Water adsorbate mediated accumulation gas sensing at hydrogenated diamond surfaces

Sebastian Beer; Andreas Helwig; Gerhard Müller; Jose Garrido; Martin Stutzmann

doi:10.1016/j.snb.2013.02.072

Water adsorbate mediated accumulation gas sensing at hydrogenated diamond surfaces

Sebastian Beer, Andreas Helwig, Gerhard Müller, Jose Garrido, Martin Stutzmann

TUM Emeriti of Excellence

Research output: Contribution to journal › Article › peer-review

20 Scopus citations

Abstract

Hydrogenated diamond (HD) specimens feature a peculiar form of gas response which occurs at room temperature and which is mediated by a thin layer of water that tends to accumulate on HD surfaces as these are exposed to normal atmospheric conditions. HD specimens are known to be sensitive to gases and vapours that are capable of forming acid-base reactions in liquid water. In this paper we show that HD sensors feature a novel kind of accumulating gas response which-under favourable conditions-comes close to an integrator-like behaviour. In this integrator-limit of operation, the HD gas response becomes proportional to the total flow of reactive gases that had been interacting with the water adsorbate layer on top of the HD sensors.

Original language	English
Pages (from-to)	894-903
Number of pages	10
Journal	Sensors and Actuators, B: Chemical
Volume	181
DOIs	https://doi.org/10.1016/j.snb.2013.02.072
State	Published - 2013

Keywords

Accumulation
Adsorbed water
Diamond
Electrolytic dissociation
Gas sensor
Integration

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title = "Water adsorbate mediated accumulation gas sensing at hydrogenated diamond surfaces",

abstract = "Hydrogenated diamond (HD) specimens feature a peculiar form of gas response which occurs at room temperature and which is mediated by a thin layer of water that tends to accumulate on HD surfaces as these are exposed to normal atmospheric conditions. HD specimens are known to be sensitive to gases and vapours that are capable of forming acid-base reactions in liquid water. In this paper we show that HD sensors feature a novel kind of accumulating gas response which-under favourable conditions-comes close to an integrator-like behaviour. In this integrator-limit of operation, the HD gas response becomes proportional to the total flow of reactive gases that had been interacting with the water adsorbate layer on top of the HD sensors.",

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T1 - Water adsorbate mediated accumulation gas sensing at hydrogenated diamond surfaces

AU - Beer, Sebastian

AU - Helwig, Andreas

AU - Müller, Gerhard

AU - Garrido, Jose

AU - Stutzmann, Martin

PY - 2013

Y1 - 2013

N2 - Hydrogenated diamond (HD) specimens feature a peculiar form of gas response which occurs at room temperature and which is mediated by a thin layer of water that tends to accumulate on HD surfaces as these are exposed to normal atmospheric conditions. HD specimens are known to be sensitive to gases and vapours that are capable of forming acid-base reactions in liquid water. In this paper we show that HD sensors feature a novel kind of accumulating gas response which-under favourable conditions-comes close to an integrator-like behaviour. In this integrator-limit of operation, the HD gas response becomes proportional to the total flow of reactive gases that had been interacting with the water adsorbate layer on top of the HD sensors.

AB - Hydrogenated diamond (HD) specimens feature a peculiar form of gas response which occurs at room temperature and which is mediated by a thin layer of water that tends to accumulate on HD surfaces as these are exposed to normal atmospheric conditions. HD specimens are known to be sensitive to gases and vapours that are capable of forming acid-base reactions in liquid water. In this paper we show that HD sensors feature a novel kind of accumulating gas response which-under favourable conditions-comes close to an integrator-like behaviour. In this integrator-limit of operation, the HD gas response becomes proportional to the total flow of reactive gases that had been interacting with the water adsorbate layer on top of the HD sensors.

KW - Accumulation

KW - Adsorbed water

KW - Diamond

KW - Electrolytic dissociation

KW - Gas sensor

KW - Integration

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DO - 10.1016/j.snb.2013.02.072

M3 - Article

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SN - 0925-4005

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EP - 903

JO - Sensors and Actuators, B: Chemical

JF - Sensors and Actuators, B: Chemical

ER -

Water adsorbate mediated accumulation gas sensing at hydrogenated diamond surfaces

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Keywords

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