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1. Acousto-optic modulator pulse-shaper compression of octave-spanning pulses from a stretched hollow-core fiber

   https://doi.org/10.1364/OSAC.440476  

   Catanese, Anthony; Kaufman, Brian; Cheng, Chuan; Jones, Eric; Cohen, Martin_G; Weinacht, Thomas (December 2021, OSA Continuum)

   We demonstrate spectral broadening and compression of amplified pulses from a titanium sapphire laser system using an argon-filled stretched, hollow-core fiber and an acousto-optic modulator based pulse-shaper. We characterize the pulses using pulse-shaper assisted collinear frequency resolved optical gating, pulse-shaper assisted D-scans, and D-scans using a variable path length water cell. The different compression and characterization approaches consistently compress the pulses down to < 6 fs, less than ∼1 fs from the transform limit. We discuss prospects for pulse shape spectroscopy with these broadband pulses, given our control over the spectral amplitude and phase. 

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2. Temporally Localized Quantum Operations on Continuous-Wave Thermal Light

   https://doi.org/10.1103/y4v8-1wgm  

   Wang, Yunkai; Zhang, Yujie; Lorenz, Virginia O (September 2025, Physical Review Letters)

   Previous work showed that thermal light with a blackbody spectrum cannot be decomposed into a mixture of independent localized pulses. However, we find that in the weak-source limit and under the assumption of a flat spectrum, the first nonvacuum term in the state expansion does form a mixture of such pulses. This decomposition is essential for quantum-enhanced astronomical interferometry, which typically operates on localized pulses even though stellar light is inherently continuous-wave. We present a quantum derivation of the van Cittert–Zernike theorem that incorporates finite bandwidth, thereby justifying the operations on localized pulses while processing continuous-wave thermal light. For general spectra in the weak-source limit, we establish a criterion under which correlations between pulses can be safely neglected. When this criterion is not met, we provide a corrected strategy that accurately accounts for both the spectral profile and the detector-defined pulse shape. 

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3. Characterization of vacuum and deep ultraviolet pulses via two-photon autocorrelation signals

   https://doi.org/10.1364/OL.427200  

   Walker, S.; Reiff, R.; Jaron-Becker, A.; Becker, A. (June 2021, Optics Letters)

   Characterization of ultrashort vacuum and deep ultraviolet pulses is important in view of applications of those pulses for spectroscopic and dynamical imaging of atoms, molecules, and materials. We present an extension of the autocorrelation technique, applied for measurement of the pulse duration via a single Gaussian function. Analytic solutions for two-photon ionization of atoms by Gaussian pulses are used along with an expansion of the pulse to be characterized using multiple Gaussians at multi-color central frequencies. This approach allows one to use two-photon autocorrelation signals to characterize isolated ultrashort pulses and pulse trains, i.e., the time-dependent amplitude and phase variation of the electric field. The potential of the method is demonstrated using vacuum and deep ultraviolet pulses and pulse trains obtained from numerical simulations of macroscopic high harmonic spectra. 

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4. Weak beam self-cleaning of femtosecond pulses in the anomalous dispersion regime

   https://doi.org/10.1364/OL.430926  

   Wu, Yuhang; Pourbeyram, Hamed; Christodoulides, Demetrios_N; Wise, Frank_W (July 2021, Optics Letters)

   Kerr beam cleaning in graded-index multimode fiber has been investigated in experiments with sub-nanosecond pulses and in experiments with femtosecond pulses at wavelengths where the dispersion is normal. We report a theoretical and experimental study of this effect with femtosecond pulses and anomalous dispersion. In this regime, only weak beam cleaning is observed experimentally, along with strong temporal evolution of the pulse. Numerical simulations exhibit the qualitative trends of the experiments. 

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5. Nonlinear waves at the free surface of flexible mechanical metamaterials

   https://doi.org/10.1063/5.0135375  

   Deng, Bolei; Shu, Hang; Li, Jian; Mo, Chengyang; Raney, Jordan R; Tournat, Vincent; Bertoldi, Katia (July 2023, Applied Physics Letters)

   In this Letter, we investigate the propagation of nonlinear pulses along the free surface of flexible metamaterials based on the rotating squares mechanism. While these metamaterials have previously been shown to support the propagation of elastic vector solitons through their bulk, here, we demonstrate that they can also support the stable propagation of nonlinear pulses along their free surface. Furthermore, we show that the stability of these surface pulses is higher when they minimally interact with the linear dispersive surface modes. Finally, we provide guidelines to select geometries that minimize these interactions. 

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