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This book is devoted to energy harvesting from smart materials and devices. It focusses on the latest available techniques recently published by researchers all over the world. Energy Harvesting allows otherwise wasted environmental energy to be converted into electric energy, such as vibrations, wind and solar energy. It is a common experience that the limiting factor for wearable electronics, such as smartphones or wearable bands, or for wireless sensors in harsh environments, is the finite energy stored in onboard batteries. Therefore, the answer to the battery “charge or change” issue is energy harvesting because it converts the energy in the precise location where it is needed. In order to achieve this, suitable smart materials are needed, such as piezoelectrics or magnetostrictives. Moreover, energy harvesting may also be exploited for other crucial applications, such as for the powering of implantable medical/sensing devices for humans and animals. Therefore, energy harvesting from smart materials will become increasingly important in the future. This book provides a broad perspective on this topic for researchers and readers with both physics and engineering backgrounds.
Technology: general issues --- History of engineering & technology --- magnetostrictive --- energy harvesting --- wearable --- magnetostrictive materials --- Galfenol --- finite element model --- iron-gallium --- measurements --- preisach model --- piezoelectric ceramics --- lead-free piezoceramics --- virtual instrument --- 3D electrospinning --- PVDF fibers --- piezoelectricity --- piezoelectric sensing --- wind energy harvesting --- snap-through motion --- dynamic stability --- variable-speed --- double-clamped --- width shapes --- piezoelectric energy harvester --- electrodes pair --- MEMS structure --- finite element method --- open circuit voltage --- moving load --- layered double hydroxide solar cell (LDHSC) --- photoactive material --- UV-Vis absorption --- dye sensitized solar cell (DSSC) --- photoactive layered double hydroxide (LDH) --- transition metal modification --- optical bandgap analysis --- renewable energy --- photovoltaic device design --- iron (Fe) modified MgFeAl LDH --- triboelectric effect --- polymer and composites --- low-power devices --- thermomagnetic energy generators --- power generation --- waste heat recovery --- lumped-element modelling --- magnetic shape memory films --- Ni-Mn-Ga film --- magnetization change --- Curie temperature --- finite element simulation --- piezoelectric unit distributions --- electrical potential and energy --- von Mises stress --- PVDF --- piezoelectric material --- human body movements --- glass fiber-reinforced polymer composite --- multifunctional structural laminate --- thermal energy harvesting --- through-thickness thermal gradient --- thermoelectric generator (TEG) --- magnetostrictive --- energy harvesting --- wearable --- magnetostrictive materials --- Galfenol --- finite element model --- iron-gallium --- measurements --- preisach model --- piezoelectric ceramics --- lead-free piezoceramics --- virtual instrument --- 3D electrospinning --- PVDF fibers --- piezoelectricity --- piezoelectric sensing --- wind energy harvesting --- snap-through motion --- dynamic stability --- variable-speed --- double-clamped --- width shapes --- piezoelectric energy harvester --- electrodes pair --- MEMS structure --- finite element method --- open circuit voltage --- moving load --- layered double hydroxide solar cell (LDHSC) --- photoactive material --- UV-Vis absorption --- dye sensitized solar cell (DSSC) --- photoactive layered double hydroxide (LDH) --- transition metal modification --- optical bandgap analysis --- renewable energy --- photovoltaic device design --- iron (Fe) modified MgFeAl LDH --- triboelectric effect --- polymer and composites --- low-power devices --- thermomagnetic energy generators --- power generation --- waste heat recovery --- lumped-element modelling --- magnetic shape memory films --- Ni-Mn-Ga film --- magnetization change --- Curie temperature --- finite element simulation --- piezoelectric unit distributions --- electrical potential and energy --- von Mises stress --- PVDF --- piezoelectric material --- human body movements --- glass fiber-reinforced polymer composite --- multifunctional structural laminate --- thermal energy harvesting --- through-thickness thermal gradient --- thermoelectric generator (TEG)
Choose an application
This book is devoted to energy harvesting from smart materials and devices. It focusses on the latest available techniques recently published by researchers all over the world. Energy Harvesting allows otherwise wasted environmental energy to be converted into electric energy, such as vibrations, wind and solar energy. It is a common experience that the limiting factor for wearable electronics, such as smartphones or wearable bands, or for wireless sensors in harsh environments, is the finite energy stored in onboard batteries. Therefore, the answer to the battery “charge or change” issue is energy harvesting because it converts the energy in the precise location where it is needed. In order to achieve this, suitable smart materials are needed, such as piezoelectrics or magnetostrictives. Moreover, energy harvesting may also be exploited for other crucial applications, such as for the powering of implantable medical/sensing devices for humans and animals. Therefore, energy harvesting from smart materials will become increasingly important in the future. This book provides a broad perspective on this topic for researchers and readers with both physics and engineering backgrounds.
Technology: general issues --- History of engineering & technology --- magnetostrictive --- energy harvesting --- wearable --- magnetostrictive materials --- Galfenol --- finite element model --- iron–gallium --- measurements --- preisach model --- piezoelectric ceramics --- lead-free piezoceramics --- virtual instrument --- 3D electrospinning --- PVDF fibers --- piezoelectricity --- piezoelectric sensing --- wind energy harvesting --- snap-through motion --- dynamic stability --- variable-speed --- double-clamped --- width shapes --- piezoelectric energy harvester --- electrodes pair --- MEMS structure --- finite element method --- open circuit voltage --- moving load --- layered double hydroxide solar cell (LDHSC) --- photoactive material --- UV-Vis absorption --- dye sensitized solar cell (DSSC) --- photoactive layered double hydroxide (LDH) --- transition metal modification --- optical bandgap analysis --- renewable energy --- photovoltaic device design --- iron (Fe) modified MgFeAl LDH --- triboelectric effect --- polymer and composites --- low-power devices --- thermomagnetic energy generators --- power generation --- waste heat recovery --- lumped-element modelling --- magnetic shape memory films --- Ni-Mn-Ga film --- magnetization change --- Curie temperature --- finite element simulation --- piezoelectric unit distributions --- electrical potential and energy --- von Mises stress --- PVDF --- piezoelectric material --- human body movements --- glass fiber-reinforced polymer composite --- multifunctional structural laminate --- thermal energy harvesting --- through-thickness thermal gradient --- thermoelectric generator (TEG) --- n/a --- iron-gallium
Choose an application
This book is devoted to energy harvesting from smart materials and devices. It focusses on the latest available techniques recently published by researchers all over the world. Energy Harvesting allows otherwise wasted environmental energy to be converted into electric energy, such as vibrations, wind and solar energy. It is a common experience that the limiting factor for wearable electronics, such as smartphones or wearable bands, or for wireless sensors in harsh environments, is the finite energy stored in onboard batteries. Therefore, the answer to the battery “charge or change” issue is energy harvesting because it converts the energy in the precise location where it is needed. In order to achieve this, suitable smart materials are needed, such as piezoelectrics or magnetostrictives. Moreover, energy harvesting may also be exploited for other crucial applications, such as for the powering of implantable medical/sensing devices for humans and animals. Therefore, energy harvesting from smart materials will become increasingly important in the future. This book provides a broad perspective on this topic for researchers and readers with both physics and engineering backgrounds.
magnetostrictive --- energy harvesting --- wearable --- magnetostrictive materials --- Galfenol --- finite element model --- iron–gallium --- measurements --- preisach model --- piezoelectric ceramics --- lead-free piezoceramics --- virtual instrument --- 3D electrospinning --- PVDF fibers --- piezoelectricity --- piezoelectric sensing --- wind energy harvesting --- snap-through motion --- dynamic stability --- variable-speed --- double-clamped --- width shapes --- piezoelectric energy harvester --- electrodes pair --- MEMS structure --- finite element method --- open circuit voltage --- moving load --- layered double hydroxide solar cell (LDHSC) --- photoactive material --- UV-Vis absorption --- dye sensitized solar cell (DSSC) --- photoactive layered double hydroxide (LDH) --- transition metal modification --- optical bandgap analysis --- renewable energy --- photovoltaic device design --- iron (Fe) modified MgFeAl LDH --- triboelectric effect --- polymer and composites --- low-power devices --- thermomagnetic energy generators --- power generation --- waste heat recovery --- lumped-element modelling --- magnetic shape memory films --- Ni-Mn-Ga film --- magnetization change --- Curie temperature --- finite element simulation --- piezoelectric unit distributions --- electrical potential and energy --- von Mises stress --- PVDF --- piezoelectric material --- human body movements --- glass fiber-reinforced polymer composite --- multifunctional structural laminate --- thermal energy harvesting --- through-thickness thermal gradient --- thermoelectric generator (TEG) --- n/a --- iron-gallium
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