Quantum-inspired terahertz spectroscopy with visible photons

Kutas, Mirco; Haase, Björn; Klier, Jens; Molter, Daniel; Freymann, Georg von

doi:10.1364/optica.415627

Cited by 32 publications

(21 citation statements)

References 30 publications

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“…The clear success of this approach for imaging and microscopy in the mid-IR motivates the question of its limitations -can we envisage this approach to wide field imaging stretching beyond its near and mid-IR, towards the far IR and even terahertz wavelengths [19], where detection technologies are even more limited? Fig.…”

Section: Discussionmentioning

confidence: 99%

“…When the two processes are aligned such that any information distinguishing whether the biphoton was born on the first or second crystal is erased, the two processes interfere. The strength (visibility) and phase of this interference signature serve as the contrast mechanism for imaging -analogously so for similar applications in varied tasks including optical co-herence tomography [12][13][14], spectroscopy [15][16][17][18][19] and polarimetry [20]. In contrast to ghost imaging schemes [21][22][23], in QIUP the detection of only one of the photons of the pair suffices to yield the information imprinted on the other.…”

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confidence: 99%

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Mid-Infrared Microscopy via Position Correlations of Undetected Photons

Kviatkovsky,

Chrzanowski,

Ramelow

2021

Preprint

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Mid-Infrared Microscopy via Position Correlations of Undetected Photons

Kviatkovsky,

Chrzanowski,

Ramelow

2021

Preprint

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“…The transfer of these concepts to the terahertz frequency range is highly attractive, as the detection of terahertz radiation is challenging due to its inherently low photon energy. Even though the quantum-optical sensing and spectroscopy approach has been demonstrated in this spectral range [6,7], its measurement time is not yet competitive. But the use of spontaneous parametric down-conversion and the correlation of the involved photons is not the only possibility to transfer photon properties to the visible range.…”

Section: Introductionmentioning

confidence: 99%

Sample thickness measurements by phase-sensitive terahertz upconversion detection

Pfeiffer¹,

Klier²,

Freymann³

et al. 2022

Preprint

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Nonlinear frequency conversion provides an elegant method to detect photons in a spectral range which differs from the pump wavelength, making it highly attractive for photons with inherently low energy. Aside from the intensity of the light, represented by the number of photons, their phase provides important information and enables a plethora of applications. We present a phase-sensitive measurement method in the terahertz spectral range by only detecting visible light. Using the optical interference of frequency-converted photons and leftover pump photons of the involved ultrashort pulses, fast determination of layer-thicknesses is demonstrated. The new method enables phase-resolved detection of terahertz pulses using standard sCMOS equipment while achieving sample measurement times of less than one second with a precision error of less than 0.6%.

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“…Instead, by exploiting widely non-degenerate correlated photonpairs generated via spontaneous parametric down-conversion, one can realise sensing and detection at vastly separated wavelengths [11]. This technique of sensing with undetected photons has also been applied to other modalities of sensing, including imaging [12,13,14,15], optical coherence tomography [16,17,18], refractometry [19], and even THz-sensing [20,21].…”

Section: Introductionmentioning

confidence: 99%

Mid-IR spectroscopy with NIR grating spectrometers

Kaufmann,

Chrzanowski,

Vanselow

et al. 2021

Preprint

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Mid-infrared (mid-IR) spectroscopy is a crucial workhorse for a plethora of analytical applications and is suitable for diverse materials, including gases, polymers or biological tissue. However, this technologically significant wavelength regime between 2.5-10 µm suffers from technical limitations primarily related to the large noise in mid-IR detectors and the complexity and cost of bright, broadband mid-IR light sources. Here, using highly non-degenerate, broadband photon pairs from bright spontaneous parametric down-conversion (SPDC) in a nonlinear interferometer, we circumvent these limitations and realise spectroscopy in the mid-IR using only a visible (VIS) solid-state laser and an off-the-shelf, commercial near-infrared (NIR) grating spectrometer. With this proof-of-concept implementation, covering a broad range from 3.2 µm to 4.4 µm we demonstrate short integration times down to 1 s and signal-to-noise ratios above 200 at a spectral resolution from 12 cm −1 down to 1.5 cm −1 for longer integration times. Through the analysis of polymer samples and the ambient CO 2 in our laboratory, we highlight the potential of this measurement technique for real-world applications.

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Quantum-inspired terahertz spectroscopy with visible photons

Cited by 32 publications

References 30 publications

Mid-Infrared Microscopy via Position Correlations of Undetected Photons

Mid-Infrared Microscopy via Position Correlations of Undetected Photons

Sample thickness measurements by phase-sensitive terahertz upconversion detection

Mid-IR spectroscopy with NIR grating spectrometers

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