Abstract
Hydrogen gas is rapidly approaching a global breakthrough as a carbon-free energy vector. In such a hydrogen economy, safety sensors for hydrogen leak detection will be an indispensable element along the entire value chain, from the site of hydrogen production to the point of consumption, due to the high flammability of hydrogen–air mixtures. To stimulate and guide the development of such sensors, industrial and governmental stakeholders have defined sets of strict performance targets, which are yet to be entirely fulfilled. In this Perspective, we summarize recent efforts and discuss research strategies for the development of hydrogen sensors that aim at meeting the set performance goals. In the first part, we describe the state-of-the-art for fast and selective hydrogen sensors at the research level, and we identify nanostructured Pd transducer materials as the common denominator in the best performing solutions. As a consequence, in the second part, we introduce the fundamentals of the Pd–hydrogen interaction to lay the foundation for a detailed discussion of key strategies and Pd-based material design rules necessary for the development of next generation high-performance nanostructured Pd-based hydrogen sensors that are on par with even the most stringent and challenging performance targets.
Highlights
Hydrogen gas is rapidly approaching a global breakthrough as a carbon-free energy vector
This event was a dramatic reminder of the high flammability of H2− air mixtures at H2 concentrations above 4%, and made the importance of robust and fast hydrogen safety sensors for leak detection highly apparent
Here we mean sensors that have been developed with the aim and/or potential to meet the US Department of Energy (DoE) hydrogen sensor performance targets
Summary
Excellent selectivity Excellent selectivity to NO2, cross sensitive to C2H5OH, fairly cross-sensitive to the rest Excellent selectivity Fairly cross-sensitive to C2H5OH, excellent selectivity to the rest Excellent selectivity Excellent selectivity Excellent selectivity. S Fairly cross-sensitive to C4H8O2, cross-sensitive to CH2O, excellent selectivity to the rest. H Excellent resistance S Excellent selectivity S Fairly cross-sensitive to NO2, excellent selectivity to the rest H Decreased response amplitude S Cross-sensitive. Cross-sensitive Fairly cross-sensitive to C2H5OH, excellent selectivity to the rest Cross-sensitive S Excellent selectivity H Decreased response amplitude, decelerated response time S Fairly cross-sensitive H Maintained response amplitude S Cross-sensitive to NH3, fairly cross-sensitive to the rest S Excellent selectivity S Excellent selectivity S Fairly cross-sensitive Cross-sensitive S Excellent selectivity H Decreased response amplitude. S Cross-sensitive P Decreased response amplitude S Fairly cross-sensitive S Cross-sensitive S Fairly cross-sensitive H Maintained response amplitude, decelerated response time S Fairly cross-sensitive to C2H5OH and CO, excellent selectivity to the rest H Increased response amplitude S Excellent selectivity H Excellent resistance S Excellent selectivity to CH4 and C3H6O, fairly crosssensitive to the rest S Excellent selectivity H Decreased response amplitude, decelerated response time beyond 46% RH S Fairly cross-sensitive NH3, excellent selectivity to the rest
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