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KAIST Advances Mid-Infrared Photodetectors for Exoplanet Discovery, Paving the Way for Environmental and Medical Innovations

May 9, 2025
in Chemistry
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In a groundbreaking advancement poised to revolutionize optical sensor technology, researchers at the Korea Advanced Institute of Science and Technology (KAIST) have unveiled a novel mid-infrared photodetector that operates efficiently at room temperature. This innovation, led by Professor SangHyeon Kim of the School of Electrical Engineering, emerges as a key enabler for the commercialization of ultra-compact, low-cost optical sensors, potentially transforming numerous fields including environmental monitoring, medical diagnostics, and industrial automation.

The James Webb Space Telescope (JWST) has shown the profound importance of mid-infrared spectroscopy in detecting molecular fingerprints in extraterrestrial atmospheres, such as water vapor and sulfur dioxide. This line of research has inspired KAIST scientists to explore similarly sensitive photodetectors for terrestrial applications. The team’s design addresses one of the fundamental challenges hindering previous mid-infrared photodetectors: the necessity of complex and bulky cooling systems that mitigate the detrimental effects of thermal noise at room temperature.

Traditional mid-infrared photodetectors usually rely on bandgap absorption mechanisms and require cryogenic cooling to maintain sensitivity. These cooling requirements inevitably increase device size, cost, and energy consumption, all while severely restricting sensor miniaturization and commercialization prospects. Additionally, existing technologies are largely incompatible with silicon-based complementary metal-oxide-semiconductor (CMOS) fabrication processes, further limiting scalability. KAIST’s new device offers a compelling solution by integrating a germanium-based photodetector onto a silicon platform using conventional CMOS processes, paving the way for mass production and widespread adoption.

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The core of this innovation lies in the employment of a germanium-on-insulator (GeOI) optical platform and a waveguide-integrated design. Waveguides serve as conduits for guiding light with minimal loss, allowing precise control of optical signals on chip-scale devices. By integrating the photodetector directly with a waveguide, the sensor achieves enhanced sensitivity across a broad mid-infrared spectrum, while maintaining an ultra-compact footprint—essential characteristics for embedded sensing applications.

Further diverging from conventional devices, the research exploits the bolometric effect as the fundamental detection principle. Unlike bandgap absorption, the bolometric effect measures changes in electrical resistance resulting from temperature increases caused by absorbed infrared radiation. This approach enables the new photodetector to respond to a wide range of mid-infrared wavelengths without being confined by material bandgap limitations, offering unprecedented versatility in detecting diverse gas molecules and chemical species.

The KAIST team demonstrated the practical applicability of their device by successfully performing real-time detection of carbon dioxide (CO₂) gas—an achievement showcasing its significant potential in environmental monitoring and hazardous gas sensing. The sensor’s ultra-thin, ultra-compact design confirms its suitability for integration into portable and smart devices, signaling a shift toward next-generation, on-the-go mid-infrared spectroscopy.

Critically, maintaining stable operation at room temperature without degradation in performance marks a major leap forward. The elimination of cooling systems significantly reduces energy demands and fabrication complexity, heightening the device’s commercial viability. Moreover, compatibility with silicon-based CMOS fabrication processes promises low-cost, large-scale production—an essential factor for widespread deployment in both industrial and consumer markets.

This breakthrough not only pushes the boundaries of sensor miniaturization but also facilitates integration with existing electronics and photonic chips. The seamless fusion of photodetection and optical waveguides on a single chip unlocks numerous possibilities for advanced optical circuits and complex on-chip functionalities, enhancing performance and reducing system complexity.

Performance benchmarks presented by the team indicate this mid-infrared photodetector exhibits the world’s highest sensitivity for devices leveraging the bolometric effect at room temperature. This performance superiority, combined with CMOS compatibility and broad spectral response, distinguishes it as a uniquely powerful solution in the competitive field of infrared photonics.

Looking ahead, the implications of this technology extend into diverse domains including medical diagnostics, where precise molecular detection is paramount; industrial process control, where real-time gas sensing can optimize safety and efficiency; and national defense and security, where compact, sensitive sensors aid in threat detection and situational awareness. Additionally, smart homes and wearable health devices stand to benefit from integration of such compact, low-cost sensors.

The research team’s publication in Light: Science & Applications underscores the scientific rigor and significance of their findings. Dr. Joonsup Shim, the study’s first author and a postdoctoral researcher at Harvard University, highlights the transformative potential of this approach, which overcomes conventional limitations that have long hindered mid-infrared sensing technology.

Professor SangHyeon Kim emphasized, “Our sensor not only answers the critical need for room-temperature operation but also leverages mass-production-friendly CMOS processes. This combination supports the future mass deployment of photodetectors necessary for environmental and industrial applications.” Such statements encapsulate the bridge this research forms between laboratory innovation and real-world utility.

As the global demand for compact, efficient, and cost-effective sensing technologies intensifies, KAIST’s room-temperature mid-infrared waveguide-integrated photodetector represents a breakthrough with broad, lasting impact. This development promises to accelerate the integration of high-performance infrared sensors into everyday technology, heralding a new era of molecular detection capabilities with unprecedented accessibility.


Subject of Research:
Not applicable

Article Title:
Room-temperature waveguide-integrated photodetector using bolometric effect for mid-infrared spectroscopy applications

News Publication Date:
27 March 2025

Web References:
DOI link

References:
Shim, J., Kim, I., Lim, J., & Kim, S. (2025). Room-temperature waveguide-integrated photodetector using bolometric effect for mid-infrared spectroscopy applications. Light: Science & Applications. DOI: 10.1038/s41377-025-01803-3

Image Credits:
KAIST 3D Integrated Opto-Electronic Device Laboratory

Keywords

Mid-infrared photodetector, bolometric effect, germanium-on-insulator, CMOS compatible, room-temperature operation, waveguide-integrated sensor, carbon dioxide detection, optical spectroscopy, environmental monitoring, compact photonics, mass production, infrared sensing

Tags: compact sensor commercializationenvironmental monitoring innovationsexoplanet detection technologiesindustrial automation sensorsJames Webb Space Telescope findingsKAIST research advancementsmedical diagnostics improvementsmid-infrared photodetector technologymolecular fingerprint detectionroom temperature optical sensorssilicon-based photodetector compatibilitythermal noise mitigation solutions
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