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Real-world applications of Moorfield products in science

Single-molecule mid-infrared spectroscopy and detection

Publication Title: Single-molecule mid-infrared spectroscopy and detection through vibrationally assisted luminescence.
Paper Abstract

Room-temperature detection of molecular vibrations in the mid-infrared (MIR, λ = 3–30 µm) has numerous applications, including real-time gas sensing, medical imaging and quantum communication. However, existing technologies rely on cooled semiconductor detectors because of thermal noise limitations. One way to overcome this challenge is to upconvert the low-energy MIR photons into high-energy visible wavelengths (λ = 500–800 nm) where detection of single photons is easily achieved using silicon technologies. This process suffers from weak cross-sections and the MIR-to-visible wavelength mismatch, limiting its efficiency. Here we exploit molecular emitters possessing both MIR and visible transitions from molecular vibrations and electronic states, coupled through Franck–Condon factors. By assembling molecules into a plasmonic nanocavity resonant at both MIR and visible wavelengths, and optically pumping them below the electronic absorption band, we show transduction of MIR light. The upconverted signal is observed as enhanced visible luminescence. Combining Purcell-enhanced visible luminescence with enhanced rates of vibrational pumping gives transduction efficiencies of >10%. MIR frequency-dependent upconversion gives the vibrational signatures of molecules assembled in the nanocavity. Transient picocavity formation further confines MIR light down to the single-molecule level. This allows us to demonstrate single-molecule MIR detection and spectroscopy that is inaccessible to any previous detector.

How Moorfield products helped:

To prepare the thin mirror a benchtop nanoPVD-T15A PVD thin film deposition system  was used to deposit 10 nm of Au onto clean Si membranes of 200-µm thickness with a deposition rate of 0.5 Å s−1 using thermal evaporation.

Open Access publication details:

Chikkaraddy, R. et al. (2023) ‘Single-molecule mid-infrared spectroscopy and detection through vibrationally assisted luminescence’, Nature Photonics, 17(10), pp. 865–871. Available at: https://doi.org/10.1038/s41566-023-01263-4.