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Single Atom-Thin Platinum Could be Used to Develop a Chemical Sensor

Researchers at Chalmers University of Technology, Sweden, together with colleagues from other universities, have discovered the possibility to prepare one-atom thin platinum for use as a chemical sensor. The results were recently published in the scientific journal Advanced Material Interfaces.

"In a nutshell, we managed to make a metal layer just one-atom thick - sort of a new material. We found that this atomically-thin metal is super sensitive to its chemical environment. Its electrical resistance changes significantly when it interacts with gases,", explains Kyung Ho Kim, postdoc at the Quantum Device Physics Laboratory at the Department of Microtechnology and Nanoscience at Chalmers, and lead author of the article.

The essence of the research is the development of 2D materials beyond graphene.

"Atomically thin platinum could be useful for ultra-sensitive and fast electrical detection of chemicals. We have studied the case of platinum in great detail, but other metals like palladium produce similar results", says Samuel Lara Avila, Associate Professor at the Quantum Device Physics Laboratory and one of the authors of the article.

The researchers used the sensitive chemical-to-electrical transduction capability of atomically thin platinum to detect toxic gases at the parts-per-billion level. They demonstrated this with detection of benzene, a compound that is carcinogenic even at very small concentrations, and for which no low-cost detection apparatus exists.

"This new approach, using atomically thin metals, is very promising for future air-quality monitoring applications", says Jens Eriksson, Head of the Applied sensor science unit at Linköping University and a co-author of the paper.

This study was first made available online in April 2020 ahead of final publication in issue on June 23, 2020.

The study was a collaboration between scientists from Chalmers University of Technology, Linköping University, Uppsala University, the University of Zaragoza in Spain, and the MAX IV Laboratory in Lund., Kyung Ho Kim, Hans He and Sergey Kubatkin from Chalmers contributed to the research together with Samuel Lara-Avila.

The work was jointly supported by the Swedish Foundation for Strategic Research (SSF), the Knut and Alice Wallenberg Foundation, The Swedish Research Council and the Chalmers Excellence Initiative for Nano. The experiments were performed in part at the Nanofabrication Laboratory at Chalmers.

Read the article in Advanced Material Interfaces:

Chemical Sensing with Atomically Thin Platinum Templated by a 2D Insulator

https://onlinelibrary.wiley.com/doi/full/10.1002/admi.201902104

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