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The aim of this work is the design of monolithic integrated power amplifiers for frequencies from 200 to 250 GHz and beyond. For this, reliable and flexible transmission line and transistor models are required. The models are created and their accuracy is verified up to 325 GHz. An innovative coupler concept is developed. It is tailor-made for the applied MMIC-technology and the frequency range. Based on this coupler, a novel amplifier topology has been established and applied.
power amplifier --- III-V semiconductor --- HEMT --- millimetre-wave --- koplanarer Wellenleiter --- monolithic integrated --- mHEMT --- Verbindungshalbleiter --- Mikrostreifenleitung --- coplanar waveguide --- FETmillimeterwave --- Terahertz --- microstrip transmission line --- 3-5 --- MMIC --- Leistungsverstärker --- Millimeterwelle
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Nanoplasmonics is an area that uses light to couple electrons in metals, and can break the diffraction limit for light confinement into subwavelength zones, allowing for strong field enhancements. In the last two decades, there has been a resurgence of this research topic and its applications. Thus, this Special Issue presents a collection of articles and reviews by international researchers and is devoted to the recent advances in and insights into this research topic, including plasmonic devices, plasmonic biosensing, plasmonic photocatalysis, plasmonic photovoltaics, surface-enhanced Raman scattering, and surface plasmon resonance spectroscopy.
Technology: general issues --- History of engineering & technology --- Materials science --- plasmonics --- localized surface plasmon resonance --- high pressure --- sensing --- SERS --- two-dimensional material --- titanium carbide MXene --- near-field enhancement --- plasmonic material --- optical properties of ultra-thin dielectric films --- surface plasmon spectroscopy --- spectroscopic ellipsometry --- SHINERS --- core-shell nanoparticles --- catalysis --- electrochemistry --- nanowires --- back reflector --- solar cells --- plasmonic --- III-V semiconductor --- surface plasmon resonance --- photonic crystal D-shaped fiber --- refractive index sensor --- dispersion sensor --- second-order dispersion sensor --- waveguide --- SPPs --- FDTD --- bandstop filter --- CMT --- nanocrystalline cellulose --- optical characterization --- copper ion --- poly(3,4-ethylenedioxythiophene) --- structural properties --- optical properties --- Surface Enhanced Raman Scattering (SERS) --- fabrication --- application --- agriculture --- food safety --- gold --- nanoparticles --- thiophenol --- silicon --- nonlinear optics --- sum-frequency generation --- UV-vis spectroscopy --- atomic force microscopy --- CLIO free electron laser --- inverse problem --- copper --- copper oxide --- plasmonics --- localized surface plasmon resonance --- high pressure --- sensing --- SERS --- two-dimensional material --- titanium carbide MXene --- near-field enhancement --- plasmonic material --- optical properties of ultra-thin dielectric films --- surface plasmon spectroscopy --- spectroscopic ellipsometry --- SHINERS --- core-shell nanoparticles --- catalysis --- electrochemistry --- nanowires --- back reflector --- solar cells --- plasmonic --- III-V semiconductor --- surface plasmon resonance --- photonic crystal D-shaped fiber --- refractive index sensor --- dispersion sensor --- second-order dispersion sensor --- waveguide --- SPPs --- FDTD --- bandstop filter --- CMT --- nanocrystalline cellulose --- optical characterization --- copper ion --- poly(3,4-ethylenedioxythiophene) --- structural properties --- optical properties --- Surface Enhanced Raman Scattering (SERS) --- fabrication --- application --- agriculture --- food safety --- gold --- nanoparticles --- thiophenol --- silicon --- nonlinear optics --- sum-frequency generation --- UV-vis spectroscopy --- atomic force microscopy --- CLIO free electron laser --- inverse problem --- copper --- copper oxide
Choose an application
Nanoplasmonics is an area that uses light to couple electrons in metals, and can break the diffraction limit for light confinement into subwavelength zones, allowing for strong field enhancements. In the last two decades, there has been a resurgence of this research topic and its applications. Thus, this Special Issue presents a collection of articles and reviews by international researchers and is devoted to the recent advances in and insights into this research topic, including plasmonic devices, plasmonic biosensing, plasmonic photocatalysis, plasmonic photovoltaics, surface-enhanced Raman scattering, and surface plasmon resonance spectroscopy.
Technology: general issues --- History of engineering & technology --- Materials science --- plasmonics --- localized surface plasmon resonance --- high pressure --- sensing --- SERS --- two-dimensional material --- titanium carbide MXene --- near-field enhancement --- plasmonic material --- optical properties of ultra-thin dielectric films --- surface plasmon spectroscopy --- spectroscopic ellipsometry --- SHINERS --- core–shell nanoparticles --- catalysis --- electrochemistry --- nanowires --- back reflector --- solar cells --- plasmonic --- III-V semiconductor --- surface plasmon resonance --- photonic crystal D-shaped fiber --- refractive index sensor --- dispersion sensor --- second-order dispersion sensor --- waveguide --- SPPs --- FDTD --- bandstop filter --- CMT --- nanocrystalline cellulose --- optical characterization --- copper ion --- poly(3,4-ethylenedioxythiophene) --- structural properties --- optical properties --- Surface Enhanced Raman Scattering (SERS) --- fabrication --- application --- agriculture --- food safety --- gold --- nanoparticles --- thiophenol --- silicon --- nonlinear optics --- sum-frequency generation --- UV-vis spectroscopy --- atomic force microscopy --- CLIO free electron laser --- inverse problem --- copper --- copper oxide --- n/a --- core-shell nanoparticles
Choose an application
Nanoplasmonics is an area that uses light to couple electrons in metals, and can break the diffraction limit for light confinement into subwavelength zones, allowing for strong field enhancements. In the last two decades, there has been a resurgence of this research topic and its applications. Thus, this Special Issue presents a collection of articles and reviews by international researchers and is devoted to the recent advances in and insights into this research topic, including plasmonic devices, plasmonic biosensing, plasmonic photocatalysis, plasmonic photovoltaics, surface-enhanced Raman scattering, and surface plasmon resonance spectroscopy.
plasmonics --- localized surface plasmon resonance --- high pressure --- sensing --- SERS --- two-dimensional material --- titanium carbide MXene --- near-field enhancement --- plasmonic material --- optical properties of ultra-thin dielectric films --- surface plasmon spectroscopy --- spectroscopic ellipsometry --- SHINERS --- core–shell nanoparticles --- catalysis --- electrochemistry --- nanowires --- back reflector --- solar cells --- plasmonic --- III-V semiconductor --- surface plasmon resonance --- photonic crystal D-shaped fiber --- refractive index sensor --- dispersion sensor --- second-order dispersion sensor --- waveguide --- SPPs --- FDTD --- bandstop filter --- CMT --- nanocrystalline cellulose --- optical characterization --- copper ion --- poly(3,4-ethylenedioxythiophene) --- structural properties --- optical properties --- Surface Enhanced Raman Scattering (SERS) --- fabrication --- application --- agriculture --- food safety --- gold --- nanoparticles --- thiophenol --- silicon --- nonlinear optics --- sum-frequency generation --- UV-vis spectroscopy --- atomic force microscopy --- CLIO free electron laser --- inverse problem --- copper --- copper oxide --- n/a --- core-shell nanoparticles
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