Hafnium - an optical hydrogen sensor spanning six orders in pressure

C. Boelsma; L. J. Bannenberg; M. J. Van Setten; N.J. Steinke; A.A. van Well; B. Dam

doi:10.1038/ncomms15718

Hafnium - an optical hydrogen sensor spanning six orders in pressure

C. Boelsma, L. J. Bannenberg, M. J. Van Setten, N.J. Steinke, A.A. van Well, B. Dam^*

^*Corresponding author for this work

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

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Abstract

Hydrogen detection is essential for its implementation as an energy vector. So far, palladium is considered to be the most effective hydrogen sensing material. Here we show that palladium-capped hafnium thin films show a highly reproducible change in optical transmission in response to a hydrogen exposure ranging over six orders of magnitude in pressure. The optical signal is hysteresis-free within this range, which includes a transition between two structural phases. A temperature change results in a uniform shift of the optical signal. This, to our knowledge unique, feature facilitates the sensor calibration and suggests a constant hydrogenation enthalpy. In addition, it suggests an anomalously steep increase of the entropy with the hydrogen/metal ratio that cannot be explained on the basis of a classical solid solution model. The optical behaviour as a function of its hydrogen content makes hafnium well-suited for use as a hydrogen detection material.

Original language	English
Article number	15718
Number of pages	8
Journal	Nature Communications
Volume	8
DOIs	https://doi.org/10.1038/ncomms15718
Publication status	Published - 2017

Keywords

Metals and alloys
Sensors and biosensors
Thermodynamics

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10.1038/ncomms15718

ncomms15718Final published version, 1.51 MBLicence: CC BY-NC-ND

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AU - van Well, A.A.

AU - Dam, B.

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AB - Hydrogen detection is essential for its implementation as an energy vector. So far, palladium is considered to be the most effective hydrogen sensing material. Here we show that palladium-capped hafnium thin films show a highly reproducible change in optical transmission in response to a hydrogen exposure ranging over six orders of magnitude in pressure. The optical signal is hysteresis-free within this range, which includes a transition between two structural phases. A temperature change results in a uniform shift of the optical signal. This, to our knowledge unique, feature facilitates the sensor calibration and suggests a constant hydrogenation enthalpy. In addition, it suggests an anomalously steep increase of the entropy with the hydrogen/metal ratio that cannot be explained on the basis of a classical solid solution model. The optical behaviour as a function of its hydrogen content makes hafnium well-suited for use as a hydrogen detection material.

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Hafnium - an optical hydrogen sensor spanning six orders in pressure

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