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This book is about supramolecular gold chemistry. This book provides a unique international forum aimed at covering a broad description of results involving the supramolecular chemistry of gold with a special focus on the gold–sulfur interface leading to hybrid materials ranging from gold–thiolate complexes to thiolate-protected gold nanoclusters and gold–thiolate supramolecular assemblies or nanoparticles. The role of thiolates on the structure and optical features of gold nanohybrid systems (ranging from plasmonic gold nanoparticles and fluorescent gold nanoclusters to self-assembled Au-containing thiolated coordination polymers) is highlighted in the 12 papers presented in this book.
Technology: general issues --- alloy --- metal exchange --- atomically precise --- gold nanoclusters --- thiolate --- catenane --- ion mobility --- DFT calculations --- gold nanocluster --- cross-coupling --- Ullmann hetero-coupling --- Sonogashira coupling --- Suzuki coupling --- A3−coupling --- catalytic mechanism --- ligand removal --- gold nanomaterials --- electron dynamics --- phonon dynamics --- optical properties --- Au70S20(PPh3)12 cluster --- superatom network model --- electronic structure --- geometric structure --- gold nanoparticles --- graphene oxide --- laser ablation --- Au-GO nano-hybrid --- coordination polymer structure --- amino acids --- template-assisted synthesis --- fluorescence --- Au(I)-thiolate --- gold nanohybrid materials --- 3-MBA/Au MPCs --- TEA-HFIP --- ESI-MS --- HPLC-MS --- bidentate binding --- gold thiolate --- coordination polymer --- lamellar structure --- luminescence --- polymer composite --- gold --- cluster --- catalyst --- hydrogen evolution reaction --- oxygen evolution reaction --- oxygen reduction reaction --- water splitting --- fuel cells --- ligand-protected --- photoluminescence mechanism --- metal nanoclusters --- quantum confinement effect --- ligand effect --- p band intermediate state (PBIS) --- interface state --- nanocatalysis --- 6-aza-2-thio-thymine --- protein --- n/a
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In the last few years, the leading semiconductor industries have introduced multi-gate non-planar transistors into their core business. These are being applied in memories and in logical integrated circuits to achieve better integration on the chip, increased performance, and reduced energy consumption. Intense research is underway to develop these devices further and to address their limitations, in order to continue transistor scaling while further improving performance. This Special Issue looks at recent developments in the field of nanowire field-effect transistors (NW-FETs), covering different aspects of the technology, physics, and modelling of these nanoscale devices.
History of engineering & technology --- random dopant --- drift-diffusion --- variability --- device simulation --- nanodevice --- screening --- Coulomb interaction --- III-V --- TASE --- MOSFETs --- Integration --- nanowire field-effect transistors --- silicon nanomaterials --- charge transport --- one-dimensional multi-subband scattering models --- Kubo–Greenwood formalism --- schrödinger-poisson solvers --- DC and AC characteristic fluctuations --- gate-all-around --- nanowire --- work function fluctuation --- aspect ratio of channel cross-section --- timing fluctuation --- noise margin fluctuation --- power fluctuation --- CMOS circuit --- statistical device simulation --- variability effects --- Monte Carlo --- Schrödinger based quantum corrections --- quantum modeling --- nonequilibrium Green’s function --- nanowire transistor --- electron–phonon interaction --- phonon–phonon interaction --- self-consistent Born approximation --- lowest order approximation --- Padé approximants --- Richardson extrapolation --- ZnO --- field effect transistor --- conduction mechanism --- metal gate --- material properties --- fabrication --- modelling --- nanojunction --- constriction --- quantum electron transport --- quantum confinement --- dimensionality reduction --- stochastic Schrödinger equations --- geometric correlations --- silicon nanowires --- nano-transistors --- quantum transport --- hot electrons --- self-cooling --- nano-cooling --- thermoelectricity --- heat equation --- non-equilibrium Green functions --- power dissipation
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This book is about supramolecular gold chemistry. This book provides a unique international forum aimed at covering a broad description of results involving the supramolecular chemistry of gold with a special focus on the gold–sulfur interface leading to hybrid materials ranging from gold–thiolate complexes to thiolate-protected gold nanoclusters and gold–thiolate supramolecular assemblies or nanoparticles. The role of thiolates on the structure and optical features of gold nanohybrid systems (ranging from plasmonic gold nanoparticles and fluorescent gold nanoclusters to self-assembled Au-containing thiolated coordination polymers) is highlighted in the 12 papers presented in this book.
Technology: general issues --- alloy --- metal exchange --- atomically precise --- gold nanoclusters --- thiolate --- catenane --- ion mobility --- DFT calculations --- gold nanocluster --- cross-coupling --- Ullmann hetero-coupling --- Sonogashira coupling --- Suzuki coupling --- A3−coupling --- catalytic mechanism --- ligand removal --- gold nanomaterials --- electron dynamics --- phonon dynamics --- optical properties --- Au70S20(PPh3)12 cluster --- superatom network model --- electronic structure --- geometric structure --- gold nanoparticles --- graphene oxide --- laser ablation --- Au-GO nano-hybrid --- coordination polymer structure --- amino acids --- template-assisted synthesis --- fluorescence --- Au(I)-thiolate --- gold nanohybrid materials --- 3-MBA/Au MPCs --- TEA-HFIP --- ESI-MS --- HPLC-MS --- bidentate binding --- gold thiolate --- coordination polymer --- lamellar structure --- luminescence --- polymer composite --- gold --- cluster --- catalyst --- hydrogen evolution reaction --- oxygen evolution reaction --- oxygen reduction reaction --- water splitting --- fuel cells --- ligand-protected --- photoluminescence mechanism --- metal nanoclusters --- quantum confinement effect --- ligand effect --- p band intermediate state (PBIS) --- interface state --- nanocatalysis --- 6-aza-2-thio-thymine --- protein --- n/a
Choose an application
In the last few years, the leading semiconductor industries have introduced multi-gate non-planar transistors into their core business. These are being applied in memories and in logical integrated circuits to achieve better integration on the chip, increased performance, and reduced energy consumption. Intense research is underway to develop these devices further and to address their limitations, in order to continue transistor scaling while further improving performance. This Special Issue looks at recent developments in the field of nanowire field-effect transistors (NW-FETs), covering different aspects of the technology, physics, and modelling of these nanoscale devices.
History of engineering & technology --- random dopant --- drift-diffusion --- variability --- device simulation --- nanodevice --- screening --- Coulomb interaction --- III-V --- TASE --- MOSFETs --- Integration --- nanowire field-effect transistors --- silicon nanomaterials --- charge transport --- one-dimensional multi-subband scattering models --- Kubo–Greenwood formalism --- schrödinger-poisson solvers --- DC and AC characteristic fluctuations --- gate-all-around --- nanowire --- work function fluctuation --- aspect ratio of channel cross-section --- timing fluctuation --- noise margin fluctuation --- power fluctuation --- CMOS circuit --- statistical device simulation --- variability effects --- Monte Carlo --- Schrödinger based quantum corrections --- quantum modeling --- nonequilibrium Green’s function --- nanowire transistor --- electron–phonon interaction --- phonon–phonon interaction --- self-consistent Born approximation --- lowest order approximation --- Padé approximants --- Richardson extrapolation --- ZnO --- field effect transistor --- conduction mechanism --- metal gate --- material properties --- fabrication --- modelling --- nanojunction --- constriction --- quantum electron transport --- quantum confinement --- dimensionality reduction --- stochastic Schrödinger equations --- geometric correlations --- silicon nanowires --- nano-transistors --- quantum transport --- hot electrons --- self-cooling --- nano-cooling --- thermoelectricity --- heat equation --- non-equilibrium Green functions --- power dissipation
Choose an application
This book is about supramolecular gold chemistry. This book provides a unique international forum aimed at covering a broad description of results involving the supramolecular chemistry of gold with a special focus on the gold–sulfur interface leading to hybrid materials ranging from gold–thiolate complexes to thiolate-protected gold nanoclusters and gold–thiolate supramolecular assemblies or nanoparticles. The role of thiolates on the structure and optical features of gold nanohybrid systems (ranging from plasmonic gold nanoparticles and fluorescent gold nanoclusters to self-assembled Au-containing thiolated coordination polymers) is highlighted in the 12 papers presented in this book.
alloy --- metal exchange --- atomically precise --- gold nanoclusters --- thiolate --- catenane --- ion mobility --- DFT calculations --- gold nanocluster --- cross-coupling --- Ullmann hetero-coupling --- Sonogashira coupling --- Suzuki coupling --- A3−coupling --- catalytic mechanism --- ligand removal --- gold nanomaterials --- electron dynamics --- phonon dynamics --- optical properties --- Au70S20(PPh3)12 cluster --- superatom network model --- electronic structure --- geometric structure --- gold nanoparticles --- graphene oxide --- laser ablation --- Au-GO nano-hybrid --- coordination polymer structure --- amino acids --- template-assisted synthesis --- fluorescence --- Au(I)-thiolate --- gold nanohybrid materials --- 3-MBA/Au MPCs --- TEA-HFIP --- ESI-MS --- HPLC-MS --- bidentate binding --- gold thiolate --- coordination polymer --- lamellar structure --- luminescence --- polymer composite --- gold --- cluster --- catalyst --- hydrogen evolution reaction --- oxygen evolution reaction --- oxygen reduction reaction --- water splitting --- fuel cells --- ligand-protected --- photoluminescence mechanism --- metal nanoclusters --- quantum confinement effect --- ligand effect --- p band intermediate state (PBIS) --- interface state --- nanocatalysis --- 6-aza-2-thio-thymine --- protein --- n/a
Choose an application
In the last few years, the leading semiconductor industries have introduced multi-gate non-planar transistors into their core business. These are being applied in memories and in logical integrated circuits to achieve better integration on the chip, increased performance, and reduced energy consumption. Intense research is underway to develop these devices further and to address their limitations, in order to continue transistor scaling while further improving performance. This Special Issue looks at recent developments in the field of nanowire field-effect transistors (NW-FETs), covering different aspects of the technology, physics, and modelling of these nanoscale devices.
random dopant --- drift-diffusion --- variability --- device simulation --- nanodevice --- screening --- Coulomb interaction --- III-V --- TASE --- MOSFETs --- Integration --- nanowire field-effect transistors --- silicon nanomaterials --- charge transport --- one-dimensional multi-subband scattering models --- Kubo–Greenwood formalism --- schrödinger-poisson solvers --- DC and AC characteristic fluctuations --- gate-all-around --- nanowire --- work function fluctuation --- aspect ratio of channel cross-section --- timing fluctuation --- noise margin fluctuation --- power fluctuation --- CMOS circuit --- statistical device simulation --- variability effects --- Monte Carlo --- Schrödinger based quantum corrections --- quantum modeling --- nonequilibrium Green’s function --- nanowire transistor --- electron–phonon interaction --- phonon–phonon interaction --- self-consistent Born approximation --- lowest order approximation --- Padé approximants --- Richardson extrapolation --- ZnO --- field effect transistor --- conduction mechanism --- metal gate --- material properties --- fabrication --- modelling --- nanojunction --- constriction --- quantum electron transport --- quantum confinement --- dimensionality reduction --- stochastic Schrödinger equations --- geometric correlations --- silicon nanowires --- nano-transistors --- quantum transport --- hot electrons --- self-cooling --- nano-cooling --- thermoelectricity --- heat equation --- non-equilibrium Green functions --- power dissipation
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Due to their unique size-dependent physicochemical properties, nanostructured thin films are used in a wide range of applications from smart coating and drug delivery to electrocatalysis and highly-sensitive sensors. Depending on the targeted application and the deposition technique, these materials have been designed and developed by tuning their atomic-molecular 2D- and/or 3D-aggregation, thickness, crystallinity, and porosity, having effects on their optical, mechanical, catalytic, and conductive properties. Several open questions remain about the impact of nanomaterial production and use on environment and health. Many efforts are currently being made not only to prevent nanotechnologies and nanomaterials from contributing to environmental pollution but also to design nanomaterials to support, control, and protect the environment. This Special Issue aims to cover the recent advances in designing nanostructured films focusing on environmental issues related to their fabrication processes (e.g., low power and low cost technologies, the use of environmentally friendly solvents), their precursors (e.g., waste-recycled, bio-based, biodegradable, and natural materials), their applications (e.g., controlled release of chemicals, mimicking of natural processes, and clean energy conversion and storage), and their use in monitoring environment pollution (e.g., sensors optically- or electrically-sensitive to pollutants)
polyhydroxibutyrate --- graphene oxide --- nanostructured films --- iridescence --- carbon nanotube --- corrosion --- biomaterial --- powders --- adsorption energy --- UPD --- plasma irradiation --- metallic nanoparticles --- STM --- nanospiral --- PA-PVD --- light trapping --- ruthenium --- aqueous dispersion --- DFT --- monomer synthesis --- ultrathin films --- galvanic displacement --- quantum confinement --- rod coating --- nanocomposite conductive polymers --- nanocrystalline cellulose --- phase transition performance --- La2O3 passivation layer --- interfacial energy --- lamination --- lysozyme --- nanofibrous membranes --- H2TPP --- poly(dimethylacrylamide) --- iron oxides --- water filtration --- hybrid deposition system --- Pt thin deposits --- reinforced --- wires --- self-assembly --- composite gel --- electron–phonon coupling --- barrier material --- PAS device --- hydrogel --- nanoscratch --- thin film --- polymeric matrix --- SEM --- silver --- sputtering --- optical transmittance --- wound dressing --- agarose --- XPEEM --- CERAMIS® --- highly oriented pyrolytic graphite --- FeO --- Raman scattering --- model system --- XPS --- photocatalysis --- photovoltaics --- atomic layer deposition --- chirality --- structural characterization --- polystyrene --- nanofiber --- 2D growth --- nanostructure --- biomedical --- VOCs selectivity --- silicon thin film --- electrodeposition --- electrocatalysis --- SLRR --- chemosensor --- CaxCoO2 --- spin coating --- nanocomposites --- Al2O3 --- metal-organic framework --- nanocoating of SiOx --- platinum --- symmetry --- PECVD --- thermal analysis --- first-principles calculation --- electrical properties --- biomimetic solvent sensors --- modulation structure --- nanofibers --- mercury vapors adsorbing layer --- hydrogenated amorphous carbon films --- phase transformation --- birefringence --- nanostructured back reflectors --- mesoporous --- silk sericin --- polymer nanoparticles --- LEEM --- SorpTest --- InAlN --- metamaterial --- microparticle deposition --- CdTe --- homogeneity --- luminous transmittance --- LDH --- hybrid material --- scaffolds --- MgO --- polystyrene sphere assisted lithography --- Ge surface engineering --- epitaxial growth --- AuNPs --- Kr physisorption --- plasma deposition --- ReB2/TaN multilayers --- vanadium dioxide --- FIB --- mask --- self-catalysed --- mesoporous graphene --- coating --- post-treatment --- Mg alloy --- photonic nanostructures --- ink --- deposition --- Mueller matrix --- electrospinning deposition --- polar semiconductors --- zinc oxide --- thin films --- Fe3O4 --- TiO2NPs --- mechanical flexibility --- hazardous organic solvents --- permeation --- interfacial model --- microscopy --- LEED --- electrical conductivity --- PVD
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During the last decade, novel graphene related materials (GRMs), perovskites, as well as metal oxides and other metal nanostructures have received the interest of the scientific community. Due to their extraordinary physical, optical, thermal, and electrical properties, which are correlated with their 2D ultrathin atomic layer structure, large interlayer distance, ease of functionalization, and bandgap tunability, these nanomaterials have been applied in the development or the improvement of innovative optoelectronic applications, as well as the expansion of theoretical studies and simulations in the fast-growing fields of energy (photovoltaics, energy storage, fuel cells, hydrogen storage, catalysis, etc.), electronics, photonics, spintronics, and sensing devices. The continuous nanostructure-based applications development has provided the ability to significantly improve existing products and to explore the design of materials and devices with novel functionalities. This book demonstrates some of the most recent trends and advances in the interdisciplinary field of optoelectronics. Most articles focus on light emitting diodes (LEDs) and solar cells (SCs), including organic, inorganic, and hybrid configurations, whereas the rest address photodetectors, transistors, and other well-known dynamic optoelectronic devices. In this context, this exceptional collection of articles is directed at a broad scientific audience of chemists, materials scientists, physicists, and engineers, with the goals of highlighting the potential of innovative optoelectronic applications incorporating nanostructures and inspiring their realization.
graphene oxide --- textured silicon solar cells --- n/a --- high-efficiency --- CdTe microdots --- piezo-phototronic effect --- electromagnetically induced transparency effect --- waveguide photons --- light output power --- hole injection --- ternary organic solar cells --- UV LEDs --- cathodoluminescence --- V-pits --- quantum confinement effect --- nano-grating --- metamaterials --- Ga2O3 --- tunneling --- transmittance --- graphene ink --- perovskite solar cells --- counter electrode --- nucleation layer --- Ag film --- AlGaN-based ultraviolet light-emitting diode --- color-conversion efficiency --- PeLEDs --- photoelectric performance --- photocurrent --- charge transfer --- double-layer ITO --- green LED --- liquid crystals --- photovoltaics --- electrowetting --- oxidation --- Fowler–Nordheim --- field emission --- excitation wavelength --- functionalization --- quantum dots --- gold split-ring --- cascade effect --- erbium --- transparent conductive electrode --- compact --- plasmon resonance --- air-processed --- FDTD --- prism-structured sidewall --- sheet resistance --- GaN --- Ti porous film --- stability --- flip-chip mini-LED --- flexible substrate --- actively tunable nanodevices --- green LEDs --- metasurfaces --- antireflective coating (ARC) --- NiCo2S4 nanotubes --- InN/p-GaN heterojunction --- InGaN/GaN superlattice --- OAB --- graded indium composition --- plasmonics --- polymer composites --- photomultiplication --- cold cathode --- solvent --- solar cells --- controllable synthesis --- tunable absorbers --- interface --- graphene --- silicon transistor --- colorimetry --- light extraction --- reduced graphene oxide --- pinhole pattern --- indium nanoparticles (In NPs) --- graphene split-ring --- organic solar cell --- light-emitting diode --- organic --- plasmonic forward scattering --- smooth --- subwavelength metal grating --- perovskite --- photoluminescence --- mid infrared --- polarization analyzer --- transparent electrode --- external quantum efficiency --- LED --- light-emitting diodes --- photodetector --- p-type InGaN --- quantum efficiency --- 2D perovskite --- quantum dot --- orthogonal polarization --- current spreading --- localized surface plasmon --- Schottky barrier --- Fowler-Nordheim
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