications that can have applications in developed as well as developing countries. It provides a comprehensive account of porous materials for potential new applications, such as catalysts for gas storage and energy efficient transformations, which engineers and scientists working in the areas of solar cells, batteries, supercapacitors, fuel cells, etc. will find to be of immense interest.