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  • Scientific Research
Time-resolved mid-infrared photoluminescence spectroscopy of an undoped InAs substrate using NLIR spectrometer as featured in Applied Physics Letters

Time-resolved mid-infrared photoluminescence spectroscopy of an undoped InAs substrate

Hisashi Sumikura et al., Applied Physics Letter 124, 052105 (2024).
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  • Scientific Research
Online Characterization of Mixed Plastic Waste Using Machine Learning and MIR Spectroscopy sing-NLIR-technology-as-in-ACS Sustainable Chemistry

Online characterization of mixed plastic waste using machine learning and mid-infrared spectroscopy

Fei Long et al., ACS Sustainable Chemistry & Engineering 10, pp. 16064-16069 (2022).
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  • Scientific Research
Accurate Characterization of Mixed Plastic Waste Using Machine Learning and Fast Infrared Spectroscopy using NLIR technology as in ASC Sustainable Chemistry & Engineering, 2021

Accurate characterization of mixed plastic waste using machine learning and fast infrared spectroscopy

Stas Zinchik et al., ACS Sustainable Chemistry & Engineering 9, pp. 14143-14151 (2021).
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  • Scientific Research
High-resolution mid-infrared optical coherence tomography with kHz line rate using NLIR technology as in Optics Letters, 2021

High-resolution mid-infrared optical coherence tomography with kHz line rate

Niels M. Israelsen et al., Optics Letters 46, pp. 4558-4561 (2021).
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  • Scientific Research
Toward Fully‐Fledged Quantum and Classical Communication Over Deployed Fiber with Up‐Conversion Module using NLIR technology as in Advanced Quantum Technology, 2021

Toward fully‐fledged quantum and classical communication over deployed fiber with up‐conversion module

Davide Bacco et al., Advanced Quantum Technologies 4, 2000156 (2021).
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  • Scientific Research
Room-Temperature, High-SNR Upconversion Spectrometer in the 6–12 µm Region using Nlir technology as in Laser & Photonics Review, 2021 - Copy

Room‐temperature, high‐SNR upconversion spectrometer in the 6–12 µm region

Peter John Rodrigo et al., Laser & Photonics Reviews 15, 2000443 (2021).
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  • Scientific Research
Real-time high-resolution mid-infrared optical coherence tomography using Nlir technology as in Light Science and Application, 2019

Real-time high-resolution mid-infrared optical coherence tomography

Niels M. Israelsen et al., Light: Science & Applications 8, Article number: 11 (2019).
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  • Scientific Research
Mid-infrared supercontinuum-based upconversion detection for trace gas sensing using Nlir Technlogy as in Optics Express, 2021

Mid-infrared supercontinuum-based upconversion detection for trace gas sensing

Khalil E. Jahromi et al., Optics Express 27, pp. 24469 – 24480 (2019).
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  • Scientific Research
Upconversion-based mid-infrared spectrometer using intra-cavity LiNbO3 crystals with chirped poling structure using Nlir technology as in Optics Letters, 2019

Upconversion-based mid-infrared spectrometer using intra-cavity LiNbO3 crystals with chirped poling structure

Søren M. M. Friis et al., Optics Letters 44, pp. 4231 – 4234 (2019).
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  • Scientific Research
Characterization of the NEP of Mid-Infrared Upconversion Detectors using NLIR technology as in IEEE Photonics Technology Letters, 2019

Characterization of the NEP of mid-infrared upconversion detectors

Rasmus. L. Pedersen et al., IEEE Photonics Technology Letters 31, pp. 681 – 684 (2019).
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  • Scientific Research
Spatially and temporally resolved IR-DFWM measurement of HCN released from gasification of biomass pellets using NLIR technology as featured in Proceedings of the Combustion Institute, 2019

Spatially and temporally resolved IR-DFWM measurement of HCN released from gasification of biomass pellets

Dina Hot et al., Proceedings of the Combustion Institute 37, pp. 1337 – 1344 (2019).
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  • Scientific Research
Enhancing the detectivity of an upconversion single-photon detector by spatial filtering of upconverted parametric fluorescence using NLIR technology as in Optics Express, 2018

Upconversion detector for range-resolved DIAL measurement of atmospheric CH4

Lichun Meng et al., Optics Express 26, pp. 3850 – 3860 (2018).
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  • Scientific Research
Enhancing the detectivity of an upconversion single-photon detector by spatial filtering of upconverted parametric fluorescence using NLIR technology as in Optics Express, 2018

Enhancing the detectivity of an upconversion single-photon detector by spatial filtering of upconverted parametric fluorescence

Lichun Meng et al., Optics Express 26, pp. 24712 – 24722 (2018).
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  • Scientific Research
Comparison of an InSb Detector and Upconversion Detector for Infrared Polarization Spectroscopy using NLIR technology as in Applied Spectroscopy, 2018

Comparison of an InSb detector and upconversion detector for infrared polarization spectroscopy

Rasmus L. Pedersen et al., Applied Spectroscopy 72, pp. 793 – 797 (2018).
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  • Scientific Research
Mid-infrared coincidence measurements on twin photons at room temperature using NLIR technology as in Nature-Communications 2017

Mid-infrared coincidence measurements on twin photons at room temperature

M. Mancinelli et al., Nature Communications 8, Article number: 15184 (2017).
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  • Scientific Research
GHz-bandwidth upconversion detector using a unidirectional ring cavity to reduce multilongitudinal mode pump effects using NLIR technology as in Optics Express, 2017

GHz-bandwidth upconversion detector using a unidirectional ring cavity to reduce multilongitudinal mode pump effects

Lichun Meng et al., Optics Express 25, pp. 14783 – 14794 (2017).
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  • Scientific Research
Ultra-broadband mid-wave-IR upconversion detection using NLIR technology as in Optics Letters, 2017

Ultra-broadband mid-wave-IR upconversion detection

Ajanta Barh et al., Optics Letters 42, pp. 1504 – 1507 (2017).
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  • Scientific Research
Mid-infrared upconversion spectroscopy using NLIR technology as in Journal of the Optical Society of America, 2016

Mid-infrared upconversion spectroscopy

Peter Tidemand-Lichtenberg et al., Journal of the Optical Society of America B 33, pp. D28 – D35 (2016).
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  • Scientific Research
Upconversion-based lidar measurements of atmospheric CO2 using NLIR technology as in Optics Express, 2016

Upconversion-based lidar measurements of atmospheric CO2

Lasse Høgstedt et al., Optics Express 24, pp. 5152 – 5162 (2016).
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  • Scientific Research
Infrared upconversion hyperspectral imaging using NLIR technology as in Optics Letters, 2015

Infrared upconversion hyperspectral imaging

Louis M. Kehlet et al., Optics Letters 40, pp. 938 – 941 (2015).
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