https://doi.org/10.1140/epjp/s13360-024-05499-z
Regular Article
Recent improvements in the novel approach to the fast detection of surface contaminations
1
Chemical Detection, Bundeswehr Research Institute for Protective Technologies and CBRN Protection WIS, Humboldtstraße 100, 29633, Munster, Lower-Saxony, Germany
2
Department of Optoelectronics, Fraunhofer Institute for Applied Solid State Physics IAF, Tullastraße 72, 79108, Freiburg, Baden-Wurttemberg, Germany
a
FrankWilsenack@bundeswehr.org
Received:
10
March
2024
Accepted:
25
July
2024
Published online:
21
August
2024
Here, we present the idea behind a novel measurement system and the recent improvements in detecting surface contaminations using a tunable, very fast three-core quantum cascade laser (QCL) system. It is developed as a potential replacement for the old established double-wheel sampling system currently used to detect surface threats caused by hazardous, non-volatile chemical substances. The novel system design is based on an optical measurement principle, allowing standoff detection and identification, thus rendering ground contact unnecessary. One of the leading military requirements for a CBRN reconnaissance vehicle is a high marching speed; hence, this new system is designed to have an ultra-short acquisition time and an adequate spectral bandwidth for measurements in the mid-infrared (MIR). This innovative approach may replace the more cumbersome indirect detection techniques. We discuss the main advantages and evaluate possible application scenarios that we expect from this setup. Active IR backscatter spectroscopy generally permits the contactless identification of hazardous chemical substances on surfaces. Here, the design was optimized around an approximate measuring distance of decimeters. Using a monoaxial setup, the autofocus is less demanding than alternative approaches and even allows for rapid measurements of rough surfaces. We built the improved measurement system based on novel QCL modules that integrate micro-opto-electro-mechanical grating scanners (MOEMS) in an external cavity. These elaborate laser modules provide almost one kilohertz (kHz) spectral scan speeds and typically cover a spectral range of 200–300 cm-1, respectively. Furthermore, such modules achieve measurement times of as short as one millisecond per spectrum. The full spectral coverage of the system is realized by coupling several of such modules.
Fabian Meyer, Yuri V. Flores and Marko Haertelt have contributed equally to this work.
© The Author(s) 2024
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