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1. Mean-field equation for phase-modulated optical parametric oscillator

Author

Sanchez, A. D., Kumar, S. Chaitanya, and Ebrahim-Zadeh, M.

Subjects
Physics - Optics
Abstract

The widely established techniques for the generation of ultrashort optical pulses rely on passive mode-locking of lasers, with the output pulse duration and emission spectrum determined by the intrinsic lifetime of laser transition in the gain medium. Due to the instantaneous nature of nonlinear gain, optical parametric oscillators (OPOs) are capable of generating optical radiation in all time scales from continuous-wave (cw) to ultrashort femtosecond regime, if driven by laser pump sources in the corresponding time domain. In the ultrashort time scale, operation of OPOs conventionally relies on mode-locked pump lasers, with the concomitant disadvantages of large footprint and high cost. At the same time, the lack of gain storage mandates the use of synchronous pumping, resulting in increased complexity. In this paper, we present the concept of phase-modulated OPO driven by cw pump laser. The approach overcomes the traditional drawbacks of ultrafast OPOs, enabling femtosecond pulse generation without the need for synchronous pumping, resulting in a simplified, compact and cost-effective architecture using cw input pump lasers. We derive a mean-field equation for a degenerate $\chi^{(2)}$ OPO driven by a cw laser with intracavity electro-optic modulator (EOM), and also including dispersion compensation. The new equation predicts the formation of stable femtosecond pulses ($<$200~fs), in both normal and anomalous dispersion regimes, with a controllable repetition rate determined by the frequency of the EOM. The remarkable functionality of the proposed scheme paves the way for the development of a new class of widely tunable coherent femtosecond light sources in both bulk and integrated format based on $\chi^{(2)}$ OPOs using cw pump lasers.

Published
2024
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2. Quadratic frequency comb based on phase-modulated cw-driven optical parametric oscillator with intracavity dispersion control

Author

Sanchez, A. D., Kumar, S. Chaitanya, and Ebrahim-Zadeh, M.

Subjects
Physics - Optics
Abstract

We report a novel configuration of bulk $\chi^{(2)}$ optical parametric oscillator (OPO) capable of delivering coherent broadband phase-locked spectrum when driven by a continuous-wave (cw) pump laser. By deploying an electro-optic modulator (EOM) internal to a degenerate cw OPO based on MgO:sPPLT or MgO:PPLN and implementing intracavity dispersion control, we show that output spectra extending over 9 nm (119 nm) with well-defined phase coherence can be generated. Pumping the cw OPO at 532~nm (1550~nm) for degenerate operation in the normal (anomalous) dispersion regime at 1064~nm (3100~nm), and using the coupled-wave equations to simulate the OPO in the presence of intracavity dispersion compensation, we demonstrate that this device offers a new alternative for $\chi^{(2)}$-based frequency comb generation. We also show that in the time domain the output of such a device corresponds to femtosecond quadratic solitons in both dispersion regimes. The described concept is generic, paving the way for the realization of a new class of coherent broadband frequency comb sources in different spectral regions based on $\chi^{(2)}$ OPOs pumped by cw lasers.

Published
2024

3. CUDA-based focused Gaussian beams second-harmonic generation efficiency calculator

Author

Sanchez, A. D., Kumar, S. Chaitanya, and Ebrahim-Zadeh, M.

Subjects
Physics - Optics
Abstract

We present an object-oriented programming (OOP) CUDA-based package for fast and accurate simulation of second-harmonic generation (SHG) efficiency using focused Gaussian beams. The model includes linear as well as two-photon absorption that can ultimately lead to thermal lensing due to self-heating effects. Our approach speeds up calculations by nearly 40x (11x) without (with) temperature profiles with respect to an equivalent implementation using CPU. The package offers a valuable tool for experimental design and study of 3D field propagation in nonlinear three-wave interactions. It is useful for optimization of SHG-based experiments and mitigates undesired thermal effects, enabling improved oven designs and advanced device architectures, leading to stable, efficient high-power SHG.

Published
2024
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4. Talbot effect-based sensor measuring grating period change in subwavelength range

Author

Sarkar, Saumya J., Ebrahim-Zadeh, M., and Samanta, G. K.

Subjects
Physics - Optics
Abstract

Talbot length, the distance between two consecutive self-image planes along the propagation axis for a periodic diffraction object (grating) illuminated by a plane wave, depends on the period of the object and the wavelength of illumination. This property makes the Talbot effect a straightforward technique for measuring the period of a periodic object (grating) by accurately determining the Talbot length for a given illumination wavelength. However, since the Talbot length scale is proportional to the square of the grating period, traditional Talbot techniques face challenges when dealing with smaller grating periods and minor changes in the grating period. Recently, we demonstrated a Fourier transform technique-based Talbot imaging method that allows for controlled Talbot lengths of a periodic object with a constant period and illumination wavelength. Using this method, we successfully measured periods as small as a few micrometers and detected sub-micrometer changes in the periodic object. Furthermore, by measuring the Talbot length of gratings with varying periods imaged through the combination of a thick lens of short focal length and a thin lens of long focal length and large aperture, we determined the effective focal length of the thick lens in close agreement with the theoretical effective focal length of a thick lens in the presence of spherical aberration. These findings establish the Talbot effect as an effective and simple technique for various sensing applications in optics and photonics through the measurement of any physical parameter influencing the Talbot length of a periodic object.

Published
2024

6. Imaging inspired characterization of single photons carrying orbital angular momentum

Author

Kumar, Vimlesh, Sharma, Varun, Singh, Sandeep, Kumar, S. Chaitanya, Forbes, Andrew, Ebrahim-Zadeh, M., and Samanta, G. K.

Subjects
Quantum Physics, Physics - Optics
Abstract

We report on an imaging-inspired measurement of orbital angular momentum (OAM) using only a simple tilted lens and an Intensified Charged Coupled Device (ICCD) camera, allowing us to monitor the propagation of OAM structured photons over distance, crucial for free-space quantum communication networks. We demonstrate measurement of OAM orders as high as 14 in a heralded single-photon source (HSPS) and show, for the first time, the imaged self-interference of photons carrying OAM in a modified Mach-Zehnder Interferometer (MZI). The described methods reveal both the charge and order of a photons OAM, and provide a proof of concept for the interference of a single OAM photon with itself. Using these tools, we are able to study the propagation characteristics of OAM photons over distance, important for estimating transport in free-space quantum links. By translating these classical tools into the quantum domain, we offer a robust and direct approach for the complete characterization of a twisted single-photon source, an important building block of a quantum network.

Published
2021
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8. SHG (532 nm)-induced spontaneous parametric downconversion noise in 1064 nm-pumped IR upconversion detectors

Author

Meng, L., Padhye, A., Pedersen, C., Ebrahim-Zadeh, M., and Rodrigo, P. J.

Subjects
Physics - Optics
Abstract

As a novel technique for infrared detection, frequency upconversion has been successfully deployed in many applications. However, investigations into the noise properties of upconversion detectors (UCDs) have also received considerable attention. In this letter, we present a new noise source - second harmonic generation (SHG)-induced spontaneous parametric downconversion (SPDC) - experimentally and theoretically shown to exist in short-wavelength-pumped UCDs. We investigate the noise properties of two UCDs based on single-pass 1064 nm-pumped periodically poled LiNbO$_{3}$ bulk crystals. One UCD is designed to detect signals in the telecom band and the other in the mid-infrared regime. Our experimental demonstration and theoretical analysis reveal the basic properties of this newly discovered UCD noise source, including its dependence on crystal temperature and pump power. Furthermore, the principle behind the generation of this noise source can also be applied to other UCDs, which utilize nonlinear crystals either in waveguide form or with different bulk materials. This study may also aid in developing methods to suppress the newly identified noise in future UCD designs., Comment: 5 pages, 5 figures, journal paper

Published
2019
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11. Fiber-laser-pumped Ti:sapphire laser

Author

Samanta, G. K., Kumar, S. Chaitanya, Devi, Kavita, and Ebrahim-Zadeh, M.

Subjects
Physics - Optics
Abstract

We report the first experimental demonstration of efficient and high-power operation of a Ti:sapphire laser pumped by a simple, compact, continuous-wave (cw) fiber-laser-based green source. The pump radiation is obtained by direct single-pass second-harmonic-generation (SHG) of a 33-W, cw Yb-fiber laser in 30-mm-long MgO:sPPLT crystal, providing 11 W of single-frequency green power at 532 nm in TEM00 spatial profile with power and frequency stability better than 3.3% and 32 MHz, respectively, over one hour. The Ti:sapphire laser is continuously tunable across 743-970 nm and can deliver an output power up to 2.7 W with a slope efficiency as high as 32.8% under optimum output coupling of 20%. The laser output has a TEM00 spatial profile with M2<1.44 across the tuning range and exhibits a peak-to-peak power fluctuation below 5.1% over 1 hour.

Published
2010

13. Dynamically tunable broadband output coupling of optical oscillators based on non-cyclic geometric phase mirror.

Author

Kaushik, Chahat, Aadhi, A., Ghosh, Anirban, Singh, R. P., Gupta, S. Dutta, Ebrahim-Zadeh, M., and Samanta, G. K.

Subjects
OPTICAL parametric oscillators, LIGHT sources, GEOMETRIC quantum phases, OPTICAL control, MIRRORS
Abstract

We present a uniquely versatile and efficient mirror system capable of real-time fine-tuning in reflection and transmission properties across a broad wavelength range and at a high optical power. Leveraging the principles of the non-cyclic geometric phase (GP) acquired by the clockwise and counterclockwise beams of the Sagnac interferometer satisfying the anti-resonant condition on propagation through the quarter-wave plate, half-wave plate, and quarter-wave plate combination having fast axes oriented at 45° (fixed), θ (variable), and −45° (fixed) with respect to the vertical, respectively, our mirror system offers dynamic transmission control across 0–100% without the need for realignment. Notably, the GP-based mirror (GP-mirror) preserves the polarization state of the reflected beam, making it ideal for polarization-sensitive applications. The wavelength insensitivity of the GP enables seamless operation of the mirror across a wide wavelength range. As a proof-of-principle, we use the GP-mirror as the output coupler of a continuous-wave, green-pumped, doubly resonant optical parametric oscillator (DRO) based on a 30-mm-long MgO:sPPLT crystal and obtain stable operation at high powers over a wide wavelength tuning range. For a pump power of 5 W, the DRO provides an output power of 2.45 W at an extraction efficiency as high as 49% when operated at optimum output coupling. The DRO shows a maximum pump depletion of 89% and delivers an optimum output power across a tuning range ≥90 nm. The demonstrated concept offers a promising approach for advancing the capabilities and control of coherent optical sources tunable across different spectral regions and in all time scales from continuous-wave to ultrafast femtosecond domain. [ABSTRACT FROM AUTHOR]

Published
2023
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38. Mid-infrared upconversion imaging using femtosecond pulses

Author

A.S, Ashik, O'Donnell, Callum F., Chaitanya Kumar, S., Ebrahim-Zadeh, M., Tidemand-Lichtenberg, Peter, Pedersen, Christian, A.S, Ashik, O'Donnell, Callum F., Chaitanya Kumar, S., Ebrahim-Zadeh, M., Tidemand-Lichtenberg, Peter, and Pedersen, Christian

Abstract

Mid-infrared (mid-IR) imaging and spectroscopic techniques have been rapidly evolving in recent years, primarily due to a multitude of applications within diverse fields such as biomedical imaging, chemical sensing, and food quality inspection. Mid-IR upconversion detection is a promising tool for exploiting some of these applications. In this paper, various characteristics of mid-IR upconversion imaging in the femtosecond regime are investigated using a 4f imaging setup. A fraction of the 100 fs, 80 MHz output from a Ti:sapphire laser is used to synchronously pump an optical parametric oscillator, generating 200 fs mid-IR pulses tunable across the 2.7–4.0 μm wavelength range. The signal-carrying mid-IR pulses are detected by upconversion with the remaining fraction of the original pump beam inside a bulk LiNbO3 crystal, generating an upconverted field in the visible/near-IR range, enabling silicon-based CCD detection. Using the same pump source for generation and detection ensures temporal overlap of pulses inside the nonlinear crystal used for upconversion, thus resulting in high conversion efficiency even in a single-pass configuration. A theory is developed to calculate relevant acceptance parameters, considering the large spectral bandwidths and the reduced interaction length due to group velocity mismatch, both associated with ultrashort pulses. Furthermore, the resolution of this ultrashort-pulsed upconversion imaging system is described. It is demonstrated that the increase in acceptance bandwidth leads to increased blurring in the upconverted images. The presented theory is consistent with experimental observations.

Published
2019

39. Video-rate, mid-infrared hyperspectral upconversion imaging

Author

Junaid, Saher, Chaitanya Kumar, S., Mathez, Morgan David, Hermes, M., Stone, N., Shephard, N., Ebrahim-Zadeh, M., Tidemand-Lichtenberg, Peter, Pedersen, Christian, Junaid, Saher, Chaitanya Kumar, S., Mathez, Morgan David, Hermes, M., Stone, N., Shephard, N., Ebrahim-Zadeh, M., Tidemand-Lichtenberg, Peter, and Pedersen, Christian

Abstract

In this work we demonstrate, to the best of our knowledge, a novel wide field-of-view upconversion system, supporting upconversion of monochromatic mid-infrared (mid-IR) images, e.g., for hyperspectral imaging (HSI). An optical parametric oscillator delivering 20 ps pulses tunable in the 2.3–4 μm range acts as a monochromatic mid-IR illumination source. A standard CCD camera, in synchronism with the crystal rotation of the upconversion system, acquires in only 2.5 ms the upconverted mid-IR images containing 64 kpixels, thereby eliminating the need for postprocessing. This approach is generic in nature and constitutes a major simplification in realizing video-frame-rate mid-IR monochromatic imaging. A second part of this paper includes a proof-of-principle study on esophageal tissues samples, from a tissue microarray, in the 3–4 μm wavelength range. The use of mid-IR HSI for investigation of esophageal cancers is particularly promising as it allows for a much faster and possibly more observer-independent workflow than state-of-the-art histology. Comparing histologically stained sections evaluated by a pathologist to images obtained by either Fourier transform IR or upconversion HSI based on machine learning shows great promise for further work pointing towards clinical translation using the presented mid-IR HSI upconversion system.

Published
2019

40. Theoretical modelling and experimental demonstration of a mid-infrared femtosecond upconversion system

Author

A.S, Ashik, O'Donnell, Callum F., Chaitanya Kumar, S., Ebrahim-Zadeh, M., Tidemand-Lichtenberg, Peter, Pedersen, Christian, A.S, Ashik, O'Donnell, Callum F., Chaitanya Kumar, S., Ebrahim-Zadeh, M., Tidemand-Lichtenberg, Peter, and Pedersen, Christian

Abstract

Summary form only given. Mid-infrared (mid-IR) imaging and spectroscopic techniques have been rapidly evolving in recent years, primarily due to a multitude of application within diverse fields like biomedical imaging, chemical sensing and cancer diagnostics [1]. Most complex chemicals have unique spectral signatures in the mid-IR region, facilitating unambiguous identification based on their absorption features. Owing to the limitations of conventional detectors in the mid-IR spectral range, sum frequency generation (SFG) in a second order nonlinear crystal can be used to convert the mid-IR signal to the visible/near-IR, enabling easy detection using silicon-based detectors. Ultrashort-pulsed upconversion is of particular interest for performing pump-probe experiments and studies of fast relaxation dynamics of chemicals and molecules [2]. In this work, we report the first demonstration of femtosecond mid-IR upconversion imaging using SFG in the Fourier plane of a 4f imaging setup. The theory developed in [3] is not valid in the short -pulsed regime (below approximately 1 picosecond) because it does not account for the reduced interaction length in the crystal (temporal walk -off between the interacting pulses) due to group velocity mismatch (GVM). We develop a theoretical model to describe femtosecond upconversion imaging, considering the broad spectrum associated with femtosecond pulses and reduced interaction length associated with GVM. This model enables the calculation of key parameters of a short -pulsed upconversion imaging system. We fmd a significant increase in angular and spectral acceptance bandwidth for mid-IR signal in the short -pulsed regimes, due to drastic reduction in interaction length, resulting in exceptionally large upconversion imaging fi eld of view (FoV) as depicted in Fig 1 (a). The resolution of the system is studied experimentally by illuminating a USAF resolution target with a mid-IR signal followed by detection of the upconverted sign

Published
2019

41. SHG (532 nm)-induced spontaneous parametric downconversion noise in 1064-nm-pumped IR upconversion detectors

Author

Meng, Lichun, Padhye, A, Pedersen, C, Ebrahim-Zadeh, M, Rodrigo, Peter John, Meng, Lichun, Padhye, A, Pedersen, C, Ebrahim-Zadeh, M, and Rodrigo, Peter John

Abstract

As a novel technique for infrared detection, frequency upconversion has been successfully deployed in many applications. However, investigations into the noise properties of upconversion detectors (UCDs) have also received considerable attention. In this Letter, to the best of our knowledge, we present a new noise source-second-harmonic generation (SHG)-induced spontaneous parametric downconversion-experimentally and theoretically shown to exist in short-wavelength-pumped UCDs. We investigate the noise properties of two UCDs based on single-pass 1064-nm-pumped periodically poled LiNbO3 bulk crystals. One UCD is designed to detect signals in the telecom band and the other in the mid-infrared regime. Our experimental demonstration and theoretical analysis reveal the basic properties of this newly discovered UCD noise source, including its dependence on crystal temperature and pump power. Furthermore, the principle behind the generation of this noise source can also be applied to other UCDs, which utilize nonlinear crystals either in waveguide form or with different bulk materials. This study may also aid in developing methods to suppress the newly identified noise in future UCD designs.

Published
2019

42. High-Power, Continuous-Wave, Fiber-Pumped Difference-Frequency-Generation at 2.26 μm.

Author

Sukeert, Kumar, S. Chaitanya, and Ebrahim-Zadeh, M.

Abstract

We report a high-power source of continuous-wave (cw) mid-infrared (mid-IR) radiation at 2.26 μm based on difference-frequency-generation (DFG) of a cw Yb-fiber laser at 1.064 μm and a cw Tm-fiber laser at 2.010 μm in MgO:PPLN. Using a 50-mm-long crystal with a single grating period of 32.16 μm$ and a simple single-pass setup, we generate up to 3.84 W of cw output power at 2.26 μm at a power conversion efficiency of ~0.47%/W. The DFG output beam is characterized by a Gaussian TEM00 spatial profile with M2 < 1.2, and exhibits excellent passive power stability of 0.6% rms and spectral stability better than 0.01% over 1 hour. We find close agreement between the measured conversion efficiencies and theoretical predictions, confirming optimum performance of the DFG source. Our approach represents a viable and practical alternative to the existing methods for generating this useful wavelength. To the best of our knowledge, the generated output represents the highest cw power obtained from any single-pass nonlinear frequency conversion source in the mid-IR. [ABSTRACT FROM AUTHOR]

Published
2021
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