Zero‐standby power hydrogen sensing using event‐driven micromechanical switches

Zero‐standby power hydrogen sensing using event‐driven micromechanical switches

Abstract Zero‐standby power sensors are crucial for enhancing the safety and widespread adoption of hydrogen (H2) technologies in chemical processes and sustainable energy applications, given the flammability of H2 at low concentrations. Here, we report an event‐driven hydrogen sensing system utiliz...

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Bibliographic Details
Main Authors: S M Jahadun Nobi, Eric Herrmann, Zhixiang Huang, Sai Rahul Sitaram, Kyle Laskowski, Xi Wang
Format: Article
Language:English
Published: Wiley 2025-08-01
Series:Responsive Materials
Subjects:
event‐driven detection
hydrogen detection
hydrogen gas sensor
palladium
passive switch
zero standby power
Online Access:https://doi.org/10.1002/rpm2.70018
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Summary:Abstract Zero‐standby power sensors are crucial for enhancing the safety and widespread adoption of hydrogen (H2) technologies in chemical processes and sustainable energy applications, given the flammability of H2 at low concentrations. Here, we report an event‐driven hydrogen sensing system utilizing palladium (Pd)‐based micromechanical cantilever switches. The detection mechanism relies on strain generation in the Pd layer, which undergoes reversible volume expansion upon hydrogen adsorption. Our experimental and simulation results demonstrate that the bistable micromechanical switch‐based sensor generates a wake‐up signal with activation time depending on hydrogen concentration in the target environment while always remaining active for events without any standby power consumption under normal conditions. The H2 adsorption‐induced subsequent switching of the multi‐cantilever‐based switch configuration on the sensor resulted in the quasi‐quantification of hydrogen concentrations. The reported zero‐standby power sensor's operational lifetime is limited by the frequency of detection events and exposure to concentrations exceeding hydrogen's flammability limit. This work advances the development of high‐density, maintenance‐free sensor networks for large‐scale deployment with Internet of Things devices, enabling unattended continuous monitoring of hydrogen generation, transportation, distribution, and end‐user applications.
ISSN:2834-8966

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