Research Background
Conventional metal oxide gas sensors are widely used in environmental monitoring, industrial Internet of Things, and aerospace applications. However, their performance is fundamentally constrained by single-type active sites and static electronic configurations. When exposed to an ultrabroad temperature range, these sensors typically suffer from sluggish reaction kinetics, surface passivation, sintering, phase transitions, and competitive adsorption, leading to poor long-term stability. Therefore, developing a sensor that maintains high sensitivity, fast response, and exceptional stability under extreme temperature conditions remains a significant challenge in materials science.

Key Findings
A research team from the National University of Defense Technology successfully constructed a dual local electric field (LEF) system with a graded electron concentration profile by anchoring platinum Pt_SA onto ordered vacancy clusters on the surface of CeO₂. This design introduces a thermally activated electric-field switching mechanism, enabling rapid response (within 12 seconds) and long-term stability (over 75 days) for NO₂​detection across an ultrabroad temperature range from -50 to 800^oC. This work provides a new paradigm for the design of intelligent sensors for extreme environments.

Technical Mechanism
Two distinct local electric fields, LEF-1 and LEF-2, are formed in the material. At low temperatures, the hybridization between Pt and Ce orbitals results in a lower thermal activation energy for LEF-1, allowing it to dominate the sensing reaction. As the temperature increases, electrons migrate from the 4f orbitals of Ce³⁺ to adjacent Ce⁴⁺
sites, weakening LEF-1. Meanwhile, thermal activation promotes efficient electron transfer in LEF-2, enabling it to dominate at high temperatures. This relay mechanism ensures sustained and stable sensing activity across the entire temperature range. The formation and temperature-dependent behavior of the dual local electric fields were systematically validated through aberration-corrected transmission electron microscopy, X-ray absorption spectroscopy, transient absorption spectroscopy, and theoretical calculations.

Future Prospects
This study demonstrates the great potential of adaptive sensing mechanisms enabled by atomic-scale defect engineering and local electric field modulation under extreme temperature conditions. This strategy opens new avenues for the development of intelligent sensors for applications in aerospace, nuclear facilities, deep-sea exploration, and high-temperature industrial processes. In the future, further optimization of material structures and field-regulation mechanisms may enable smart sensing systems with even wider operating temperature ranges, higher selectivity, and enhanced long-term durability, meeting the demands of complex and harsh environments.

The complete study is accessible via DOI:10.34133/research.1138