Absolute SESAM characterization via polarization-resolved non-collinear equivalent time sampling.
Journal
Applied physics. B, Lasers and optics
ISSN: 0946-2171
Titre abrégé: Appl Phys B
Pays: Germany
ID NLM: 100910685
Informations de publication
Date de publication:
2022
2022
Historique:
received:
11
11
2021
accepted:
21
12
2021
entrez:
7
2
2022
pubmed:
8
2
2022
medline:
8
2
2022
Statut:
ppublish
Résumé
Semiconductor saturable absorber mirrors (SESAMs) have enabled a wide variety of modelocked laser systems, which makes measuring their nonlinear properties an important step in laser design. Here, we demonstrate complete characterization of SESAMs using an equivalent time sampling apparatus. The light source is a free-running dual-comb laser, which produces a pair of sub-150-fs modelocked laser outputs at 1051 nm from a single cavity. The average pulse repetition rate is 80.1 MHz, and the full time window is scanned at 240 Hz. Cross-correlation between the beams is used to calibrate the time axis of the measurements, and we use a non-collinear pump-probe geometry on the sample. The measurements enable fast and robust determination of all the nonlinear reflectivity and recovery time parameters of the devices from a single setup, and show good agreement with conventional nonlinear reflectivity measurements. We compare measurements to a rate equation model, showing good agreement up to high pulse fluence values and revealing that the samples tested exhibit a slightly slower recovery at higher fluence values. Lastly, we examine the polarization dependence of the reflectivity, revealing a reduced rollover if cross-polarized beams are used or if the sample is oriented optimally around the beam axis.
Identifiants
pubmed: 35125672
doi: 10.1007/s00340-022-07751-9
pii: 7751
pmc: PMC8770370
doi:
Types de publication
Journal Article
Langues
eng
Pagination
24Informations de copyright
© The Author(s) 2022.
Références
Opt Express. 2021 Jun 7;29(12):18059-18069
pubmed: 34154073
Opt Lett. 1999 May 1;24(9):631-3
pubmed: 18073806
Opt Lett. 2002 May 1;27(9):766-8
pubmed: 18007926
Opt Express. 2019 Oct 28;27(22):31465-31474
pubmed: 31684382
Opt Lett. 1991 Jun 15;16(12):901-3
pubmed: 19776823
Nature. 2003 Aug 14;424(6950):831-8
pubmed: 12917697
Opt Express. 2008 Nov 10;16(23):18646-56
pubmed: 19581950
Opt Lett. 1991 Jan 1;16(1):42-4
pubmed: 19773831
Opt Express. 2015 Mar 9;23(5):5521-31
pubmed: 25836785
Opt Express. 2013 Mar 25;21(6):6764-76
pubmed: 23546059
Appl Opt. 1987 Oct 1;26(19):4303-9
pubmed: 20490226
Optica. 2016 Dec;3(12):1397-1403
pubmed: 29170754
Opt Lett. 2001 Mar 15;26(6):373-5
pubmed: 18040328
Opt Lett. 1992 Apr 1;17(7):505-7
pubmed: 19794540
Opt Express. 2021 Oct 25;29(22):35735-35754
pubmed: 34809002
Opt Express. 2020 Sep 28;28(20):30275-30288
pubmed: 33114910
Opt Express. 2008 May 12;16(10):7571-9
pubmed: 18545462
Opt Lett. 2014 Aug 1;39(15):4384-7
pubmed: 25078183
Opt Express. 2016 May 16;24(10):10512-26
pubmed: 27409874
Opt Lett. 2019 Jan 1;44(1):25-28
pubmed: 30645536
Optica. 2016;3(4):
pubmed: 34131580
Opt Express. 2021 Feb 15;29(4):5934-5946
pubmed: 33726125
Nat Commun. 2017 Nov 22;8(1):1673
pubmed: 29162824