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The market for chemical sensors continues to grow at a rapid rate, reflecting the wide range of possibilities for improving technological processes in industry and agriculture as well as living conditions that can be enhanced by the use of chemical sensors. The military, medicine, air/space, and security markets also continue to drive research and development in this area. At present it is hard to imagine an area where chemical sensors would be useless. On the contrary, we note that every day new areas arise in which new analytical instrumentation with modern functional opportunities is urgently needed.
Chemical detectors. --- Chemical sensors --- Chemical apparatus --- Detectors --- atmosphere monitoring --- chemical gas mixture analysis --- chemical sensor applications --- chemical sensor selection --- chemical sensor technologies --- chemical sensors --- electronic nose --- electronic tongue --- remote chemical sensing --- wireless chemical sensors
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This is the third of a new five-volume comprehensive reference work that provides computer simulation and modeling techniques in various fields of chemical sensing and the important applications for chemical sensing such as bulk and surface diffusion, adsorption, surface reactions, sintering, conductivity, mass transport, and interphase interactions.
Chemical detectors. --- Solid state electronics. --- Nanostructured materials. --- Nanomaterials --- Nanometer materials --- Nanophase materials --- Nanostructure controlled materials --- Nanostructure materials --- Ultra-fine microstructure materials --- Microstructure --- Nanotechnology --- Electronics --- Semiconductors --- Solid state physics --- Chemical sensors --- Chemical apparatus --- Detectors --- chemical sensors --- molecular modeling --- solid-state devices --- electrochemistry of surfaces --- nanostructures --- semiconductors --- humidity sensor --- MIS hydrogen sensor --- microacoustic chemical sensor --- carbon nanotube array --- microcantilever-based sensor --- thermoelectric gas sensor --- polymeric electronic nose
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The selective and quantitative detection of biocomponents is greatly requested in biomedical applications and clinical diagnostics. Many traditional magnetic materials are not suitable for the ever-increasing demands of these processes. The push for a new generation of microscale sensors for bioapplications continues to challenge the materials science community to develop novel nanostructures that are suitable for such purposes. The principal requirements of a new generation of nanomaterials for sensor applications are based on well-known demands: high sensitivity, small size, low power consumption, stability, quick response, resistance to aggressive media, low price, and easy operation by nonskilled personnel. There are different types of magnetic effects capable of creating sensors for biology, medicine, and drug delivery, including magnetoresistance, spin valves, Hall and inductive effects, and giant magnetoimpedance. The present goal is to design nanomaterials both for magnetic markers and sensitive elements as synergetic pairs working in one device with adjusted characteristics of both materials. Synthetic approaches using the advantages of simulation methods and synthetic materials mimicking natural tissue properties can be useful, as can the further development of modeling strategies for magnetic nanostructures.
History of engineering & technology --- magnetic multilayers --- magnetoimpedance --- modeling --- magnetic sensors --- magnetic biosensors --- Magnetoimpedance effect --- amorphous ribbons --- patterned ribbons --- meander sensitive element --- magnetic field sensor --- magnetic nanoparticles --- contrast agent --- relaxation --- relaxation rate --- Langevin model --- magnetic field inhomogeneity --- ferrogels --- medical ultrasound --- sonography --- biomedical applications --- magnetic polymersomes --- magnetic vesicles --- magnetoactive composites --- nanocapsules --- coarse-grained molecular dynamics --- computer simulation --- spintronics --- CFA --- thermoelectric effect --- spin seebeck effect --- magneto-impedance --- biosensor --- finite-element method --- magnetic hyperthermia --- specific loss power --- magnetic mixed ferrites --- hysteresis losses --- thermometric measurements --- nanobiotechnology --- nanomedicine --- therapeutics --- biosensing --- magnetoelasticity --- precipitation --- mass measurement --- chemical sensor
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Fossil fuels leaded the 21st century industrial revolution but caused some critical problems such as exhaustion of resources and global warming. Also, current power plants require too much high cost and long time for establishment and facilities to provide electricity. Thus, developing new power production systems with environmental friendliness and low-cost is critical global needs. There are some emerging energy harvesting technologies such as thermoelectric, piezoelectric, and triboelectric nanogenerators, which have great advantages on eco-friendly low-cost materials, simple fabrication, and various operating sources. Since the introduction of various energy harvesting technologies, many novel designs and applications as power suppliers and physical sensors in the world have been demonstrated based on their unique advantages. In this Special Issue, we would like to address and share basic approaches, new designs, and industrial applications related to thermoelectric, piezoelectric, and triboelectric devices which are on-going in Korea. With this Special Issue, we aim to promote fundamental understanding and to find novel ways to achieve industrial product manufacturing for energy harvesters.
triboelectric nanogenerators --- n/a --- carbon nanotube --- mesoporous composite polymer --- organic composites --- railroad vehicle --- rolling stock --- suspension system --- remnant polarization --- water wave energy --- oxygen vacancy --- energy harvesting --- PVDF --- thermoelectric --- high dielectric constant --- advanced driver assistance technology --- thin film --- sensor --- wireless chemical sensor --- energy-harvesting metamaterial --- metamaterial sensor --- thermoelectric generator --- nanoimprinting --- superhydrophobic surface --- layer-by-layer --- high deformability --- metal oxidation --- IoT technology --- TiO2?x nanoparticle --- spray method --- piezoelectric --- graphene --- shock absorber --- ferroelectric --- frictional force --- axle bearing --- femtosecond laser --- carbon nanotubes --- mechanical energy --- polymers --- mechanical fatigue resistance --- gapless --- power factor --- nanostructures --- triboelectric generator --- hybrid energy --- microstructures --- triboelectric nanogenerator
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This book, entitled “Mesoporous Metal Oxide Films”, contains an editorial and a collection of ten research articles covering fundamental studies and applications of different metal oxide films. Mesoporous materials have been widely investigated and applied in many technological applications owing to their outstanding structural and physical properties. In this book, important developments in this fast-moving field are presented from various research groups around the world. Different preparation methods and applications of these novel and interesting materials have been reported, and it was demonstrated that mesoporosity has a direct impact on the properties and potential applications of such materials. The potential use of mesoporous metal oxide films and coatings with different morphology and structures is demonstrated in many technological applications, particularly chemical and electrochemical sensors, supercapacitors, solar cells, photoelectrodes, bioceramics, photonic switches, and anticorrosion agents.
History of engineering & technology --- SnO2 --- Metglas --- hemin --- H2O2 --- cyclic voltammetry --- magnetoelastic resonance --- sensor --- titanium dioxide --- mesoporous --- thin film --- multi-layered --- photoanode --- semiconductor --- photoelectrochemical water oxidation --- Mn2O3 --- mesoporous materials --- electrochemical characterizations --- electrode --- supercapacitors --- gadolinium oxide --- hydrazine --- p-nitrophenol --- electrochemical sensing --- amperometric --- selective sensor --- nanocrystal --- ZnO --- density of states --- optical and electrical properties --- TiO2 films --- Ag nanoparticles --- optical properties --- spectroelectrochemistry --- surface plasmon --- Fe-doped TiO2 --- hydrothermal --- GCE --- chemical sensor --- amperometry --- dye-sensitized solar cells --- working electrode --- TiO2 --- NiO nanoparticles --- electron transport --- corrosion --- guar gum --- coatings --- electrochemical impedance spectroscopy (EIS) --- SECM --- AFM --- calcium phosphate silicate --- PEG --- bioceramics --- sol-gel preparation --- hard tissue engineering --- metal oxide --- sol-gel --- supercapacitor --- photoelectrode --- dye sensitized solar cell --- NiO
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Fossil fuels leaded the 21st century industrial revolution but caused some critical problems such as exhaustion of resources and global warming. Also, current power plants require too much high cost and long time for establishment and facilities to provide electricity. Thus, developing new power production systems with environmental friendliness and low-cost is critical global needs. There are some emerging energy harvesting technologies such as thermoelectric, piezoelectric, and triboelectric nanogenerators, which have great advantages on eco-friendly low-cost materials, simple fabrication, and various operating sources. Since the introduction of various energy harvesting technologies, many novel designs and applications as power suppliers and physical sensors in the world have been demonstrated based on their unique advantages. In this Special Issue, we would like to address and share basic approaches, new designs, and industrial applications related to thermoelectric, piezoelectric, and triboelectric devices which are on-going in Korea. With this Special Issue, we aim to promote fundamental understanding and to find novel ways to achieve industrial product manufacturing for energy harvesters.
triboelectric nanogenerators --- n/a --- carbon nanotube --- mesoporous composite polymer --- organic composites --- railroad vehicle --- rolling stock --- suspension system --- remnant polarization --- water wave energy --- oxygen vacancy --- energy harvesting --- PVDF --- thermoelectric --- high dielectric constant --- advanced driver assistance technology --- thin film --- sensor --- wireless chemical sensor --- energy-harvesting metamaterial --- metamaterial sensor --- thermoelectric generator --- nanoimprinting --- superhydrophobic surface --- layer-by-layer --- high deformability --- metal oxidation --- IoT technology --- TiO2?x nanoparticle --- spray method --- piezoelectric --- graphene --- shock absorber --- ferroelectric --- frictional force --- axle bearing --- femtosecond laser --- carbon nanotubes --- mechanical energy --- polymers --- mechanical fatigue resistance --- gapless --- power factor --- nanostructures --- triboelectric generator --- hybrid energy --- microstructures --- triboelectric nanogenerator
Choose an application
The selective and quantitative detection of biocomponents is greatly requested in biomedical applications and clinical diagnostics. Many traditional magnetic materials are not suitable for the ever-increasing demands of these processes. The push for a new generation of microscale sensors for bioapplications continues to challenge the materials science community to develop novel nanostructures that are suitable for such purposes. The principal requirements of a new generation of nanomaterials for sensor applications are based on well-known demands: high sensitivity, small size, low power consumption, stability, quick response, resistance to aggressive media, low price, and easy operation by nonskilled personnel. There are different types of magnetic effects capable of creating sensors for biology, medicine, and drug delivery, including magnetoresistance, spin valves, Hall and inductive effects, and giant magnetoimpedance. The present goal is to design nanomaterials both for magnetic markers and sensitive elements as synergetic pairs working in one device with adjusted characteristics of both materials. Synthetic approaches using the advantages of simulation methods and synthetic materials mimicking natural tissue properties can be useful, as can the further development of modeling strategies for magnetic nanostructures.
magnetic multilayers --- magnetoimpedance --- modeling --- magnetic sensors --- magnetic biosensors --- Magnetoimpedance effect --- amorphous ribbons --- patterned ribbons --- meander sensitive element --- magnetic field sensor --- magnetic nanoparticles --- contrast agent --- relaxation --- relaxation rate --- Langevin model --- magnetic field inhomogeneity --- ferrogels --- medical ultrasound --- sonography --- biomedical applications --- magnetic polymersomes --- magnetic vesicles --- magnetoactive composites --- nanocapsules --- coarse-grained molecular dynamics --- computer simulation --- spintronics --- CFA --- thermoelectric effect --- spin seebeck effect --- magneto-impedance --- biosensor --- finite-element method --- magnetic hyperthermia --- specific loss power --- magnetic mixed ferrites --- hysteresis losses --- thermometric measurements --- nanobiotechnology --- nanomedicine --- therapeutics --- biosensing --- magnetoelasticity --- precipitation --- mass measurement --- chemical sensor
Choose an application
This book, entitled “Mesoporous Metal Oxide Films”, contains an editorial and a collection of ten research articles covering fundamental studies and applications of different metal oxide films. Mesoporous materials have been widely investigated and applied in many technological applications owing to their outstanding structural and physical properties. In this book, important developments in this fast-moving field are presented from various research groups around the world. Different preparation methods and applications of these novel and interesting materials have been reported, and it was demonstrated that mesoporosity has a direct impact on the properties and potential applications of such materials. The potential use of mesoporous metal oxide films and coatings with different morphology and structures is demonstrated in many technological applications, particularly chemical and electrochemical sensors, supercapacitors, solar cells, photoelectrodes, bioceramics, photonic switches, and anticorrosion agents.
SnO2 --- Metglas --- hemin --- H2O2 --- cyclic voltammetry --- magnetoelastic resonance --- sensor --- titanium dioxide --- mesoporous --- thin film --- multi-layered --- photoanode --- semiconductor --- photoelectrochemical water oxidation --- Mn2O3 --- mesoporous materials --- electrochemical characterizations --- electrode --- supercapacitors --- gadolinium oxide --- hydrazine --- p-nitrophenol --- electrochemical sensing --- amperometric --- selective sensor --- nanocrystal --- ZnO --- density of states --- optical and electrical properties --- TiO2 films --- Ag nanoparticles --- optical properties --- spectroelectrochemistry --- surface plasmon --- Fe-doped TiO2 --- hydrothermal --- GCE --- chemical sensor --- amperometry --- dye-sensitized solar cells --- working electrode --- TiO2 --- NiO nanoparticles --- electron transport --- corrosion --- guar gum --- coatings --- electrochemical impedance spectroscopy (EIS) --- SECM --- AFM --- calcium phosphate silicate --- PEG --- bioceramics --- sol-gel preparation --- hard tissue engineering --- metal oxide --- sol-gel --- supercapacitor --- photoelectrode --- dye sensitized solar cell --- NiO
Choose an application
The selective and quantitative detection of biocomponents is greatly requested in biomedical applications and clinical diagnostics. Many traditional magnetic materials are not suitable for the ever-increasing demands of these processes. The push for a new generation of microscale sensors for bioapplications continues to challenge the materials science community to develop novel nanostructures that are suitable for such purposes. The principal requirements of a new generation of nanomaterials for sensor applications are based on well-known demands: high sensitivity, small size, low power consumption, stability, quick response, resistance to aggressive media, low price, and easy operation by nonskilled personnel. There are different types of magnetic effects capable of creating sensors for biology, medicine, and drug delivery, including magnetoresistance, spin valves, Hall and inductive effects, and giant magnetoimpedance. The present goal is to design nanomaterials both for magnetic markers and sensitive elements as synergetic pairs working in one device with adjusted characteristics of both materials. Synthetic approaches using the advantages of simulation methods and synthetic materials mimicking natural tissue properties can be useful, as can the further development of modeling strategies for magnetic nanostructures.
History of engineering & technology --- magnetic multilayers --- magnetoimpedance --- modeling --- magnetic sensors --- magnetic biosensors --- Magnetoimpedance effect --- amorphous ribbons --- patterned ribbons --- meander sensitive element --- magnetic field sensor --- magnetic nanoparticles --- contrast agent --- relaxation --- relaxation rate --- Langevin model --- magnetic field inhomogeneity --- ferrogels --- medical ultrasound --- sonography --- biomedical applications --- magnetic polymersomes --- magnetic vesicles --- magnetoactive composites --- nanocapsules --- coarse-grained molecular dynamics --- computer simulation --- spintronics --- CFA --- thermoelectric effect --- spin seebeck effect --- magneto-impedance --- biosensor --- finite-element method --- magnetic hyperthermia --- specific loss power --- magnetic mixed ferrites --- hysteresis losses --- thermometric measurements --- nanobiotechnology --- nanomedicine --- therapeutics --- biosensing --- magnetoelasticity --- precipitation --- mass measurement --- chemical sensor --- magnetic multilayers --- magnetoimpedance --- modeling --- magnetic sensors --- magnetic biosensors --- Magnetoimpedance effect --- amorphous ribbons --- patterned ribbons --- meander sensitive element --- magnetic field sensor --- magnetic nanoparticles --- contrast agent --- relaxation --- relaxation rate --- Langevin model --- magnetic field inhomogeneity --- ferrogels --- medical ultrasound --- sonography --- biomedical applications --- magnetic polymersomes --- magnetic vesicles --- magnetoactive composites --- nanocapsules --- coarse-grained molecular dynamics --- computer simulation --- spintronics --- CFA --- thermoelectric effect --- spin seebeck effect --- magneto-impedance --- biosensor --- finite-element method --- magnetic hyperthermia --- specific loss power --- magnetic mixed ferrites --- hysteresis losses --- thermometric measurements --- nanobiotechnology --- nanomedicine --- therapeutics --- biosensing --- magnetoelasticity --- precipitation --- mass measurement --- chemical sensor
Choose an application
This book, entitled “Mesoporous Metal Oxide Films”, contains an editorial and a collection of ten research articles covering fundamental studies and applications of different metal oxide films. Mesoporous materials have been widely investigated and applied in many technological applications owing to their outstanding structural and physical properties. In this book, important developments in this fast-moving field are presented from various research groups around the world. Different preparation methods and applications of these novel and interesting materials have been reported, and it was demonstrated that mesoporosity has a direct impact on the properties and potential applications of such materials. The potential use of mesoporous metal oxide films and coatings with different morphology and structures is demonstrated in many technological applications, particularly chemical and electrochemical sensors, supercapacitors, solar cells, photoelectrodes, bioceramics, photonic switches, and anticorrosion agents.
History of engineering & technology --- SnO2 --- Metglas --- hemin --- H2O2 --- cyclic voltammetry --- magnetoelastic resonance --- sensor --- titanium dioxide --- mesoporous --- thin film --- multi-layered --- photoanode --- semiconductor --- photoelectrochemical water oxidation --- Mn2O3 --- mesoporous materials --- electrochemical characterizations --- electrode --- supercapacitors --- gadolinium oxide --- hydrazine --- p-nitrophenol --- electrochemical sensing --- amperometric --- selective sensor --- nanocrystal --- ZnO --- density of states --- optical and electrical properties --- TiO2 films --- Ag nanoparticles --- optical properties --- spectroelectrochemistry --- surface plasmon --- Fe-doped TiO2 --- hydrothermal --- GCE --- chemical sensor --- amperometry --- dye-sensitized solar cells --- working electrode --- TiO2 --- NiO nanoparticles --- electron transport --- corrosion --- guar gum --- coatings --- electrochemical impedance spectroscopy (EIS) --- SECM --- AFM --- calcium phosphate silicate --- PEG --- bioceramics --- sol-gel preparation --- hard tissue engineering --- metal oxide --- sol-gel --- supercapacitor --- photoelectrode --- dye sensitized solar cell --- NiO --- SnO2 --- Metglas --- hemin --- H2O2 --- cyclic voltammetry --- magnetoelastic resonance --- sensor --- titanium dioxide --- mesoporous --- thin film --- multi-layered --- photoanode --- semiconductor --- photoelectrochemical water oxidation --- Mn2O3 --- mesoporous materials --- electrochemical characterizations --- electrode --- supercapacitors --- gadolinium oxide --- hydrazine --- p-nitrophenol --- electrochemical sensing --- amperometric --- selective sensor --- nanocrystal --- ZnO --- density of states --- optical and electrical properties --- TiO2 films --- Ag nanoparticles --- optical properties --- spectroelectrochemistry --- surface plasmon --- Fe-doped TiO2 --- hydrothermal --- GCE --- chemical sensor --- amperometry --- dye-sensitized solar cells --- working electrode --- TiO2 --- NiO nanoparticles --- electron transport --- corrosion --- guar gum --- coatings --- electrochemical impedance spectroscopy (EIS) --- SECM --- AFM --- calcium phosphate silicate --- PEG --- bioceramics --- sol-gel preparation --- hard tissue engineering --- metal oxide --- sol-gel --- supercapacitor --- photoelectrode --- dye sensitized solar cell --- NiO
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