Characterization of spatiotemporal couplings with far-field beamlet cross-correlation

Slava Smartsev; Sheroy Tata; Aaron Liberman; Michael Adelberg; Arujash Mohanty; Eitan Y. Levine; Omri Seemann; Yang Wan; Eyal Kroupp; Ronan Lahaye; Cédric Thaury; Victor Malka

doi:10.1088/2040-8986/ac9631

Characterization of spatiotemporal couplings with far-field beamlet cross-correlation

Slava Smartsev
, Sheroy Tata
, Aaron Liberman
, Michael Adelberg
, Arujash Mohanty
, Eitan Y. Levine
, Omri Seemann
, Yang Wan
, Eyal Kroupp
, Ronan Lahaye
, Cédric Thaury
, Victor Malka

Research output: Contribution to journal › Article › peer-review

Abstract

We present a novel, straightforward method for the characterization of spatiotemporal couplings (STCs) in ultra-short laser pulses. The method employs far-field interferometry and inverse Fourier transform spectroscopy, built on the theoretical basis derived in this paper. It stands out in its simplicity: it requires few non-standard optical elements and simple analysis algorithms. This method was used to measure the space-time intensity of our 100 TW class laser and to test the efficacy of a refractive doublet as a suppressor of pulse front curvature (PFC). The measured low-order STCs agreed with ray-tracing simulations. In addition, we demonstrate a one-shot measurement technique, derived from our central method, which allows for quick and precise alignment of the compressor by pulse front tilt minimization and for optimal refractive doublet positioning for the suppression of PFC.

Original language	English
Article number	115503
Journal	Journal of Optics (United Kingdom)
Volume	24
Issue number	11
DOIs	https://doi.org/10.1088/2040-8986/ac9631
Publication status	Published - 1 Nov 2022

Keywords

far-field interferometry
inverse Fourier transform spectroscopy
pulse front curvature
pulse front tilt
spatiotemporal characterization
ultra-short laser pulses

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10.1088/2040-8986/ac9631

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title = "Characterization of spatiotemporal couplings with far-field beamlet cross-correlation",

abstract = "We present a novel, straightforward method for the characterization of spatiotemporal couplings (STCs) in ultra-short laser pulses. The method employs far-field interferometry and inverse Fourier transform spectroscopy, built on the theoretical basis derived in this paper. It stands out in its simplicity: it requires few non-standard optical elements and simple analysis algorithms. This method was used to measure the space-time intensity of our 100 TW class laser and to test the efficacy of a refractive doublet as a suppressor of pulse front curvature (PFC). The measured low-order STCs agreed with ray-tracing simulations. In addition, we demonstrate a one-shot measurement technique, derived from our central method, which allows for quick and precise alignment of the compressor by pulse front tilt minimization and for optimal refractive doublet positioning for the suppression of PFC.",

keywords = "far-field interferometry, inverse Fourier transform spectroscopy, pulse front curvature, pulse front tilt, spatiotemporal characterization, ultra-short laser pulses",

author = "Slava Smartsev and Sheroy Tata and Aaron Liberman and Michael Adelberg and Arujash Mohanty and Levine, \{Eitan Y.\} and Omri Seemann and Yang Wan and Eyal Kroupp and Ronan Lahaye and C{\'e}dric Thaury and Victor Malka",

note = "Publisher Copyright: {\textcopyright} 2022 The Author(s). Published by IOP Publishing Ltd.",

year = "2022",

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doi = "10.1088/2040-8986/ac9631",

language = "English",

volume = "24",

journal = "Journal of Optics (United Kingdom)",

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TY - JOUR

T1 - Characterization of spatiotemporal couplings with far-field beamlet cross-correlation

AU - Smartsev, Slava

AU - Tata, Sheroy

AU - Liberman, Aaron

AU - Adelberg, Michael

AU - Mohanty, Arujash

AU - Levine, Eitan Y.

AU - Seemann, Omri

AU - Wan, Yang

AU - Kroupp, Eyal

AU - Lahaye, Ronan

AU - Thaury, Cédric

AU - Malka, Victor

PY - 2022/11/1

Y1 - 2022/11/1

N2 - We present a novel, straightforward method for the characterization of spatiotemporal couplings (STCs) in ultra-short laser pulses. The method employs far-field interferometry and inverse Fourier transform spectroscopy, built on the theoretical basis derived in this paper. It stands out in its simplicity: it requires few non-standard optical elements and simple analysis algorithms. This method was used to measure the space-time intensity of our 100 TW class laser and to test the efficacy of a refractive doublet as a suppressor of pulse front curvature (PFC). The measured low-order STCs agreed with ray-tracing simulations. In addition, we demonstrate a one-shot measurement technique, derived from our central method, which allows for quick and precise alignment of the compressor by pulse front tilt minimization and for optimal refractive doublet positioning for the suppression of PFC.

AB - We present a novel, straightforward method for the characterization of spatiotemporal couplings (STCs) in ultra-short laser pulses. The method employs far-field interferometry and inverse Fourier transform spectroscopy, built on the theoretical basis derived in this paper. It stands out in its simplicity: it requires few non-standard optical elements and simple analysis algorithms. This method was used to measure the space-time intensity of our 100 TW class laser and to test the efficacy of a refractive doublet as a suppressor of pulse front curvature (PFC). The measured low-order STCs agreed with ray-tracing simulations. In addition, we demonstrate a one-shot measurement technique, derived from our central method, which allows for quick and precise alignment of the compressor by pulse front tilt minimization and for optimal refractive doublet positioning for the suppression of PFC.

KW - far-field interferometry

KW - inverse Fourier transform spectroscopy

KW - pulse front curvature

KW - pulse front tilt

KW - spatiotemporal characterization

KW - ultra-short laser pulses

U2 - 10.1088/2040-8986/ac9631

DO - 10.1088/2040-8986/ac9631

M3 - Article

AN - SCOPUS:85140267265

SN - 2040-8978

VL - 24

JO - Journal of Optics (United Kingdom)

JF - Journal of Optics (United Kingdom)

IS - 11

M1 - 115503

ER -

Characterization of spatiotemporal couplings with far-field beamlet cross-correlation

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Keywords

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