Andrea Ponzoni scite author profile

Three-dimensional ͑3D͒ tungsten oxide nanowire networks have been demonstrated as a high-surface area material for building ultrasensitive and highly selective gas sensors. Utilizing the 3D hierarchical structure of the networks, high sensitivity has been obtained towards NO 2 , revealing the capability of the material to detect concentration as low as 50 ppb ͑parts per billion͒. The distinctive selectivity at different working temperatures is observed for various gases. The results highlight that the nanobelts ͑nanowires͒ technology can be adopted for the development of gas sensors with performances suitable for practical applications.

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Metal oxide nanoscience and nanotechnology for chemical sensors

Comini

Baratto

Concina

et al. 2013

Sensors and Actuators B: Chemical

167

107

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Cellulose Fibers Enable Near-Zero-Cost Electrical Sensing of Water-Soluble Gases

et al. 2019

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We report an entirely new class of printed electrical gas sensors that are produced at near "zero cost". This technology exploits the intrinsic hygroscopic properties of cellulose fibers within paper; although it feels and looks dry, paper contains substantial amount of moisture, adsorbed from the environment, enabling the use of wet chemical methods for sensing without manually adding water to the substrate. The sensors exhibit high sensitivity to water-soluble gases (e.g., lower limit of detection for NH 3 < 200 parts-per-billion) with a fast and reversible response. The sensors show comparable or better performance (especially at high relative humidity) than most commercial ammonia sensors at a fraction of their price (<$0.02 per sensor). We demonstrate that the sensors proposed can be integrated into food packaging to monitor freshness (to reduce food waste and plastic pollution) or implemented into near-field-communication tags to function as wireless, battery-less gas sensors that can be interrogated with smartphones.

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Metal Oxide Gas Sensors, a Survey of Selectivity Issues Addressed at the SENSOR Lab, Brescia (Italy)

Ponzoni

Baratto

Cattabiani

et al. 2017

Sensors

139

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This work reports the recent results achieved at the SENSOR Lab, Brescia (Italy) to address the selectivity of metal oxide based gas sensors. In particular, two main strategies are being developed for this purpose: (i) investigating different sensing mechanisms featuring different response spectra that may be potentially integrated in a single device; (ii) exploiting the electronic nose (EN) approach. The former has been addressed only recently and activities are mainly focused on determining the most suitable configuration and measurements to exploit the novel mechanism. Devices suitable to exploit optical (photoluminescence), magnetic (magneto-optical Kerr effect) and surface ionization in addition to the traditional chemiresistor device are here discussed together with the sensing performance measured so far. The electronic nose is a much more consolidated technology, and results are shown concerning its suitability to respond to industrial and societal needs in the fields of food quality control and detection of microbial activity in human sweat.

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Synthesis and characterization of semiconducting nanowires for gas sensing

Sberveglieri¹,

Baratto²,

Comini³

et al. 2007

Sensors and Actuators B: Chemical

167

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Bovine Serum Albumin protofibril-like aggregates formation: Solo but not simple mechanism

Vetri

D’Amico

Foderà

et al. 2011

Archives of Biochemistry and Biophysics

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Synthesis of In2O3–ZnO core–shell nanowires and their application in gas sensing

Singh

Ponzoni

Gupta

et al. 2011

Sensors and Actuators B: Chemical

134

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Semiconducting tin oxide nanowires and thin films for Chemical Warfare Agents detection

et al. 2009

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Andrea Ponzoni

Ultrasensitive and highly selective gas sensors using three-dimensional tungsten oxide nanowire networks

Metal oxide nanoscience and nanotechnology for chemical sensors

Cellulose Fibers Enable Near-Zero-Cost Electrical Sensing of Water-Soluble Gases

Metal Oxide Gas Sensors, a Survey of Selectivity Issues Addressed at the SENSOR Lab, Brescia (Italy)

Synthesis and characterization of semiconducting nanowires for gas sensing

Bovine Serum Albumin protofibril-like aggregates formation: Solo but not simple mechanism

Synthesis of In2O3–ZnO core–shell nanowires and their application in gas sensing

Semiconducting tin oxide nanowires and thin films for Chemical Warfare Agents detection

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