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Home NEWS Science News Technology

Broadband Photon-Counting Dual-Comb Spectroscopy Achieves Attowatt Sensitivity

Bioengineer by Bioengineer
August 27, 2025
in Technology
Reading Time: 4 mins read
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In a groundbreaking advancement poised to redefine the boundaries of optical spectroscopy, researchers have unveiled a pioneering broadband photon-counting dual-comb spectrometer exhibiting attowatt-level sensitivity, capable of operating reliably over turbulent atmospheric paths. This technological feat, detailed in a recent publication, promises transformative applications ranging from atmospheric sensing and environmental monitoring to secure communications and precision metrology.

The new system leverages the power of dual-comb spectroscopy, an emerging technique that uses two coherent frequency combs to extract high-resolution spectral information with remarkable speed and accuracy. Unlike traditional spectrometers that scan wavelengths sequentially, dual-comb spectroscopy enables simultaneous acquisition across a broad spectral bandwidth by interfering two closely spaced frequency combs whose repetition rates differ slightly. This approach has revolutionized spectroscopic measurements, allowing for rapid and precise analysis of molecular absorption and emission features.

What sets this particular development apart is the unprecedented sensitivity achieved—reaching the attowatt level, which corresponds to single-photon detection extremes that dramatically surpass existing sensors. Attowatts are a scale of power a thousand times weaker than previously detectable limits in many dual-comb configurations. The ability to detect signals at this minuscule power scale while maintaining broad spectral coverage represents a seminal advancement with deep implications.

Key to this innovation is the integration of photon-counting detectors, which operate fundamentally differently from conventional photodiodes by directly counting individual photons rather than measuring aggregate photonic currents. Through careful synchronization and noise reduction protocols, the research team employed advanced single-photon detectors that permit extraction of the comb interference signal even under conditions of atmospheric turbulence, where beam distortions typically degrade measurement quality.

Turbulence, a persistent obstacle in open-air optical systems, causes random fluctuations in the refractive index along the propagation path, leading to beam wander, scintillation, and phase noise. Overcoming this instability, especially for ultra-sensitive detection, demanded novel approaches. The team designed sophisticated adaptive compensation algorithms and employed robust optical architectures that preserve coherence between the dual combs despite disturbances encountered in free-space channels extending over tens or hundreds of meters.

The broadband nature of the spectrometer is another remarkable feature, enabling simultaneous probing across a wide spectral region that encompasses molecular fingerprints of various gases and materials. This capability is essential for applications such as atmospheric chemistry, where multiple trace gases need to be identified and quantified accurately and rapidly. Previously, such spectral breadth accompanied by high sensitivity was unachievable in field-deployable systems.

Experimentally, the setup demonstrated detection of weak absorption features from trace gases under simulated environmental turbulence, maintaining signal integrity even when power levels plunged to attowatt scales. The verification included rigorous comparison against reference spectra, confirming fidelity and reproducibility. The data clearly show that photon-counting dual-comb spectroscopy can transcend laboratory conditions and venture into practical, real-world scenarios demanding resilient and ultra-sensitive optical instrumentation.

Another critical advancement lies in the coherence management between the two combs, which typically drift over time due to environmental fluctuations. By implementing active feedback loops and electronic stabilization methods tailored for photon-counting regimes, the researchers achieved long-term stability, enabling continuous monitoring over extended periods without significant degradation in spectral quality.

The implications of this research are multifaceted. Environmental monitoring can benefit from portable, highly sensitive sensors capable of detecting trace pollutants or greenhouse gases from a safe distance without intrusive sampling. In security and defense, such systems could enable covert detection of chemical agents dispersed in the atmosphere. Additionally, telecommunications could leverage these findings to enhance quantum communication protocols by stabilizing photon-counting links over turbulent channels.

Moreover, the system’s broadband capability allows simultaneous interrogation of multiple species or materials, which traditional spectrometers often cannot achieve without complex and time-consuming scanning. This attribute enhances throughput and opens new avenues for multiplexed sensing in biomedicine, where precise chemical fingerprinting is critical for diagnostics.

From the metrological perspective, this development pushes the envelope of precision measurement, allowing unprecedented characterization of light-matter interactions at the photon level in non-ideal environments. The capability to detect subtle spectral nuances under turbulence could advance fundamental research in photonics and atmospheric physics alike.

The research team underscores that while the current setup marks significant progress, ongoing optimization and miniaturization efforts aim to make the technology more compact, low-power, and user-friendly. Integration with fiber optics and deployment in unmanned aerial vehicles or satellites are envisioned next steps, further expanding the horizons of remote sensing instruments.

Technological hurdles remain, particularly concerning background noise suppression and detector dead time, but the promising results herald a new era where dual-comb spectroscopy transcends laboratory confines. The convergence of photon counting with dual-comb techniques represents a paradigm shift, harmonizing sensitivity, speed, and robustness over challenging optical paths.

Finally, this breakthrough exemplifies the ingenious merger of quantum detection principles with classical optical comb technology, pushing photonics into regimes once deemed unattainable. The researchers’ work lays a sturdy foundational platform to inspire a wealth of future studies and technological innovations in precision spectroscopy under realistic environmental conditions.

As science marches forward, the fusion of attowatt-level photon counting within broadband dual-comb spectroscopy will undoubtedly galvanize new applications, empowering humanity with sharper, faster, and more sensitive tools to decode the spectral whispers of the world around us.

Subject of Research: Broadband photon-counting dual-comb spectroscopy with attowatt sensitivity over turbulent optical paths

Article Title: Broadband photon-counting dual-comb spectroscopy with attowatt sensitivity over turbulent optical paths

Article References:
Zhong, W., Liu, Y., Yin, Q. et al. Broadband photon-counting dual-comb spectroscopy with attowatt sensitivity over turbulent optical paths. Light Sci Appl 14, 293 (2025). https://doi.org/10.1038/s41377-025-01934-7

Image Credits: AI Generated

DOI: https://doi.org/10.1038/s41377-025-01934-7

Tags: atmospheric sensing technologyattowatt sensitivity optical spectroscopybroadband photon-counting dual-comb spectroscopydual-comb spectroscopy innovationsenvironmental monitoring advancementshigh-resolution spectral information extractionmolecular absorption and emission analysisprecision metrology techniquessecure communications applicationssimultaneous spectral acquisition methodssingle-photon detection technologiestransformative optical measurement systems

Tags: attowatt sensitivitybroadband optical spectroscopyenvironmental monitoring technologyphoton-counting dual-comb spectroscopyturbulent atmospheric sensing
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