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1. Attosecond Streaking Time Delays: Finite-Range Interpretation and Applications

   https://doi.org/10.3390/app9030492  

   Goldsmith, Cory; Jaroń-Becker, Agnieszka; Becker, Andreas (February 2019, Applied Sciences)

   We review theoretical studies of the attosecond streaking time delay concept in photoionization via the investigation of the electron dynamics in the streaking field after the transition of the photoelectron into the continuum upon absorption of an extreme ultraviolet photon. Based on the results, a so-called finite range interpretation was introduced, which highlighted that the delay is accumulated until the streaking pulse ends and, hence, over a finite range of the potential of the parent ion. Following a discussion of the analysis leading to this interpretation, we summarize a few applications which provide insights into different aspects of the streaking time delay concept in photoionization. Besides a review of previously presented results, we give an analysis of the relevance of the first half-cycle of the streaking field and an outlook regarding the perspective of using the streaking method to resolve dynamical changes in the potential that the photoelectron explores during its propagation in the continuum. 

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2. High-order harmonic generation from a thin film crystal perturbed by a quasi-static terahertz field

   https://doi.org/10.1038/s41467-023-38187-0  

   Li, Sha; Tang, Yaguo; Ortmann, Lisa; Talbert, Bradford K.; Blaga, Cosmin I.; Lai, Yu Hang; Wang, Zhou; Cheng, Yang; Yang, Fengyuan; Landsman, Alexandra S.; et al (May 2023, Nature Communications)

   Abstract Studies of laser-driven strong field processes subjected to a (quasi-)static field have been mainly confined to theory. Here we provide an experimental realization by introducing a bichromatic approach for high harmonic generation (HHG) in a dielectric that combines an intense 70 femtosecond duration mid-infrared driving field with a weak 2 picosecond period terahertz (THz) dressing field. We address the physics underlying the THz field induced static symmetry breaking and its consequences on the efficient production/suppression of even-/odd-order harmonics, and demonstrate the ability to probe the HHG dynamics via the modulation of the harmonic distribution. Moreover, we report a delay-dependent even-order harmonic frequency shift that is proportional to the time derivative of the THz field. This suggests a limitation of the static symmetry breaking interpretation and implies that the resultant attosecond bursts are aperiodic, thus providing a frequency domain probe of attosecond transients while opening opportunities in precise attosecond pulse shaping. 

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3. An Improved Ptychographic Algorithm for Multi-Pulse Phase Retrieval

   https://doi.org/10.1364/FIO.2020.FM2A.6  

   Wilhelm, Alex M.; Schmidt, David D.; Adams, Daniel E.; Durfee, Charles G. (September 2020, Frontiers in Optics)

   B. Lee, C. Mazzali (Ed.)

   We present a ptychographic phase retrieval algorithm which solves the square root problem in second order pulse measurement techniques and reconstructs the fields of multiple incoherent pulses simultaneously from a single dispersion scan trace. 

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4. Multi-mode root preserving ptychographic phase retrieval algorithm for dispersion scan

   https://doi.org/10.1364/OE.426859  

   Wilhelm, Alex_M; Schmidt, David_D; Adams, Daniel_E; Durfee, Charles_G (June 2021, Optics Express)

   We present a phase retrieval algorithm for dispersion scan (d-scan), inspired by ptychography, which is capable of characterizing multiple mutually-incoherent ultrafast pulses (or modes) in a pulse train simultaneously from a single d-scan trace. In addition, a form of Newton’s method is employed as a solution to the square root problem commonly encountered in second harmonic pulse measurement techniques. Simulated and experimental phase retrievals of both single-mode and multi-mode d-scan traces are shown to demonstrate the accuracy and robustness of the root preserving ptychographic algorithm (RPPA). 

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5. Retrieval of Vertical Profile of Cirrus Cloud Effective Particle Size Using Reflected Line Spectra in 1.38 μm Band

   https://doi.org/10.1029/2020EA001119  

   Gu, Yu; Takano, Yoshi; Liou, Kuo‐Nan (May 2020, Earth and Space Science)

   Abstract This paper presents a new retrieval method for inferring the vertical profile of cirrus cloud effective particle size by using solar reflected line spectra in the 1.38‐μm band. The retrieval method is based on the maximum‐photon penetration principle coupled with the constrained linear inversion. This approach takes advantage of the vertical stratification of cirrus cloud effective particle size as well as absorption lines of water vapor of different intensity, which contain rich information on the vertical structure of cloud particle size. Reflected radiances at different wavenumbers provide the effective‐size information at different heights within cirrus associated with photon different penetration depths. Assuming a vertical profile of effective size monotonically decreasing toward cloud top and using results based on “exact” radiative transfer computations, we perform retrieval of the effective size for a number of model cirrus to check for algorithm accuracy. The retrieved profile of effective size is close to the model profile for cirrus optical depth less than about eight with an uncertainty range of 2.2–4.2 μm. In addition, we further carry out a sensitivity study involving the retrieved effective size in connection with different water vapor profiles and demonstrate that the difference from the model is only several percent except for the cloud top if an appropriate wavenumber set is selected. The results from this study suggest that the present method can be applied to realistic remote sensing of the vertical profile of cirrus cloud particle size. 

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