ACS applied materials & interfaces

Scientific reports

Nanomaterials (Basel, Switzerland)

Frontiers in chemistry

Sensors (Basel, Switzerland)

acs nano

Analytical chemistry

Journal of hazardous materials

Nanotechnology

ACS sensors

[1] Two-Dimensional Graphene Family Material: Assembly, Biocompatibility and Sensors Applications.

[2] Conductance Model for Single-Crystalline/Compact Metal Oxide Gas-Sensing Layers in the Nondegenerate Limit: Example of Epitaxial SnO(101).

[3] Reliable Anatase-Titania Nanoclusters Functionalized GaN Sensor Devices for UV assisted NO2 Gas-Sensing in ppb level.

[4] Ultrathin agaric-like ZnO with Pd dopant for aniline sensor and DFT investigation.

[5] Nanotransfer Printing on Textile Substrate with Water-Soluble Polymer Nanotemplate.

[6] Hydrogen Detection with SAW Polymer/Quantum Dots Sensitive Films.

[7] Laser-generated BiVO colloidal particles with tailoring size and native oxygen defect for highly efficient gas sensing.

[8] Synthesis of ZnO Nanostructures for Low Temperature CO and UV Sensing

[9] Smart Multi-Sensor Platform for Analytics and Social Decision Support in Agriculture

[10] A Single Nanobelt Transistor for Gas Identification: Using a Gas-Dielectric Strategy

[11] Gas Biosensor Arrays Based on Single-Stranded DNA-Functionalized Single-Walled Carbon Nanotubes for the Detection of Volatile Organic Compound Biomarkers Released by Huanglongbing Disease-Infected Citrus Trees

[12] Gas Sensors Based on Conducting Polymers

[13] Surface Acoustic Wave Hydrogen Sensors Based on Nanostructured Pd/WO3 Bilayers

[14] Smart Multi-Sensor Platform for Analytics and Social Decision Support in Agriculture

[15] Gas Biosensor Arrays Based on Single-Stranded DNA-Functionalized Single-Walled Carbon Nanotubes for the Detection of Volatile Organic Compound Biomarkers Released by Huanglongbing Disease-Infected Citrus Trees

[16] 2d sno2 nanosheets: synthesis, characterization, structures, and excellent sensing performance to ethylene glycol

[17] mesoporous wn/wo3-composite nanosheets for the chemiresistive detection of no2 at room temperature

[18] catalysis-based cataluminescent and conductometric gas sensors: sensing nanomaterials, mechanism, applications and perspectives

[19] the influence of platinum dopant on the characteristics of sno2thin film for gas sensor application

[20] metal oxide nanostructures in food applications: quality control and packaging

[21] synthesis, characterization and sensing properties of azo and izo nanomaterials

[22] effect of ni doping on gas sensing performance of zno thick film resistor

[23] Harnessing self-heating in nanowires for energy efficient, fully autonomous and ultra-fast gas sensors

[24] Development of a Novel Gas-Sensing Platform Based on a Network of Metal Oxide Nanowire Junctions Formed on a Suspended Carbon Nanomesh Backbone

[25] Operation Temperature Effects on a Microwave Gas Sensor with and without Sensitive Material.

[26] When organometallic chemistry and metal oxide nanoparticles meet optimized silicon based gas sensor

[27] MOFs-Derived Porous NiFeO Nano-Octahedrons with Hollow Interiors for an Excellent Toluene Gas Sensor.

[28] Electrospun ZnO Nanowires as Gas Sensors for Ethanol Detection

[29] ZnO/ZnS core/shell nanostructures based gas sensor for sensing Acetone gas at room temperature

[30] CNTs-CuO/SnO2 based gas sensor for detecting H2S in low concentration.

[31] Gas Sensor by Direct Growth and Functionalization of Metal Oxide/Metal Sulfide Core-Shell Nanowires on Flexible Substrates.

[32] CdS quantum dots supported by ultrathin porous nanosheets assembled into hollowed-out Co<inf>3</inf>O<inf>4</inf> microspheres: A room-temperature H<inf>2</inf>S gas sensor with ultra-fast response and recovery

[33] A fast response/recovery ppb-level H<inf>2</inf>S gas sensor based on porous CuO/ZnO heterostructural tubule via confined effect of absorbent cotton

[34] Solid Electrolyte Gas Sensor Based on a Proton-Conducting Graphene Oxide Membrane.

[35] Room-temperature gas sensors based on ZnO nanorod/Au hybrids: Visible-light-modulated dual selectivity to NO<inf>2</inf> and NH<inf>3</inf>

[36] Highly sensitive surface acoustic wave HCl gas sensors based on hydroxyl-rich sol-gel AlO<inf>x</inf>OH<inf>y</inf> films

[37] Twofold Porosity and Surface Functionalization Effect on Pt-Porous GaN for High-Performance H-Gas Sensors at Room Temperature.

[38] Fabrication and H-Sensing Properties of SnO Nanosheet Gas Sensors.

[39] High Sensitivity of NO Gas Sensors Based on Novel Ag-Doped ZnO Nanoflowers Enhanced with a UV Light-Emitting Diode.

[40] Superior triethylamine detection at room temperature by {-112} faceted WO<inf>3</inf> gas sensor

[41] Pt-Cr<inf>2</inf>O<inf>3</inf>-WO<inf>3</inf> composite nanofibers as gas sensors for ultra-high sensitive and selective xylene detection

[42] Outdoor air monitoring: Performance evaluation of a gas sensor to assess episodic nuisance/odorous events using active multi-sorbent bed tube sampling coupled to TD-GC/MS analysis

[43] Gas Sensors Based on Chemically Reduced Holey Graphene Oxide Thin Films

[44] High sensitivity NH<inf>3</inf> gas sensor with electrical readout made on paper with perovskite halide as sensor material

[45] Author Correction: Low-Temperature Ionic Layer Adsorption and Reaction Grown Anatase TiO<inf>2</inf> Nanocrystalline Films for Efficient Perovskite Solar Cell and Gas Sensor Applications (Scientific Reports, (2018), 8, 1, (11016), 10.1038/s41598-018-29363-0)

[46] NO gas sensor based on ZnGa <inf>2</inf> O <inf>4</inf> epilayer grown by metalorganic chemical vapor deposition

[47] Sub-ppm acetic acid gas sensor based on In<inf>2</inf>O<inf>3</inf> nanofibers

[48] Room temperature gas sensor based on tin dioxide@ polyaniline nanocomposite assembled on flexible substrate: ppb-level detection of NH<inf>3</inf>

[49] Array of chemiresistors for single input multiple output (SIMO) variation-tolerant all printed gas sensor

[50] Deactivation mechanism and anti-deactivation modification of SnO<inf>2</inf>-based catalysts for methane gas sensors

[51] Design of highly sensitive and selective xylene gas sensor based on Ni-doped MoO<inf>3</inf> nano-pompon

[52] High sensitive reduced graphene oxide-based room temperature ionic liquid electrochemical gas sensor with carbon-gold nanocomposites amplification

[53] A DFT study of In doped Tl<inf>2</inf>O: a superior NO<inf>2</inf> gas sensor with selective adsorption and distinct optical response

[54] Rationally designed mesoporous In<inf>2</inf>O<inf>3</inf> nanofibers functionalized Pt catalysts for high-performance acetone gas sensors

[55] Room temperature fiber optic gas sensor technology based on nanocrystalline Ba<inf>3</inf> (VO<inf>4</inf>)<inf>2</inf>: Design, spectral and surface science

[56] Facile fabrication of ZnO/C nanoporous fibers and ZnO hollow spheres for high performance gas sensor

[57] Temperature Modulation with Specified Detection Point on Metal Oxide Semiconductor Gas Sensors for E-Nose Application

[58] High-temperature CO / HC gas sensors to optimize firewood combustion in low-power fireplaces

[59] Rapid Prototyping of MOX Gas Sensors in Form-Factor of SMD Packages

[60] A novel solid state non-dispersive infrared CO2 gas sensor compatible with wireless and portable deployment.

[61] Quantum Capacitance Model for Graphene FET-Based Gas Sensor

[62] MEMS based highly sensitive dual FET gas sensor using graphene decorated Pd-Ag alloy nanoparticles for H<inf>2</inf> detection

[63] Advanced Micro- and Nano-Gas Sensor Technology: A Review.

[64] The fabrication of high sensitivity gold nanorod H2S gas sensors utilizing the highly uniform anodic aluminum oxide template

[65] Nanomaterial Gas Sensors for Online Monitoring System of Fruit Jams.

[66] Investigation of indoor air quality in a low energy high school building combining micro gas sensors and unsupervised learning

[67] A Rapid Process for Fabricating Gas Sensors

[68] Validation of a novel Multi-Gas sensor for volcanic HCl alongside HS and SO at Mt. Etna.

[69] Novel Miniature and Selective Combustion-Type CMOS Gas Sensor for Gas-Mixture Analysis-Part 1: Emphasis on Chemical Aspects.

[70] Design of Highly Selective Gas Sensors via Physicochemical Modification of Oxide Nanowires: Overview

[71] Exploitation of Unique Properties of Zeolites in the Development of Gas Sensors

[72] Metal Oxide Gas Sensors: Sensitivity and Influencing Factors

[73] Microfabricated Formaldehyde Gas Sensors

[74] Metal Oxide Semi-Conductor Gas Sensors in Environmental Monitoring

[75] Gas Sensors Based on Conducting Polymers

[76] effect of water vapor and surface morphology on the low temperature response of metal oxide semiconductor gas sensors

[77] volatile organic compounds gas sensors based on molybdenum oxides: a mini review

[78] response optimization of a chemical gas sensor array using temperature modulation

[79] formulation and characterization of cr2o3 doped zno thick films as h2s gas sensor

[80] polymer based gas sensors

[81] catalysis-based cataluminescent and conductometric gas sensors: sensing nanomaterials, mechanism, applications and perspectives

[82] effect of varying the semiconducting/metallic tube ratio on the performance of mixed single-walled carbon nanotube network gas sensors

[83] the influence of platinum dopant on the characteristics of sno2thin film for gas sensor application

[84] study on hydrogen gas concentration to voltage and resistance using semiconductor hydrogen gas sensor

[85] Harnessing self-heating in nanowires for energy efficient, fully autonomous and ultra-fast gas sensors

[86] Microfabricated formaldehyde gas sensors

[87] Characterization and Neural Modeling of a Microwave Gas Sensor for Oxygen Detection Aimed at Healthcare Applications

[88] Metal oxide gas sensors: sensitivity and influencing factors

[89] Operation Temperature Effects on a Microwave Gas Sensor with and without Sensitive Material.

[90] Correction: Bibi et al. Valorization of Agricultural Waste as a Chemiresistor HS-Gas Sensor: A Composite of Biodegradable-Electroactive Polyurethane-Urea and Activated-Carbon Composite Derived from Coconut-Shell Waste. 2023, , 685.