| 2D material [1] |
| 2D Materials [1] |
| 2D materials [6] |
| 3-acetyl-2,5-dimethylthiophene [1] |
| 3D printing [1] |
| 3d transition metal oxides [1] |
| ?-Fe2O3 [1] |
| ?-Fe<sub>2</sub>O<sub>3</sub> thin film [1] |
| ?-sheets [1] |
| ]+ catalyst [3] |
| a.c. conductivity [1] |
| Ab initio [1] |
| Ab initio calculations [1] |
| Ab initio modelling [1] |
| Ablation duration [1] |
| absorber [1] |
| absorption [1] |
| AC conductivity renewable energy sources [1] |
| AC magnetic fields [1] |
| Accelerating voltages [1] |
| Acceleration cavities and superconducting magnets (high-temperature superconductor, radiation hardened magnets, normal-conducting, permanent magnet devices, wigglers and undulators) [1] |
| Accelerator Applications [1] |
| Acidic media [1] |
| Activated carbon [8] |
| Activated Carbon@FeOOH [1] |
| Activation energy [2] |
| Activation of CO2 [1] |
| Activation process [1] |
| Active particles [1] |
| Active site [1] |
| Active suspension [1] |
| additive engineering [2] |
| additive lithography [1] |
| Additives [1] |
| Adsorption [2] |
| adsorption [2] |
| Adsorption energies [1] |
| Adsorption isotherms [1] |
| Adsorption kinetics [1] |
| Adsorption of CO2 [1] |
| Advanced cyclic stability [1] |
| Ag-NPs [1] |
| Aggregates [1] |
| Aggregation model [1] |
| Alkaline media [1] |
| Alkalinity [1] |
| All-solid state [1] |
| Aluminum [1] |
| Aluminum compounds [2] |
| Ammonium chloride [1] |
| Amorphous content [1] |
| and computer simulations [1] |
| And melting [1] |
| Angle-resolved photoemission [1] |
| Anisotropic behaviors [1] |
| Anisotropic Dirac cone materials [1] |
| Anisotropy [2] |
| Anode material [1] |
| anode materials [1] |
| Anodes [1] |
| Antibodies [1] |
| Antiferromagnetic orderings [1] |
| Antiferromagnetic transition [1] |
| Antiferromagnetism [2] |
| APNR [1] |
| Applications [1] |
| Aqueous precursor [1] |
| Argon [1] |
| Armchair graphene nanoribbons [1] |
| Article [1] |
| article [2] |
| Aspect ratio [1] |
| Association reactions [1] |
| Asymmetric [1] |
| Asymmetric configurations [1] |
| Asymmetric supercapacitor [1] |
| Asymmetric supercapacitors [1] |
| Atomic force microscopy [1] |
| Atomic layer [1] |
| Atoms [3] |
| ATP biomolecule [2] |
| Axial distribution [1] |
| Axial magnetic field [1] |
| Bacterial biofilm [1] |
| Bacterial motion [1] |
| Ballistic conductance [1] |
| BaMnO3 [2] |
| Band Gap [2] |
| band gap [2] |
| Band structure [2] |
| Band-splitting [1] |
| Bandgap tuning [1] |
| Barium [1] |
| Barium compounds [2] |
| Barium zirconate [1] |
| Basil [2] |
| BaTiO<sub>3</sub> nanofiller [1] |
| Battery-type materials [1] |
| Bi<sub>2</sub>WO<sub>6</sub>/rGO [1] |
| BiFeO<sub>3</sub> [1] |
| Bimetallic clusters [1] |
| Bimetallic sulfides [1] |
| Bimetallic systems [1] |
| BiMnO3 [1] |
| Binary alloys [3] |
| Binding affinity [1] |
| binding affinity [1] |
| Binding energy [3] |
| Bioactive compounds [1] |
| BiOBr [1] |
| Biocompatibility [1] |
| Biodegradability [1] |
| Biofilm formation [1] |
| Biofilms [1] |
| Biomedical & bioengineering [1] |
| biomedical applications [1] |
| Biomedicine [1] |
| Biomolecules [1] |
| Biopolymers [1] |
| Biosensors [1] |
| BiPO<sub>4</sub> [1] |
| Bismuth compounds [3] |
| Bismuth titanate [3] |
| Blast [1] |
| blend polymer electrolyte [1] |
| Blend solid polymer electrolyte [3] |
| Blended solid polymeric thin films [2] |
| Blending [1] |
| Blood [1] |
| Blood plasma [1] |
| Blue Phosphorene [1] |
| Boltzmann transport theory [2] |
| Bond length [1] |
| Boron-based monolayers [1] |
| Bottom-up approach [1] |
| Building blockes [1] |
| Bulk-like [1] |
| Calcination [1] |
| Calcination temperature [1] |
| Calcium [2] |
| Calculations [2] |
| Capacitance [7] |
| capacitance retention [1] |
| Capacitive principle [1] |
| Capacitors [1] |
| Capacity [2] |
| Carbon [4] |
| carbon black [1] |
| Carbon dioxide [1] |
| Carbon modified [1] |
| Carbon nanotubes [2] |
| Carbonaceous electrode [1] |
| carbonaceous electrode [1] |
| Carrier concentration [3] |
| Carrier mobility [2] |
| carrier mobility [1] |
| Catalyst activity [1] |
| Catalyst selectivity [1] |
| Cathode Material [1] |
| Cathode material [1] |
| Cathodes [2] |
| Cell accumulation [1] |
| Cell-be [1] |
| Cell/B.E [1] |
| Cell/BE [1] |
| Cells [3] |
| cellulose [1] |
| Ceramic fabrication techniques [1] |
| Ceramic materials [1] |
| Ceramic samples [1] |
| Chains [1] |
| Chalcogenides [2] |
| Characterization [1] |
| Characterization techniques [2] |
| charge carrier dynamics [1] |
| Charge ordering [1] |
| Charge ordering phenomena [1] |
| Charge transfer resistance [1] |
| Chemical activation [1] |
| Chemical analysis [1] |
| Chemical bath deposition methods [1] |
| Chemical detection [1] |
| Chemical hardness [1] |
| Chemical method [1] |
| Chemical synthesis [2] |
| Chemical vapor deposition [1] |
| Chemical vapour deposition [1] |
| Chemical-bath deposition [1] |
| Chemisorption [1] |
| Chemisorptions [1] |
| chilling stress [1] |
| Chlorine compounds [2] |
| Cholesterol [1] |
| Cholesterol detection [1] |
| Cholesterol oxidase [1] |
| Ciprofloxacin antibiotic photocatalytic degradation [1] |
| circular dichroism [1] |
| Clean energy [1] |
| Clean energy sources [1] |
| CNF [1] |
| Co-doped [1] |
| CO2 hydrogenation [1] |
| CO<sub>2</sub> Capture [1] |
| Coated glass [1] |
| Cobalt compounds [1] |
| Colloidal Stability [1] |
| Colonisation [1] |
| Columbic efficiency [1] |
| Compact electronics [1] |
| Comparatives studies [1] |
| Complex conductivity [1] |
| Complex dielectric permittivities [1] |
| Complex Impedance Analysis [1] |
| Complex impedance spectroscopy [1] |
| Complex permittivity [1] |
| Complexation [1] |
| Composite [3] |
| Composites [2] |
| composites [1] |
| Composites electrodes [1] |
| Composition [1] |
| Compressed air [1] |
| Computational analysis [1] |
| Computational studies [1] |
| computer simulation [1] |
| COMSOL-Multiphysics [1] |
| Conducting polymer nanocomposites [1] |
| Conducting polymers [1] |
| Conductive additives [1] |
| Conductive materials [1] |
| Conductivity [3] |
| Constitutive analysis [1] |
| Constitutive parameters [1] |
| constitutive parameters [1] |
| Contrast agent [2] |
| Contrast Enhancement [1] |
| Contrast to noise ratio [1] |
| Conversion efficiency [2] |
| Copper [2] |
| Copper alloys [1] |
| Copper deposition [2] |
| Copper oxides [1] |
| Core-shell [1] |
| Coronavirus [2] |
| CoSe<sub>2</sub> [1] |
| Cost effectiveness [2] |
| Cost-effective material [1] |
| Coulombic efficiency [1] |
| Counter electrodes [1] |
| Covid-19 [1] |
| CR-39 [1] |
| Cr-doping [1] |
| Cr<sub>2</sub>O<sub>3</sub> nanoparticles [1] |
| Critical review [1] |
| Crystal impurities [1] |
| Crystal structure [1] |
| Crystalline nature [1] |
| Crystalline structure [1] |
| Crystallinity [1] |
| crystallite size [1] |
| Crystallization control [1] |
| crystallization control [1] |
| Cu/Al2O3 [1] |
| CuO doping [1] |
| CuO NPs [1] |
| Current voltage characteristics [1] |
| Current voltage curve [1] |
| Cycle [1] |
| Cycle lives [1] |
| Cyclic stability [1] |
| Cyclic voltammetry [5] |
| Cyclic voltammetry (CV) [1] |
| cyclic voltammetry (CV) [1] |
| Cytology [1] |
| D-band center model [1] |
| Dark current [2] |
| DC magnetron plasma [1] |
| Dc magnetron sputtering [1] |
| DC magnetron sputtering systems [1] |
| Decay time [1] |
| Defect passivation [1] |
| defect passivation [2] |
| Deformation mechanics [1] |
| Deformation potential theory [1] |
| Degrees of freedom (mechanics) [1] |
| delamination [1] |
| Densities of state [1] |
| density [1] |
| Density (specific gravity) [1] |
| Density functional theoretical calculation [1] |
| Density Functional Theory [1] |
| Density functional theory [14] |
| density functional theory [6] |
| Density functionals [1] |
| Density of States [1] |
| Density-functional theory calculations [1] |
| Density-functional-theory [3] |
| Depolarization [1] |
| Depolarization fields [1] |
| Deposition [3] |
| Deposition Parameters [1] |
| Deposition rates [3] |
| Depression [1] |
| Design and Development [1] |
| desolvation method [1] |
| Device application [1] |
| DFT [8] |
| DFT calculations [1] |
| Diagnostic facilities [1] |
| Dielectric Analysis . [1] |
| Dielectric and electro-optical properties [1] |
| Dielectric and ferroelectric properties [1] |
| Dielectric anisotropy [1] |
| Dielectric loss [1] |
| Dielectric loss spectra [1] |
| Dielectric losses [2] |
| Dielectric Permittivity [1] |
| Dielectric properties [8] |
| dielectric property, [1] |
| Dielectric relaxation [1] |
| Dielectric spectroscopy [1] |
| Dielectric strengths [1] |
| Dielectrics property [1] |
| Differential scanning calorimetry [2] |
| Diffuse reflectance spectroscopy [1] |
| Diffusion paths [1] |
| Diffusion resistance [1] |
| Digital storage [1] |
| Dirac cone [1] |
| Direct current magnetron sputtering [1] |
| Direct production [1] |
| Direct-to-indirect gap transitions [1] |
| Diseases [2] |
| Dispersion spectra [1] |
| Dispersions [1] |
| Dissociation [1] |
| Distribution functions [1] |
| Doctor blade [1] |
| Doped MoS<sub>2</sub> [1] |
| doping [1] |
| Doping (additives) [1] |
| Doping effects [1] |
| Double-layer capacitance [1] |
| Driving forces [1] |
| Drug delivery [1] |
| drug-binding affinity [1] |
| Dye-sensitized solar cells [1] |
| Dynamic deformation [1] |
| Dynamic trajectories [1] |
| ecologically friendly materials [1] |
| ECR plasma cavity [1] |
| EDLC [1] |
| EDS [1] |
| Effective mass approximation [1] |
| Effective strain [1] |
| Efficiency [2] |
| EIS [1] |
| Electric batteries [2] |
| Electric conductivity [1] |
| electric conductivity [1] |
| Electric discharges [3] |
| electric field [2] |
| Electric field profiles [1] |
| Electric fields [4] |
| Electric power factor [1] |
| Electric resistance [1] |
| electrical [1] |
| Electrical Conductivity [2] |
| Electrical conductivity [3] |
| Electrical contacts [1] |
| Electrical resistance [2] |
| Electrical resistances [1] |
| Electro-optical [1] |
| Electrocatalysis [1] |
| electrocatalyst [1] |
| Electrocatalysts [1] |
| electrocatalysts [1] |
| Electrocatalytic activity [1] |
| Electrochemical [1] |
| Electrochemical analysis [3] |
| electrochemical analysis [2] |
| Electrochemical applications [1] |
| Electrochemical characterization [1] |
| Electrochemical electrodes [5] |
| Electrochemical energy conversions [1] |
| Electrochemical impedance spectroscopy [1] |
| Electrochemical measurements [1] |
| Electrochemical mechanisms [1] |
| Electrochemical parameters [1] |
| Electrochemical performance [2] |
| Electrochemical properties [7] |
| electrochemical properties [1] |
| electrochemical reactions [1] |
| Electrochemicals [1] |
| electrochemistry [1] |
| electrode [1] |
| Electrode material [2] |
| electrode material [1] |
| electrode materials [1] |
| Electrodes [7] |
| Electrolyte [1] |
| Electrolyte solutions [1] |
| Electrolytes [7] |
| Electrolytic capacitors [1] |
| Electromagnetic fields [1] |
| electromagnetic wave [1] |
| electron beam irradiation [1] |
| Electron density measurement [2] |
| Electron emission [1] |
| Electron energy levels [2] |
| Electron energy loss spectroscopy [2] |
| Electron energy loss spectrum [1] |
| Electron irradiation [1] |
| Electron scattering [1] |
| Electron temperature [1] |
| electron transport [1] |
| Electron transport properties [2] |
| Electronic and magnetic properties [1] |
| Electronic band [1] |
| Electronic band gaps [1] |
| Electronic Conductivity [1] |
| Electronic conductivity [1] |
| Electronic device [1] |
| Electronic equipment [1] |
| Electronic Properties [1] |
| Electronic properties [8] |
| Electronic Structure [2] |
| Electronic structure [3] |
| electronic structure [1] |
| Electrons [2] |
| Electrostatic double-layer capacitor [1] |
| ELI [1] |
| Embedding Process [1] |
| emission [1] |
| Emission stability [1] |
| Energy [3] |
| energy [1] |
| Energy conversion efficiency [1] |
| Energy demands [2] |
| Energy density [7] |
| energy density [1] |
| Energy density (E<sub>d</sub>) [3] |
| Energy density and power density [1] |
| energy density etc [1] |
| Energy dissipation [2] |
| Energy efficiency [1] |
| Energy gap [10] |
| Energy loss-range profile [1] |
| Energy policy [1] |
| Energy storage [7] |
| energy storage [1] |
| Energy storage device [1] |
| energy storage devices [1] |
| Energy storage/conversion devices [5] |
| Energy technologies [1] |
| Engineering [1] |
| Enhanced conductivity [1] |
| Environment friendly [1] |
| Environmental pollutions [2] |
| Environmentally friendly [1] |
| Environmentally safe [1] |
| Epoxy nanocomposites [1] |
| Equation of state [1] |
| Equivalent series resistance [1] |
| Escherichia coli [1] |
| etching [1] |
| Ethylene [1] |
| Ethylene glycol [1] |
| Excitonic solar cells [1] |
| Experimental evidence [1] |
| External electric field [1] |
| Extraction [1] |
| extraction [1] |
| Extraction process [1] |
| Facile synthesis [1] |
| Fe content TiO2 [2] |
| Fe content TiO<sub>2</sub> [1] |
| Fe doping [1] |
| Fe<sub>3</sub>O<sub>4</sub>-?-Fe<sub>2</sub>O<sub>3</sub>hollow nanoparticles [1] |
| FeOOH [2] |
| Ferrites [4] |
| ferrites [1] |
| Ferro Electricity [1] |
| Ferroelectric [2] |
| Ferroelectric and piezoelectric properties [1] |
| Ferroelectric ceramics [1] |
| Ferroelectric liquid crystals [1] |
| Ferroelectric materials [1] |
| Ferroelectric properties [1] |
| Ferroelectric property [1] |
| Ferroelectricity [2] |
| Ferromagnetic character [1] |
| Ferromagnetic ferroelectrics [1] |
| Ferromagnetic materials [1] |
| Ferromagnetic transitions [1] |
| Ferromagnetism [2] |
| FESEM [3] |
| Field electron emissions [1] |
| Field emission [3] |
| Field emission cathodes [1] |
| Field emission microscopes [3] |
| Field emission scanning electron microscopes [2] |
| Field emission scanning electron microscopy [3] |
| Filled polymers [1] |
| Fillers [1] |
| Film preparation [3] |
| Film thickness [1] |
| Films [1] |
| films [1] |
| Finite-size effect [1] |
| First-principle study [1] |
| First-principles study [1] |
| first-principles theory [1] |
| Flat band potential [1] |
| Flexible device [1] |
| Floating potential fluctuation [1] |
| Floating potentials [1] |
| Flocculation [1] |
| Fluctuation [1] |
| fluidity [1] |
| Fluorine [1] |
| Fluorine doped tin oxide [1] |
| Football players [1] |
| Formation energies [1] |
| Fossil fuels [1] |
| Fourier transform infra reds [2] |
| Fourier transform infrared [1] |
| Fourier transform infrared spectra [1] |
| Fourier transform infrared spectroscopy [5] |
| Free cholesterols [1] |
| FT-IR [1] |
| FTIR [9] |
| Functionalizations [1] |
| Fuzzy sets [1] |
| Galvanostatic charge/discharge [1] |
| Galvanostatic charges [1] |
| Galvanostatic charging/discharging (GCD) [1] |
| Ganoderma boninense [1] |
| Gas adsorption [1] |
| Gas detectors [1] |
| Gas sensing properties [1] |
| Genomic DNA [1] |
| Germanene [1] |
| Giant stark effects [1] |
| Gibbs free energy [2] |
| Glass [2] |
| Glass substrates [1] |
| Glass transition [2] |
| Glass transition relaxation [1] |
| Glass transition temperature [2] |
| Global economies [1] |
| Global energy [1] |
| Gold [1] |
| Gold alloys [2] |
| gold cluster [1] |
| gold-hydrogen analogy [1] |
| Gold-Platinum Clusters [1] |
| graded heterojunctions [1] |
| gradient energy alignment [1] |
| Grain boundaries [1] |
| Grain size [1] |
| Grain size and shape [1] |
| Graphene [4] |
| graphene [2] |
| Graphene likes [1] |
| Graphene Nanoplatelets [1] |
| Graphene nanoribbon [1] |
| Graphene nanoribbons [1] |
| Graphene quantum dots [1] |
| Graphene spirals [1] |
| Graphite [1] |
| Green energy [1] |
| Ground state [1] |
| Growth rate [1] |
| Hairy roots [1] |
| handheld speedometer [1] |
| Harvesting devices [1] |
| Heating [1] |
| Heating efficiencies [1] |
| Heating performance [1] |
| Heavy metals [1] |
| Herbal medicines [1] |
| Hetero-structure [1] |
| Heterojunctions [3] |
| heterostructure [2] |
| Heterostructure interface [1] |
| Heterostructures [1] |
| Hexaferrite [1] |
| Hexagonal structures [1] |
| Hierarchical systems [1] |
| High aspect ratio [1] |
| High carrier mobility [1] |
| High efficiency [1] |
| high efficiency [1] |
| High energy forming [1] |
| High frequency [1] |
| High power rates [1] |
| High resolution transmission electron microscopy [2] |
| High-k dielectric [1] |
| Higher energy density [1] |
| Hole mobility [1] |
| Homogeneous suspensions [1] |
| homology modeling [1] |
| Hopping conductivity [1] |
| Hopping transport [1] |
| Host lattice [1] |
| Hugoniot model [1] |
| Human population [1] |
| human tissue [1] |
| Humidity sensor [1] |
| Hurst exponent [1] |
| hybrid [1] |
| hybrid capacitor [1] |
| Hybrid electrodes [1] |
| Hybrid materials [1] |
| Hybrid supercapacitor [1] |
| Hybrid supercapacitors [2] |
| Hydraulic structures [1] |
| Hydrazine hydrate [2] |
| Hydrodynamics [1] |
| Hydroelectric cell [1] |
| Hydrogen [5] |
| hydrogen doping [1] |
| Hydrogen Energy [1] |
| Hydrogen evolution reaction [1] |
| Hydrogen evolution reaction activities [1] |
| Hydrogen evolution reactions [1] |
| Hydrogen impurity [1] |
| Hydrogen production [1] |
| Hydrogen reduction [1] |
| Hydrogenation [1] |
| Hydrothermal [6] |
| hydrothermal [2] |
| Hydrothermal method [2] |
| Hydrothermal methods [1] |
| Hydrothermal synthesis [3] |
| Hydrothermal techniques [1] |
| Hydrothermal-synthesis [1] |
| Hyperthermia treatments [1] |
| Hysteresis [1] |
| Ideal tensile strengths [1] |
| II-VI semiconductors [2] |
| illumination [1] |
| Imaging [2] |
| impedance [1] |
| Impedance Spectroscopy [1] |
| Impedance spectroscopy [3] |
| impedance spectroscopy [1] |
| Impedance Spectroscopy, [1] |
| ImpedanceSpectroscopy [1] |
| implantation [1] |
| Impurities [1] |
| In-situ characterization [1] |
| Indicators (chemical) [1] |
| Industrial sector [1] |
| Infra-red [1] |
| Infrared photodetector [1] |
| Infrared spectroscopy [2] |
| Infrared vibrational spectra [1] |
| Infrared-active phonon [1] |
| Inhomogeneous distribution [1] |
| Inorganic metals [1] |
| Insulator-to-metal transitions [1] |
| integrated frequency selective surface (IFSS) [1] |
| Inter-particle interaction [1] |
| Interaction [1] |
| interaction [2] |
| Interaction of radiation with matter [1] |
| intercalation [1] |
| interface passivation [1] |
| Interfacial sites [1] |
| interrupt driven [1] |
| Intrinsic coherence resonance [1] |
| Ion exchange [1] |
| Ion implantation [2] |
| Ion interactions [1] |
| Ion sources [1] |
| Ion sources (positive ions, negative ions, electron cyclotron resonance (ECR), electron beam (EBIS)) [1] |
| ion transport mechanism [3] |
| Ion transport mechanisms [1] |
| Ion-implantation [1] |
| Ionic conduction in solids [1] |
| Ionic Conductivity [1] |
| Ionic conductivity [6] |
| Ionic nature [1] |
| Ions [4] |
| iron (II) oxide powder [1] |
| Iron oxide [3] |
| iron oxide [1] |
| Iron oxide nanomaterials [1] |
| Iron oxide nanoparticles [2] |
| Iron oxides [4] |
| Isotropics [1] |
| IV-VI semiconductors [1] |
| Janus monolayer [1] |
| Jaro-Winkler [1] |
| Kinetic energy [1] |
| Kinetics [1] |
| Kubelka-Munk function [1] |
| LaCoO<sub>3</sub>/NiCo<sub>2</sub>O<sub>4</sub> [1] |
| Land vehicle propulsion [1] |
| Langmuir probe [1] |
| Lanthanum compounds [1] |
| Large area arrays [1] |
| Large surface area [1] |
| laser [1] |
| lattice thermal conductivity [1] |
| Layered double hydroxides (LDHs) [1] |
| Layered semiconductors [1] |
| Layered transition metal dichalcogenides [1] |
| Lead acid batteries [1] |
| Lead compounds [2] |
| Lead free ceramics [2] |
| Lead-Free [1] |
| Lead-free ceramics [1] |
| Lead-free piezoelectric ceramic [1] |
| LED testing [1] |
| LEDs [1] |
| Length distributions [1] |
| Li- ion battery [1] |
| Li-ion batteries [1] |
| Li-ion battery [3] |
| Li<sub>2</sub>FeSiO<sub>4</sub> [1] |
| Li<sub>2</sub>MnSiO<sub>4</sub> [2] |
| Light [1] |
| Light absorption [4] |
| Light emitting diodes [2] |
| light scattering [1] |
| Light-harvesting [1] |
| Linear sweep voltammetry [1] |
| Liquid crystal biosensors [1] |
| Liquid crystals [2] |
| Liquid-crystal composites [1] |
| Liquid-phase method [1] |
| Lithium [2] |
| Lithium alloys [2] |
| Lithium compounds [1] |
| Lithium ion battery [1] |
| Lithium-ion batteries [4] |
| Long rang [1] |
| Low frequency magnetic fields [1] |
| Low glass transition temperatures [1] |
| Low-costs [1] |
| Low-frequency relaxation [1] |
| LR flat fuzzy numbers [1] |
| LRM [1] |
| Magnesium ferrite [1] |
| Magnetic and electrical properties [1] |
| Magnetic and transport properties [1] |
| Magnetic character [1] |
| magnetic field [1] |
| Magnetic field distribution [1] |
| Magnetic fields [2] |
| Magnetic hyperthermia [1] |
| magnetic hyperthermia [2] |
| Magnetic nanoflowers [1] |
| Magnetic nanoparticles [1] |
| magnetic nanoparticles [1] |
| Magnetic nanospheres [1] |
| Magnetic probes [1] |
| Magnetic remanence [1] |
| Magnetic resonance imaging [3] |
| Magnetic semiconductors [1] |
| Magnetic stability [1] |
| Magnetic susceptibility [1] |
| Magnetic vortex domain [1] |
| Magnetic vortex state [1] |
| Magnetic vortices [1] |
| Magnetic-luminescence [1] |
| Magnetism [5] |
| Magnetite [3] |
| Magnetite quenching [1] |
| Magnetization reversal [1] |
| Magneto-mechanical actuation [1] |
| Magnetoelectric couplings [1] |
| Magnetoelectrics [1] |
| Magnetron sputtering [2] |
| magnetron sputtering plasma [1] |
| Magnetron sputtering systems [1] |
| Manganese [1] |
| Manganese compounds [1] |
| Manganese dioxide (MnO<sub>2</sub>) [1] |
| Manganese oxide [3] |
| Manganites [2] |
| MD simulation [1] |
| Mechanical and electronic properties [2] |
| Mechanical behavior [1] |
| Mechanical exfoliation [1] |
| Mechanical properties [2] |
| Mechanical Relaxation [1] |
| Mechanical robustness [1] |
| Mechanical strain [1] |
| Mediated interaction [1] |
| Melting [1] |
| Melting point [1] |
| Membrane [1] |
| Memory applications [1] |
| Memory effect [1] |
| Meso-porous nano-carbon [1] |
| Mesoporous carbon [2] |
| mesoporous carbon [1] |
| Metal halides [1] |
| Metal insulator transition [1] |
| Metal ions [2] |
| Metal semiconductor interface [1] |
| Metal-induced gap state [1] |
| Metals [1] |
| Methanol [1] |
| Methanol synthesis [1] |
| Micro-structural [1] |
| Micro-structural properties [2] |
| micromagnetic simulation [1] |
| Micromagnetic simulations [2] |
| Microscopic interaction [1] |
| Microscopic techniques [1] |
| Microwave [1] |
| microwave [1] |
| Microwave ion source [1] |
| Microwave irradiation [1] |
| microwave method [1] |
| microwave radiation [1] |
| Microwave spectroscopy [2] |
| microwave spectroscopy [1] |
| microwave synthesis [2] |
| Microwave-assisted [1] |
| Microwave-assisted solvothermal method [1] |
| Microwaves [1] |
| Mitochondria [1] |
| mitochondria [1] |
| Mixed powder [1] |
| MMMT [1] |
| MnCo<sub>2</sub>O<sub>4</sub> [2] |
| MnO 2 [1] |
| MnO<sub>2</sub> [2] |
| Model and simulation [1] |
| Modeling parameters [1] |
| modelocked fiber lasers [1] |
| Modification of polymers [1] |
| modified dynamic hysteresis model [1] |
| molecular docking [2] |
| Molecular dynamics [1] |
| Molecular farming [1] |
| molecular physics [1] |
| Molecules [3] |
| Molybdenum compounds [1] |
| Molybdenum oxide [1] |
| Monoclinic/hexagonal phase [1] |
| Monolayer [1] |
| Monolayers [10] |
| Monomer concentration [1] |
| Monomers [1] |
| Morphology [4] |
| MoS2 [2] |
| MoS2 nano-sheets [1] |
| MoS<sub>2</sub> [6] |
| MoS<sub>2</sub>@CoS<sub>2</sub> [1] |
| MoS<sub>2</sub>@TiO<sub>2</sub> [1] |
| MoSe 2 [1] |
| MoSe2 [1] |
| MoSe<sub>2</sub> [3] |
| Moss�Burstein effect [1] |
| Motion [1] |
| motion [1] |
| Muga silk fibroin [1] |
| Muga silk nanoparticles [4] |
| multiferoic [2] |
| Multiferroic [1] |
| Multivalency [1] |
| Multiwalled carbon nanotubes (MWCN) [1] |
| MWCNT [1] |
| MXene [1] |
| Nano-carbons [2] |
| Nano-composites [2] |
| Nanobowls [1] |
| Nanocatalysts [1] |
| Nanocomposite [2] |
| nanocomposite [1] |
| Nanocomposite films [3] |
| Nanocomposites [9] |
| nanocomposites [1] |
| Nanocrystallines [1] |
| Nanocrystals [1] |
| Nanoferrites [1] |
| Nanofibers [1] |
| Nanoflakes [1] |
| nanoflower [1] |
| Nanomagnetic ferrites [1] |
| Nanomagnetics [1] |
| nanomaterial [1] |
| Nanomaterials [2] |
| Nanoneedles [1] |
| Nanoparticle (NPs) [1] |
| Nanoparticles [5] |
| nanoparticles [1] |
| Nanoribbons [3] |
| Nanorings [1] |
| Nanorods [2] |
| Nanoscale device [1] |
| Nanoscale electronic devices [1] |
| nanosheet [1] |
| Nanosheets [2] |
| Nanospheres [2] |
| Nanostructure [1] |
| Nanostructured materials [1] |
| Nanostructured thin film [1] |
| Nanosystems [2] |
| Nanotechnology [1] |
| Nanotubes [2] |
| Nanotubes and nanoflake photoconductivity [1] |
| Narrow band gap semiconductors [1] |
| Narrow-gap semiconductors [1] |
| Natural dye [2] |
| NDR region [1] |
| Near surfaces [1] |
| Negative differential conductance [1] |
| Nematic liquid crystal [2] |
| NetBeans [1] |
| Neutral medium [1] |
| Nickel compounds [1] |
| NiO-Co3O4 [1] |
| NiS/ZnS composite materials [1] |
| Nitrogen compounds [1] |
| Nitrogen oxides [1] |
| Noise component [1] |
| Non-magnetic semiconductors [1] |
| Non-stoichiometric materials [1] |
| Nonstoichiometric [1] |
| Ns-pulsed laser [1] |
| Nucleation and growth [1] |
| Numerical methods [1] |
| numerical modeling [1] |
| O phase [1] |
| OER [1] |
| Ohmic contacts [1] |
| Open circuit voltage [1] |
| Optical emission spectroscopy [1] |
| Optical energy gap [1] |
| Optical lattices [1] |
| Optical phonons [1] |
| Optical properties [3] |
| optical properties [1] |
| optical property [1] |
| optical property. [1] |
| Optical strain [1] |
| Optical tomography [1] |
| Optical transmittance and reflectance [1] |
| Optical- [1] |
| Optimized composites [1] |
| Optoelectronic devices [2] |
| Optoelectronic properties [1] |
| Optoelectronics [1] |
| Optoelectronics property [1] |
| Orange peel-derived carbon [1] |
| Orbital interaction [1] |
| Orbitals [1] |
| Order parameter [1] |
| organelles [1] |
| Organic reagents [1] |
| organic-inorganic materials [1] |
| Organic/inorganic [1] |
| Orthorhombic crystals [1] |
| Orthosilicate [1] |
| Oscillators (electronic) [1] |
| Ostwald ripening [1] |
| Oxide minerals [2] |
| oxygen evolution reaction [1] |
| Oxygen vacancies [1] |
| p-BiOBr/n-ZnWO<sub>4</sub> heterostructures [1] |
| p-n junction [1] |
| P-type [1] |
| PANI [1] |
| Particle walls [1] |
| Paschen curves [1] |
| Paschen minimums [1] |
| Passivation [3] |
| Peanut shell [1] |
| Pentagonal structures [1] |
| PEO [2] |
| Perceived stress [1] |
| Percolation (solid state) [1] |
| Performance [3] |
| Periodic boundary conditions [1] |
| Permeability [1] |
| Permittivity [3] |
| Perovskite [7] |
| Perovskite films [1] |
| perovskite oxides [2] |
| Perovskite solar cell [1] |
| perovskite solar cell [1] |
| Perovskite solar cells [1] |
| perovskite solar cells [1] |
| Perovskite type [1] |
| Personal protective equipment [1] |
| Phase space methods [1] |
| Phase structure [1] |
| Phase transition [1] |
| Phase transitions [1] |
| phonon [1] |
| Phonon dispersions [1] |
| Phonons [3] |
| Phosphorene [1] |
| phosphorene [2] |
| Photo Catalyst [1] |
| Photo-electrodes [1] |
| Photocatalysis [2] |
| Photocatalyst [1] |
| photocatalysts [1] |
| Photocatalytic [1] |
| Photocatalytic activity [1] |
| photocatalytic activity [1] |
| Photocatalytic property [1] |
| Photocatalytic water splitting [3] |
| Photocurrents [1] |
| Photodetector [3] |
| Photodetectors [2] |
| Photoelectrochemical cells [1] |
| Photoelectrochemical currents [1] |
| Photoelectrochemical properties [1] |
| Photoelectrochemical response radiolysis [1] |
| Photoelectrode [1] |
| Photoelectron spectroscopy [3] |
| photoluminescence (PL) [2] |
| Photons [1] |
| Photoresponsivity [1] |
| Photovoltaic property [1] |
| Photovoltaic solar cells [1] |
| physiochemical properties [1] |
| PIC?MCC [1] |
| Piezoelectric ceramics [2] |
| Piezoelectric property [1] |
| Piezoelectricity [3] |
| PL spectra [1] |
| Plant extracts [1] |
| Plasma devices [1] |
| Plasma diagnostics [1] |
| Plasma fluctuations [1] |
| Plasma parameter [1] |
| plasma parameters [1] |
| Plasma reduction [1] |
| plasma treatments [1] |
| Plasmonic nanostructures [1] |
| Plasmons [1] |
| Plasticity [1] |
| Platinum [2] |
| Platinum alloys [1] |
| Polarization-independent [1] |
| Polarizing optical microscopy [2] |
| polulation inversion [1] |
| Poly(vinylidene fluoride) [1] |
| Polycarbonate [1] |
| Polycrystalline samples [1] |
| Polyelectrolytes [4] |
| Polyethylene [2] |
| Polyethylene oxide [3] |
| polyethylene oxide [1] |
| Polyethylene oxide (PEO) [1] |
| Polyethylene oxides [1] |
| Polyethylenes [1] |
| Polymer blends [1] |
| Polymer ceramic composite [1] |
| Polymer composite [1] |
| Polymer electrolyte [4] |
| polymer electrolyte [1] |
| Polymer electrolyte films [1] |
| Polymer electrolyte films; [1] |
| Polymer electrolytes [1] |
| Polymer films [5] |
| polymer films [1] |
| Polymer matrix composites [1] |
| Polymer nanocomposite [1] |
| Polymer nanocomposites [2] |
| Polymer Nanocomposites . [1] |
| Polymer nocomposites; Ion dymics; electrochemical alysis; Energy storage/conversion devices [1] |
| Polymer pen lithography [1] |
| Polymer thin films [1] |
| Polymeric Films [1] |
| Polymers [4] |
| Polymorphism [1] |
| Polyvinyl chlorides [1] |
| pore size distribution [1] |
| Porosity [1] |
| Porous nature [1] |
| Porous networks [1] |
| Portable energy [1] |
| Potassium hydroxide [2] |
| Power conversion efficiencies [2] |
| Power densities [3] |
| Power density [3] |
| power density [1] |
| Power density (P<sub>d</sub>) [3] |
| Power spectrum [1] |
| Precious metals [1] |
| Preconditioned [1] |
| Preparation techniques [1] |
| pressure [1] |
| Primidone [1] |
| Probe spectroscopy [1] |
| Process parameters [1] |
| Production of hydrogen [1] |
| projectile sensor [1] |
| Properties [1] |
| Protective clothing [1] |
| Protein [1] |
| Pseudo-capacitor [1] |
| Pseudocapacitor [2] |
| Pure perovskite phase [1] |
| Pyrochlore [1] |
| Pyrolysis temperature [1] |
| quantitative analysis [1] |
| Quantum capacitance [1] |
| Quantum chemistry [2] |
| Quantum confinement effects [1] |
| radar cross-section (RCS) [1] |
| Radial distribution functions [1] |
| Raman spectroscopy [2] |
| Ranking functions [1] |
| Rare-earth magnetism and luminescence [1] |
| Rashba-splitting [1] |
| Rate of penetration [1] |
| reactive oxygen species (ROS) generation [1] |
| Real-life problems [1] |
| Recent researches [1] |
| Receptor-binding domains [1] |
| Rechargeable batteries [1] |
| Rechargeable lithium ion battery [1] |
| Red blood cell [1] |
| Red blood cells aggregations [1] |
| Redox reactions [3] |
| reduced graphene oxide [1] |
| Reference electrodes [1] |
| Reflectance spectrum [1] |
| Refractive Index [1] |
| refractive index [1] |
| Relative humidity [1] |
| Relaxation Time [1] |
| Relaxation time [7] |
| relaxation time [2] |
| Remanence [1] |
| Renewable energies [1] |
| Renewable energy (Solar) [1] |
| Renewable energy resources [1] |
| Renewable sources [1] |
| Research efforts [1] |
| Resistance switching memory [1] |
| Respiratory diseases [1] |
| Rhodamine B [1] |
| Rhodamine B dye [1] |
| Rhombohedral phase [1] |
| Rhombohedral phasis [1] |
| Ridge waveguides [1] |
| Rietveld refinement [1] |
| RLM [1] |
| RLWC [1] |
| Ru-rGO [1] |
| Running [1] |
| running [1] |
| Sandwich assay [1] |
| saturable absorbers [1] |
| Saturation magnetization [1] |
| Scalability [1] |
| Scalable methods [1] |
| Scanning electron microscope [1] |
| Scanning electron microscopy [6] |
| scanning probe nanolithography [1] |
| Scanning tunneling microscopy [1] |
| Scanning tunneling spectroscopy [1] |
| Scattering co-efficient [1] |
| Schottky barrier diodes [2] |
| Schottky barriers [1] |
| Schottky contact [1] |
| Schottky contacts [1] |
| Scientific community [1] |
| Secondary batteries [1] |
| secondary structures [1] |
| Selenium compounds [2] |
| Self assembled monolayers [1] |
| Self assembled nanostructures [1] |
| Self-doping feature [1] |
| Self-purposed charge storage mechanism [1] |
| self-regulated magnetic hyperthermia [1] |
| Semi-conducting property [1] |
| Semiconducting behavior [1] |
| Semiconducting films [1] |
| Semiconductor diodes [1] |
| Semiconductor doping [1] |
| Semiconductor materials [1] |
| Sensing mechanism [1] |
| Sensor applications [1] |
| Sensors [2] |
| Separators [2] |
| severe acute respiratory syndrome coronavirus-2 (SARS-COV-2) [1] |
| shape anisotropy [1] |
| Shielding efficiency [2] |
| shielding efficiency [1] |
| Shock waves [1] |
| Short-range attraction [1] |
| Si substrates [1] |
| Siesta [1] |
| sigma representation [1] |
| Silicene [1] |
| silicone [1] |
| Silver [3] |
| Silver alloys [1] |
| Silver doped magnesium vanadate [1] |
| Silver electrode [1] |
| SIMPLE method [1] |
| Simple++ [1] |
| simulation [1] |
| Simulation studies [1] |
| Simulation technique [1] |
| Single crystals [1] |
| Sintered samples [1] |
| Sintering [3] |
| Sintering temperatures [2] |
| Sm<sub>2</sub>O<sub>3</sub> [1] |
| Sodium compounds [2] |
| Sodium ion battery [1] |
| Sodium molybdate [1] |
| Sodium-ion batteries [1] |
| Sol-gel [1] |
| Sol-gel process [1] |
| Sol-gels [1] |
| Solar cell [4] |
| solar cell [1] |
| Solar cells [3] |
| Solar energy [1] |
| Solar energy conversions [1] |
| Solar energy storages [1] |
| solar power conversion efficiency [1] |
| Solar power generation [5] |
| Solar-to-hydrogen [2] |
| Solid electrolytes [4] |
| Solid polymer electrolyte [2] |
| solid polymer electrolyte [1] |
| Solid Polymer Electrolyte (SPE) [1] |
| Solid polymer electrolytes [1] |
| Solid polymers [1] |
| solid state [1] |
| Solid state reaction method [1] |
| Solid state reactions [1] |
| Solid state sintering [1] |
| Solid-state supercapacitors [1] |
| Sols [2] |
| Solution mixing process [1] |
| Solution-casting method [1] |
| Solvents [2] |
| Sources of energy [1] |
| Space Ratio [1] |
| Specific absorption rate [1] |
| Specific capacitance [5] |
| specific capacitance [1] |
| specific capacity [1] |
| specific energy density [1] |
| Specific heat [1] |
| Specific power [1] |
| Spectrometric techniques [1] |
| Spectroscopic analysis [1] |
| Spectroscopy [1] |
| spectroscopy [1] |
| Spin lattice coupling [1] |
| Spin-phonon coupling [1] |
| Spinel [1] |
| Spinel ferrite [2] |
| spinel oxides [1] |
| Splitting process [1] |
| Spray pyrolysis [5] |
| spray pyrolysis [1] |
| Spray-deposited [1] |
| Stability [2] |
| Stacked configuration [1] |
| Stacking patterns [1] |
| State of the art [1] |
| Static dielectric constants [1] |
| Statistical mechanics [2] |
| stealth [1] |
| Stego-Key [1] |
| Stereochemistry [1] |
| STM [1] |
| STM images [1] |
| Stoichiometry [2] |
| Storage (materials) [2] |
| Storage energy density [1] |
| Storage solutio [1] |
| Storage systems [2] |
| Storage-mechanism [1] |
| structural and optical properties [1] |
| Structural conformations [1] |
| Structural deformation [1] |
| Structural phase transformations [1] |
| Structural properties [2] |
| Structural stabilities [1] |
| Structural studies [1] |
| Structure and morphology [1] |
| Submicrometers [1] |
| Substrates [3] |
| subtractive lithography [1] |
| Sulfur compounds [1] |
| Sulfur dioxide [1] |
| Super capacitor [1] |
| Supercapacitance [1] |
| Supercapacitor [11] |
| supercapacitor [7] |
| Supercapacitor application [4] |
| Supercapacitors [4] |
| Supercapacitors (SCs) [1] |
| Superparamagnetic iron oxide (SPIONs) [1] |
| surface area [1] |
| Surface effect [1] |
| Surface free energy [1] |
| Surface functionalization [1] |
| Surface modification [1] |
| Surface morphology [2] |
| Surface passivation [2] |
| surface plasmon resonance [1] |
| Surface-controlled process [1] |
| Surfactant-free [1] |
| suspension [1] |
| Suspensions [1] |
| Suspensions (fluids) [2] |
| Swept source optical coherence tomographies [1] |
| Switching [1] |
| Symmetric supercapacitor [2] |
| symmetric supercapacitor [2] |
| Symmetric Supercapacitors [1] |
| Symmetrics [4] |
| Synergistic effect [1] |
| Synthesis [2] |
| synthesis [4] |
| Synthesis (chemical) [1] |
| Synthesis conditions [1] |
| Synthesis gas manufacture [1] |
| Synthesis phase [1] |
| Synthesised [1] |
| T<sub>1</sub>�T<sub>2</sub> dual weighted imaging [1] |
| Technological and physical field [1] |
| Technology [1] |
| Tellurium [2] |
| Tellurium compounds [5] |
| tellurium nanotubes [1] |
| TEM [1] |
| Temperature [1] |
| Temperature-dependent magnetizations [1] |
| Templates [1] |
| Tensile strain [1] |
| Tensile strength [3] |
| Ternary nanocomposite [1] |
| Ternary phase [1] |
| Tga-dsc [1] |
| Theoretical investigations [1] |
| Theoretical simulation [2] |
| Thermal behaviours [1] |
| Thermal conductivity [3] |
| thermal conductivity [1] |
| Thermal decomposition [1] |
| Thermal degradation [1] |
| Thermal effects [1] |
| Thermal measurements [1] |
| thermal plasma [1] |
| Thermo-Electric materials [1] |
| Thermodynamic stability [2] |
| Thermodynamical stability [1] |
| Thermoelectric equipment [2] |
| Thermoelectric material [1] |
| Thermoelectric performance [1] |
| Thermoelectric Properties [1] |
| Thermoelectric properties [2] |
| Thermoelectricity [2] |
| Thermogravimetric analysis [1] |
| Thermogravimetric analysis (TGA) [1] |
| Thermogravimitric Analysis [1] |
| Thermophysical [1] |
| Thick films [1] |
| Thickness of the film [1] |
| Thin film [3] |
| thin film [1] |
| Thin films [4] |
| thin films [1] |
| Thin-film technology [1] |
| Thin-films [1] |
| Three electrode-system [1] |
| Tin compounds [1] |
| Tin monoxides [1] |
| Tin oxides [1] |
| TiO2 (nanofiller vs. nanorod) [2] |
| TiO2 nanoparticles [1] |
| TiO<sub>2</sub> nanowire [1] |
| TiO<sub>2</sub>/Al<sub>2</sub>o<sub>3</sub> multilayer [1] |
| Tissue [1] |
| Tissue engineering [1] |
| Titanium [2] |
| Titanium compounds [1] |
| Titanium dioxide [5] |
| Titanium dioxides (TiO2) [1] |
| titanium thin film [1] |
| TMDs [2] |
| Tomography [1] |
| Topographical images [1] |
| Topological Insulator [1] |
| topological insulators [1] |
| Topological properties [2] |
| Torque [1] |
| torque [1] |
| Torsional strain [1] |
| Toxic materials [1] |
| Toxicity [1] |
| Traditional ceramics [1] |
| Transistors [2] |
| Transition metal dichalcogenides [2] |
| Transition metal oxides/hydroxides (TMOs/TMHs) [1] |
| Transition metals [2] |
| Transmission electron microscopy [2] |
| Transport mechanism [1] |
| Transport no [1] |
| Transport parameters [3] |
| Transport properties [1] |
| Transportation problem [1] |
| Trimetallic [1] |
| Tunables [1] |
| Tungstates [1] |
| Tungsten compounds [1] |
| tungsten disulfide nanoparticle [1] |
| Tunnel diodes [1] |
| Tunneling characteristics [1] |
| Tunneling current [1] |
| Twist deformations [1] |
| Two Dimensional (2 D) [1] |
| two dimensional structure [1] |
| Two-dimensional [3] |
| Two-dimensional materials [3] |
| Two-dimensional structures [1] |
| Two-electrode setup [1] |
| Uncertain environments [1] |
| Universal power law [1] |
| upconversion nanoparticles [1] |
| Urea [1] |
| UV light [1] |
| UV-blocking [1] |
| UV-visible [1] |
| UV�vis spectroscopy [2] |
| Valance bands [1] |
| Valence band photoemission spectra [1] |
| Van der Waal [1] |
| Van der waals [1] |
| Van der Waals forces [3] |
| Variant chemical composition [1] |
| VB [1] |
| Vertically aligned [1] |
| Verwey transition [1] |
| Vibration spectroscopy [1] |
| Viruses [1] |
| Visible region [1] |
| Visual and optical detection [1] |
| Voltage Window [1] |
| Vortex configurations [1] |
| Vortex domain structures [1] |
| Vortex flow [3] |
| Water absorption [1] |
| water electrolysis [1] |
| Water molecule [1] |
| Water splitting [2] |
| water splitting [1] |
| Wet chemical techniques [1] |
| Wet chemistry [1] |
| Wide band gap [1] |
| Wide band gap semiconductors [1] |
| Wide-gap semiconductor [1] |
| Wider potential window [1] |
| X and Ku bands [1] |
| X ray diffraction [4] |
| X ray diffraction; [1] |
| X ray photoelectron spectroscopy [2] |
| X ray photoemission spectroscopy [3] |
| X- ray diffractions [1] |
| X-ray diffraction [2] |
| X-ray methods [1] |
| XANES [1] |
| XPS [1] |
| XRD [2] |
| Yarn [1] |
| Zinc [1] |
| Zinc compounds [1] |
| Zinc oxide [2] |
| Zirconia [2] |
| Zirconia nanoparticles [1] |
| Zirconium [1] |
| ZnO [3] |
| ZnO thin film [1] |
| ZnWO<sub>4</sub> [1] |
| ZPNR [1] |
| ZrO<sub>2</sub> [1] |
| α-Fe2O3 [1] |
