Supraparticles for Bare-Eye H2 Indication and Monitoring: Design, Working Principle, and Molecular Mobility

Reichstein J, Schötz S, Macht M, Maisel S, Stockinger N, Cuadrado Collados C, Schubert K, Blaumeiser D, Wintzheimer S, Görling A, Thommes M, Zahn D, Libuda J, Bauer T, Mandel K (2022)

Publication Type: Journal article, Online publication

Publication year: 2022

Journal

Advanced Functional Materials Wiley-VCH Verlag

Book Volume: 32

Article Number: 2112379

Journal Issue: 22

URI: https://onlinelibrary.wiley.com/doi/10.1002/adfm.202112379

DOI: 10.1002/adfm.202112379

Open Access Link: https://onlinelibrary.wiley.com/doi/10.1002/adfm.202112379

Abstract

Indicators for H2 are crucial to ensure safety standards in a green hydrogen economy. Herein, the authors report micron-scaled indicator supraparticles for real-time monitoring and irreversible recording of H2 gas via a rapid eye-readable two-step color change. They are produced via spray-drying SiO2 nanoparticles, AuPd nanoparticles, and indicator-dye resazurin. The resulting gas-accessible mesoporous supraparticle framework absorbs water from humid atmospheres to create a three-phase-system. In the presence of H2, the color of the supraparticle switches first irreversibly from purple to pink and further reversibly to a colorless state. In situ infrared spectroscopy measurements indicate that this color change originates from the (ir)reversible H2-induced reduction of resazurin to resorufin and hydroresorufin. Further infrared spectroscopic measurements and molecular dynamics simulations elucidate that key to achieve this functionality is an established three-phase-system within the supraparticles, granting molecular mobility of resazurin. Water acts as transport medium to carry resazurin molecules towards the catalytically active AuPd nanoparticles. The advantages of the supraparticles are their small dimensions, affordable and scalable production, fast response times, straightforward bare-eye detection, and the possibility of simultaneously monitoring H2 exposure in real-time and ex post. Therefore, H2 indicator supraparticles are an attractive safety additive for leakage detection and localization in a H2 economy.

Authors with CRIS profile

Jakob Reichstein Professur für Anorganische Chemie Simon Schötz Lehrstuhl für Katalytische Grenzflächenforschung Moritz Macht Professur für Theoretische Chemie Sven Maisel Collaborative Research Centre 1452/1 Catalysis at Liquid Interfaces (CLINT) Carlos Cuadrado Collados Sonderforschungsbereich 1411 Produktgestaltung disperser Systeme / Design of Particulate Products Dominik Blaumeiser Lehrstuhl für Katalytische Grenzflächenforschung Susanne Wintzheimer Professur für Anorganische Chemie Andreas Görling Lehrstuhl für Theoretische Chemie Matthias Thommes Lehrstuhl für Thermische Verfahrenstechnik Dirk Zahn Professur für Theoretische Chemie Jörg Libuda Lehrstuhl für Katalytische Grenzflächenforschung Tanja Retzer Lehrstuhl für Katalytische Grenzflächenforschung Karl Mandel Professur für Anorganische Chemie

How to cite

APA:

Reichstein, J., Schötz, S., Macht, M., Maisel, S., Stockinger, N., Cuadrado Collados, C.,... Mandel, K. (2022). Supraparticles for Bare-Eye H2 Indication and Monitoring: Design, Working Principle, and Molecular Mobility. Advanced Functional Materials, 32(22). https://doi.org/10.1002/adfm.202112379

MLA:

Reichstein, Jakob, et al. "Supraparticles for Bare-Eye H2 Indication and Monitoring: Design, Working Principle, and Molecular Mobility." Advanced Functional Materials 32.22 (2022).

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