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Since the great success of graphene, atomically thin-layered nanomaterials, called two dimensional (2D) materials, have attracted tremendous attention due to their extraordinary physical properties. Specifically, van der Waals heterostructured architectures based on a few 2D materials, named atomic-scale Lego, have been proposed as unprecedented platforms for the implementation of versatile devices with a completely novel function or extremely high-performance, shifting the research paradigm in materials science and engineering. Thus, diverse 2D materials beyond existing bulk materials have been widely studied for promising electronic, optoelectronic, mechanical, and thermoelectric applications. Especially, this Special Issue included the recent advances in the unique preparation methods such as exfoliation-based synthesis and vacuum-based deposition of diverse 2D materials and also their device applications based on interesting physical properties. Specifically, this Editorial consists of the following two parts: Preparation methods of 2D materials and Properties of 2D materials
History of engineering & technology --- α-MoO3 --- carbon nitride --- g-C3N4 --- molybdenum trioxide --- nanoplates --- synthesis --- few-layer MoS2 --- magnetron sputtering --- magnetron sputtering power --- raman spectroscopy --- disorder --- V2Se9 --- atomic crystal --- mechanical exfoliation --- scanning Kelvin probe microscopy --- MoS2 --- black phosphorus --- 2D/2D heterojunction --- junction FET --- tunneling diode --- tunneling FET --- band-to-band tunneling (BTBT) --- natural molybdenite --- MoS2 nanosheet --- SiO2 --- liquid exfoliation --- photoelectric properties --- uniaxial strain --- flexible substrate --- film–substrate interaction --- photoluminescence --- Raman spectroscopy --- molybdenum disulfide --- bilayer-stacked structure --- WS2 --- lubricant additives --- tribological properties --- interfacial layer --- contact resistance --- bias stress stability --- saturable absorbers --- Langmuir–Blodgett technique --- Q-switched laser --- chemical vapor deposition --- P2O5 --- p-type conduction --- P-doped MoS2 --- transition metal dichalcogenides --- two-dimensional materials --- ferroelectrics --- 2D heterostructure --- WSe2 --- NbSe2 --- Nb2O5 interlayer --- synapse device --- neuromorphic system --- n/a --- film-substrate interaction --- Langmuir-Blodgett technique
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This highly informative and carefully presented book discusses the preparation, processing, characterization and applications of different types of nanoenergetic materials, as well as the tailoring of their properties. It gives an overview of recent advances of outstanding classes of energetic materials applied in the fields of physics, chemistry, aerospace, defense, and materials science, among others. The content of this book is relevant to researchers in academia and industry professionals working on the development of advanced nanoenergetic materials and their applications.
History of engineering & technology --- solid propellants --- condensed products --- catalytic combustion --- compositions --- rocket motor --- thermolysis --- energetic materials --- GO-based catalysts --- quantitative analyses --- decomposition mechanisms --- electrospinning --- NC/GAP/nano-LLM-105 --- energetic performance --- sensitivity --- nitrocellulose --- supercritical antisolvent process --- nanoparticles --- combustion --- nano AP --- nano AN --- liquid nitrogen --- freeze drying --- nanoenergetic material --- compatibility --- nonisothermal reaction kinetics --- thermal safety --- catalytic action --- nano-Al/MoO3 MIC --- stable suspension --- electrophoretic deposition --- kinetics --- micro initiator --- carbon mesosphere --- Fe2O3 --- supported nanoparticles --- thermal decomposition --- composite energetic materials --- nano-sized particles --- Al-based --- morphology performance --- hazardous properties --- ignition --- metal --- combustion mode --- heat transfer --- free-molecular --- burning time --- nanothermite --- pyroMEMS --- nanoenergetics --- reactive thin film --- Al --- CuO --- aging --- initiation --- HTPB --- aluminum nanopowders --- burning rate --- coated aluminum --- n/a --- reactive materials --- nanocomposite --- metal combustion --- thermal analysis
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Microporous zeolites and nanoporous materials are important from an academic and industrial research perspective. These inorganic materials have found application as catalysts in several industrial processes in oil refinery, petro-chemical reactions, fine chemicals, speciality, drug discovery and pharmaceutical synthesis, exhaust emission control for stationary and mobile engines and industrial wastewater treatment. The reasons for their versatile applications in several industrial processes are their unique properties of microporous zeolites and nanoporous materials such as uniform pores, channel systems, shape selectivity, resistance to coke formation, thermal and hydrothermal stability. Furthermore, the possibility to tune the amount and strength of Brønsted and Lewis acid sites and their crystal size, as well as the possibility of modification with transition and noble metals, are key to their success as efficient, high selectivity and stable catalysts.
Technology: general issues --- Chemical engineering --- zeolitic imidazolate frameworks --- Zn-Co@N-doped carbon --- transesterification --- Ti-CFI --- Ti-CIT-5 --- extra-large-pore --- zeolites --- fluorides --- titanosilicates --- oxidation --- generalized macro-transport theory --- adsorbent and non-adsorbent membranes --- bulk and surface diffusion --- heterogeneous catalysis --- mass transfer and effectiveness factor --- mesoporous H-ZSM-5 --- methanol-to-olefin (MTO) --- propylene --- acid sites density --- operando UV-vis spectroscopy --- CO2 assisted dehydrogenation --- isobutane --- silicalite-1 --- SBA-15 --- carbamazepine --- ozone --- catalysts synthesis and characterization --- catalytic ozonation --- isosorbide --- solid acid catalyst --- sorbitol --- dehydration --- bisphenol A --- diclofenac --- heterogeneous catalyst --- catalyst characterization --- advanced oxidation processes --- methanol to aromatics --- para-xylene --- selectivity --- phosphorous modified ZSM-5 --- advanced oxidation process --- catalyst preparation --- wastewater treatment --- interzeolite conversion method --- CHA-type zeolite --- LTL-type zeolite --- crystallization mechanism --- MTO reaction --- α-Pinene oxide --- campholenic aldehyde --- trans-carveol --- isomerization --- MoO3-zeolite BETA --- n/a
Choose an application
This highly informative and carefully presented book discusses the preparation, processing, characterization and applications of different types of nanoenergetic materials, as well as the tailoring of their properties. It gives an overview of recent advances of outstanding classes of energetic materials applied in the fields of physics, chemistry, aerospace, defense, and materials science, among others. The content of this book is relevant to researchers in academia and industry professionals working on the development of advanced nanoenergetic materials and their applications.
History of engineering & technology --- solid propellants --- condensed products --- catalytic combustion --- compositions --- rocket motor --- thermolysis --- energetic materials --- GO-based catalysts --- quantitative analyses --- decomposition mechanisms --- electrospinning --- NC/GAP/nano-LLM-105 --- energetic performance --- sensitivity --- nitrocellulose --- supercritical antisolvent process --- nanoparticles --- combustion --- nano AP --- nano AN --- liquid nitrogen --- freeze drying --- nanoenergetic material --- compatibility --- nonisothermal reaction kinetics --- thermal safety --- catalytic action --- nano-Al/MoO3 MIC --- stable suspension --- electrophoretic deposition --- kinetics --- micro initiator --- carbon mesosphere --- Fe2O3 --- supported nanoparticles --- thermal decomposition --- composite energetic materials --- nano-sized particles --- Al-based --- morphology performance --- hazardous properties --- ignition --- metal --- combustion mode --- heat transfer --- free-molecular --- burning time --- nanothermite --- pyroMEMS --- nanoenergetics --- reactive thin film --- Al --- CuO --- aging --- initiation --- HTPB --- aluminum nanopowders --- burning rate --- coated aluminum --- n/a --- reactive materials --- nanocomposite --- metal combustion --- thermal analysis
Choose an application
Microporous zeolites and nanoporous materials are important from an academic and industrial research perspective. These inorganic materials have found application as catalysts in several industrial processes in oil refinery, petro-chemical reactions, fine chemicals, speciality, drug discovery and pharmaceutical synthesis, exhaust emission control for stationary and mobile engines and industrial wastewater treatment. The reasons for their versatile applications in several industrial processes are their unique properties of microporous zeolites and nanoporous materials such as uniform pores, channel systems, shape selectivity, resistance to coke formation, thermal and hydrothermal stability. Furthermore, the possibility to tune the amount and strength of Brønsted and Lewis acid sites and their crystal size, as well as the possibility of modification with transition and noble metals, are key to their success as efficient, high selectivity and stable catalysts.
Technology: general issues --- Chemical engineering --- zeolitic imidazolate frameworks --- Zn-Co@N-doped carbon --- transesterification --- Ti-CFI --- Ti-CIT-5 --- extra-large-pore --- zeolites --- fluorides --- titanosilicates --- oxidation --- generalized macro-transport theory --- adsorbent and non-adsorbent membranes --- bulk and surface diffusion --- heterogeneous catalysis --- mass transfer and effectiveness factor --- mesoporous H-ZSM-5 --- methanol-to-olefin (MTO) --- propylene --- acid sites density --- operando UV-vis spectroscopy --- CO2 assisted dehydrogenation --- isobutane --- silicalite-1 --- SBA-15 --- carbamazepine --- ozone --- catalysts synthesis and characterization --- catalytic ozonation --- isosorbide --- solid acid catalyst --- sorbitol --- dehydration --- bisphenol A --- diclofenac --- heterogeneous catalyst --- catalyst characterization --- advanced oxidation processes --- methanol to aromatics --- para-xylene --- selectivity --- phosphorous modified ZSM-5 --- advanced oxidation process --- catalyst preparation --- wastewater treatment --- interzeolite conversion method --- CHA-type zeolite --- LTL-type zeolite --- crystallization mechanism --- MTO reaction --- α-Pinene oxide --- campholenic aldehyde --- trans-carveol --- isomerization --- MoO3-zeolite BETA --- n/a
Choose an application
Since the great success of graphene, atomically thin-layered nanomaterials, called two dimensional (2D) materials, have attracted tremendous attention due to their extraordinary physical properties. Specifically, van der Waals heterostructured architectures based on a few 2D materials, named atomic-scale Lego, have been proposed as unprecedented platforms for the implementation of versatile devices with a completely novel function or extremely high-performance, shifting the research paradigm in materials science and engineering. Thus, diverse 2D materials beyond existing bulk materials have been widely studied for promising electronic, optoelectronic, mechanical, and thermoelectric applications. Especially, this Special Issue included the recent advances in the unique preparation methods such as exfoliation-based synthesis and vacuum-based deposition of diverse 2D materials and also their device applications based on interesting physical properties. Specifically, this Editorial consists of the following two parts: Preparation methods of 2D materials and Properties of 2D materials
History of engineering & technology --- α-MoO3 --- carbon nitride --- g-C3N4 --- molybdenum trioxide --- nanoplates --- synthesis --- few-layer MoS2 --- magnetron sputtering --- magnetron sputtering power --- raman spectroscopy --- disorder --- V2Se9 --- atomic crystal --- mechanical exfoliation --- scanning Kelvin probe microscopy --- MoS2 --- black phosphorus --- 2D/2D heterojunction --- junction FET --- tunneling diode --- tunneling FET --- band-to-band tunneling (BTBT) --- natural molybdenite --- MoS2 nanosheet --- SiO2 --- liquid exfoliation --- photoelectric properties --- uniaxial strain --- flexible substrate --- film–substrate interaction --- photoluminescence --- Raman spectroscopy --- molybdenum disulfide --- bilayer-stacked structure --- WS2 --- lubricant additives --- tribological properties --- interfacial layer --- contact resistance --- bias stress stability --- saturable absorbers --- Langmuir–Blodgett technique --- Q-switched laser --- chemical vapor deposition --- P2O5 --- p-type conduction --- P-doped MoS2 --- transition metal dichalcogenides --- two-dimensional materials --- ferroelectrics --- 2D heterostructure --- WSe2 --- NbSe2 --- Nb2O5 interlayer --- synapse device --- neuromorphic system --- n/a --- film-substrate interaction --- Langmuir-Blodgett technique
Choose an application
Since the great success of graphene, atomically thin-layered nanomaterials, called two dimensional (2D) materials, have attracted tremendous attention due to their extraordinary physical properties. Specifically, van der Waals heterostructured architectures based on a few 2D materials, named atomic-scale Lego, have been proposed as unprecedented platforms for the implementation of versatile devices with a completely novel function or extremely high-performance, shifting the research paradigm in materials science and engineering. Thus, diverse 2D materials beyond existing bulk materials have been widely studied for promising electronic, optoelectronic, mechanical, and thermoelectric applications. Especially, this Special Issue included the recent advances in the unique preparation methods such as exfoliation-based synthesis and vacuum-based deposition of diverse 2D materials and also their device applications based on interesting physical properties. Specifically, this Editorial consists of the following two parts: Preparation methods of 2D materials and Properties of 2D materials
α-MoO3 --- carbon nitride --- g-C3N4 --- molybdenum trioxide --- nanoplates --- synthesis --- few-layer MoS2 --- magnetron sputtering --- magnetron sputtering power --- raman spectroscopy --- disorder --- V2Se9 --- atomic crystal --- mechanical exfoliation --- scanning Kelvin probe microscopy --- MoS2 --- black phosphorus --- 2D/2D heterojunction --- junction FET --- tunneling diode --- tunneling FET --- band-to-band tunneling (BTBT) --- natural molybdenite --- MoS2 nanosheet --- SiO2 --- liquid exfoliation --- photoelectric properties --- uniaxial strain --- flexible substrate --- film–substrate interaction --- photoluminescence --- Raman spectroscopy --- molybdenum disulfide --- bilayer-stacked structure --- WS2 --- lubricant additives --- tribological properties --- interfacial layer --- contact resistance --- bias stress stability --- saturable absorbers --- Langmuir–Blodgett technique --- Q-switched laser --- chemical vapor deposition --- P2O5 --- p-type conduction --- P-doped MoS2 --- transition metal dichalcogenides --- two-dimensional materials --- ferroelectrics --- 2D heterostructure --- WSe2 --- NbSe2 --- Nb2O5 interlayer --- synapse device --- neuromorphic system --- n/a --- film-substrate interaction --- Langmuir-Blodgett technique
Choose an application
Microporous zeolites and nanoporous materials are important from an academic and industrial research perspective. These inorganic materials have found application as catalysts in several industrial processes in oil refinery, petro-chemical reactions, fine chemicals, speciality, drug discovery and pharmaceutical synthesis, exhaust emission control for stationary and mobile engines and industrial wastewater treatment. The reasons for their versatile applications in several industrial processes are their unique properties of microporous zeolites and nanoporous materials such as uniform pores, channel systems, shape selectivity, resistance to coke formation, thermal and hydrothermal stability. Furthermore, the possibility to tune the amount and strength of Brønsted and Lewis acid sites and their crystal size, as well as the possibility of modification with transition and noble metals, are key to their success as efficient, high selectivity and stable catalysts.
zeolitic imidazolate frameworks --- Zn-Co@N-doped carbon --- transesterification --- Ti-CFI --- Ti-CIT-5 --- extra-large-pore --- zeolites --- fluorides --- titanosilicates --- oxidation --- generalized macro-transport theory --- adsorbent and non-adsorbent membranes --- bulk and surface diffusion --- heterogeneous catalysis --- mass transfer and effectiveness factor --- mesoporous H-ZSM-5 --- methanol-to-olefin (MTO) --- propylene --- acid sites density --- operando UV-vis spectroscopy --- CO2 assisted dehydrogenation --- isobutane --- silicalite-1 --- SBA-15 --- carbamazepine --- ozone --- catalysts synthesis and characterization --- catalytic ozonation --- isosorbide --- solid acid catalyst --- sorbitol --- dehydration --- bisphenol A --- diclofenac --- heterogeneous catalyst --- catalyst characterization --- advanced oxidation processes --- methanol to aromatics --- para-xylene --- selectivity --- phosphorous modified ZSM-5 --- advanced oxidation process --- catalyst preparation --- wastewater treatment --- interzeolite conversion method --- CHA-type zeolite --- LTL-type zeolite --- crystallization mechanism --- MTO reaction --- α-Pinene oxide --- campholenic aldehyde --- trans-carveol --- isomerization --- MoO3-zeolite BETA --- n/a
Choose an application
This highly informative and carefully presented book discusses the preparation, processing, characterization and applications of different types of nanoenergetic materials, as well as the tailoring of their properties. It gives an overview of recent advances of outstanding classes of energetic materials applied in the fields of physics, chemistry, aerospace, defense, and materials science, among others. The content of this book is relevant to researchers in academia and industry professionals working on the development of advanced nanoenergetic materials and their applications.
solid propellants --- condensed products --- catalytic combustion --- compositions --- rocket motor --- thermolysis --- energetic materials --- GO-based catalysts --- quantitative analyses --- decomposition mechanisms --- electrospinning --- NC/GAP/nano-LLM-105 --- energetic performance --- sensitivity --- nitrocellulose --- supercritical antisolvent process --- nanoparticles --- combustion --- nano AP --- nano AN --- liquid nitrogen --- freeze drying --- nanoenergetic material --- compatibility --- nonisothermal reaction kinetics --- thermal safety --- catalytic action --- nano-Al/MoO3 MIC --- stable suspension --- electrophoretic deposition --- kinetics --- micro initiator --- carbon mesosphere --- Fe2O3 --- supported nanoparticles --- thermal decomposition --- composite energetic materials --- nano-sized particles --- Al-based --- morphology performance --- hazardous properties --- ignition --- metal --- combustion mode --- heat transfer --- free-molecular --- burning time --- nanothermite --- pyroMEMS --- nanoenergetics --- reactive thin film --- Al --- CuO --- aging --- initiation --- HTPB --- aluminum nanopowders --- burning rate --- coated aluminum --- n/a --- reactive materials --- nanocomposite --- metal combustion --- thermal analysis
Choose an application
Significant progress has been made in nanophotonics and the use of nanostructured materials for optoelectronic devices, including light-emitting diodes (LEDs) and laser diodes, which have recently attracted considerable attention due to their unique geometry. Nanostructures in small dimensions, comprising nanowires, nanotubes, and nanoparticles, etc,. can be perfectly integrated into a variety of technological platforms, offering novel physical and chemical properties for high-performance, light-emitting devices. This Special Issue aims to present the most recent advances in the field of nanophotonics, which focuses on LEDs and laser diodes. We invite contributions of original research articles, as well as review articles that are aligned to the following topics that include, but are not limited to, thetheoretical calculation, synthesis, characterization, and application of such novel nanostructures for light-emitting devices. The application of nanostructured light-emitters in general lighting, imaging, and displays is also highly encouraged.
History of engineering & technology --- Liquid phase deposition method --- InGaN/GaN light-emitting diode --- silver nanoparticle --- zinc oxide --- localized surface plasmon --- β-Ga2O3 --- III-Nitrides --- monoclinic --- hexagonal arrangement --- high-power --- current distribution --- vertical structure LED --- blue organic light emitting diodes --- transport materials --- host-dopant --- nanoparticles --- luminescence --- non-stoichiometric ZnxAgyInS1.5+x+0.5y nanocrystals --- photoluminescence properties --- tunable fluorescence emission --- one-pot approach --- perovskite light-emitting diodes --- three-step spin coating --- hole transport layer --- PEDOT:PSS/MoO3-ammonia composite --- μLED displays --- μLEDs --- GaN nanowires --- core-shell structure --- ultraviolet (UV) emitter --- surface plasmon --- Pt nanoparticles --- hole-pattern --- photon emission efficiency --- distributed Bragg reflectors --- gratings --- GaN-based lasers --- linewidth --- epsilon-near-zero --- wideband absorber --- plasmon mode --- Brewster mode --- visible light communication --- photonic crystals --- flip-chip LED --- Purcell effect --- light extraction efficiency --- nanostructured materials --- surface/interface properties --- nanostructured light-emitting devices --- physical mechanism --- surface/interface modification --- surface/interface control --- micro-scale light emitting diode --- sapphire substrate --- encapsulation --- compound semiconductor --- nanostructure --- ultraviolet --- light-emitting diode (LED) --- molecular beam epitaxy --- GaN --- AlN --- photonic nanojet --- photonic nanojet array --- self-assembly --- template-assisted self-assembly --- patterning efficiency --- III-nitride thin film --- nanostructures --- ultraviolet emitters --- surface passivation --- luminescence intensity --- n/a
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