03530nam 2200457 450 991058338330332120230120002728.00-12-813350-30-12-813349-X(CKB)4100000001474190(MiAaPQ)EBC5154047(EXLCZ)99410000000147419020171223h20182018 uy 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierGraphene bioelectronics /edited by Ashutosh TiwariAmsterdam, Netherlands :Elsevier,2018.©20181 online resource (390 pages) illustrations (some color), graphs, tablesAdvanced Nanomaterials SeriesIncludes bibliographical references at the end of each chapters and index.Graphene and 2D-like nanomaterials: different biofunctionalization pathways for electrochemical biosensor development -- Vertical graphene for biosensors -- Recent advances in metal alloy-graphene hybrids for biosensors -- Functionalization of graphene and graphene oxide for plasmonic and biosensing applications -- Graphene field-effect transistor sensors -- Efforts, challenges, and future perspectives of graphene-based (bio)sensors for biomedical applications -- Surface plasmon resonance-modified graphene oxide surfaces for whole-cell-based sensing -- Label-free biosensing platforms based on graphene/DNA interfaces -- The electrochemical aptasensors for the determination of tumor markers -- Nanoengineering of graphene-supported functional composites for performance-enhanced enzymatic biofuel cells -- Graphene-fabricated electrodes for improving the performance of microbial bioelectrochemical systems -- Graphene-based nanosensors and smart food packaging systems for food safety and quality monitoring -- Graphene-based portable, flexible, and wearable sensing platforms: an emerging trend for health care and biomedical surveillance -- Wearable graphene-based electrophysiological biosensing system for real-time health monitoring.Graphene Bioelectronics covers the expending field of graphene biomaterials, a wide span of biotechnological breakthroughs, opportunities, possibilities and challenges. It is the first book that focuses entirely on graphene bioelectronics, covering the miniaturization of bioelectrode materials, bioelectrode interfaces, high-throughput biosensing platforms, and systemic approaches for the development of electrochemical biosensors and bioelectronics for biomedical and energy applications. The book also showcases key applications, including advanced security, forensics and environmental monitoring. Thus, the evolution of these scientific areas demands innovations in crosscutting disciplines, starting from fabrication to application. This book is an important reference resource for researchers and technologists in graphene bioelectronics-particularly those working in the area of harvest energy biotechnology-employing state-of-the-art bioelectrode materials techniques.GrapheneNanostructured materialsBiosensorsGraphene.Nanostructured materials.Biosensors.620.115Tiwari AshutoshMiAaPQMiAaPQMiAaPQBOOK9910583383303321Graphene bioelectronics1960033UNINA03997nam 2200517 450 991076847040332120231222033217.03-031-48274-310.1007/978-3-031-48274-8(CKB)29092404300041(DE-He213)978-3-031-48274-8(MiAaPQ)EBC30975861(Au-PeEL)EBL30975861(EXLCZ)992909240430004120231222d2024 uy 0engur|||||||||||txtrdacontentcrdamediacrrdacarrierInteractions Between Electromagnetic Field and Moving Conducting Strip /Ihor Kondratenko, Yuriy Vasetsky, and Artur ZaporozhetsFirst edition.Cham, Switzerland :Springer,[2024]©20241 online resource (XIV, 119 p. 54 illus., 4 illus. in color.) Lecture Notes in Electrical Engineering Series ;Volume 11119783031482731 Includes bibliographical references.Mathematical Models of Electromagnetic Interaction of Field Sources with Conducting Body -- Configuration of Spatial Iron-Free Inductors for High-Frequency Induction Heating of Metal Strips -- Electromagnetic Systems of Transverse Magnetic Flux with Ferromagnetic Core for Induction Heating Devices -- Electromagnetic Systems with Iron-Free Inductors for Induction Heating of Moving Strip in Transverse Magnetic Field.The book combines two interrelated lines of research. One of them is devoted to the development of the theory for solving a certain class of three-dimensional electromagnetic field problems of the three-dimensional electromagnetic field, taking into account eddy currents in a moving conducting magnetizing body. Preference is given to the development of the analytical solution methods of the three-dimensional quasi-stationary problem of field conjugation in the system: “a contour of an arbitrary spatial configuration with an alternating current is conducting body with a flat boundary surface”. The second direction refers to the development of mathematical models for solving applied problems, which involve the use of developed methods for calculating the electromagnetic field and their characteristics. The main application of calculation methods is aimed at solving problems of heat treatment non-ferrous and ferrous metal products using the induction method of heating in a transverse magnetic field. The inverse problems are solved to determine the inductor configuration as flat and spatial current contours for providing the necessary temperature distribution of moving metal strips. To achieve uniform heating of strips across the width using inductors in the form of flat current contours parallel to the strip surface, it is advisable to use combinations of current contours, where the geometric dimensions are determined by the size and electro-physical parameters of the metal strips. A more uniform temperature distribution during high-frequency induction heating is achieved by using inductors in the form of current contours of the required spatial configuration. The book is intended for researchers, postgraduate students, and students specialized in theory and calculations of electromagnetic fields and induction heating installations.Lecture notes in electrical engineering ;Volume 1111.Electromagnetic fieldsMathematical modelsMagnetic inductionElectromagnetic fieldsMathematical models.Magnetic induction.530.141Kondratenko Ihor1456268Vasetsky YuriyZaporozhets ArturMiAaPQMiAaPQMiAaPQBOOK9910768470403321Interactions Between Electromagnetic Field and Moving Conducting Strip3657618UNINA