High-resolution Cs–Rb two-photon spectrometer for directly stabilizing a Ti:sapphire comb laser

Tze-Wei Liu; Tze-Wei Liu; Bo-Wei Chen; Bo-Wei Chen; Bo-Wei Chen; Hsin-Hung Yu; Wang-Yau Cheng

doi:10.1364/OL.486825

Optics Letters
Vol. 48,
Issue 9,
pp. 2421-2424
(2023)
•https://doi.org/10.1364/OL.486825

High-resolution Cs–Rb two-photon spectrometer for directly stabilizing a Ti:sapphire comb laser

Tze-Wei Liu, Bo-Wei Chen, Hsin-Hung Yu, and Wang-Yau Cheng

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Tze-Wei Liu, Bo-Wei Chen, Hsin-Hung Yu, and Wang-Yau Cheng, "High-resolution Cs–Rb two-photon spectrometer for directly stabilizing a Ti:sapphire comb laser," Opt. Lett. 48, 2421-2424 (2023)

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- Optical Sensors, Measurements, and Metrology
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About this Article
History
- Original Manuscript: February 2, 2023
- Revised Manuscript: March 5, 2023
- Manuscript Accepted: March 19, 2023
- Published: April 27, 2023

Abstract

In this paper, we present a simple scheme for efficiently removing the residual Doppler background of a comb laser based two-photon spectrometer to be better than 10⁻³ background-to-signal ratio. We applied this scheme to stabilize the frequencies of a mode-locked Ti:sapphire laser directly referring to the cesium 6S–8S transition and rubidium 5S–5D transition. We suggest a standard operation procedure (SOP) for the fully direct comb laser stabilization and evaluate the frequency of two spectral lines at a certain temperature, by which we demonstrate an all-atomic-transition-based Ti:sapphire comb laser merely via a 6-cm glass cell.

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Data underlying the results presented in this Letter are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Lines in Fig. 2	Transition Pathways	Velocity^a
⁸⁷Rb line 6	5S_1/2 F = 1→5P_3/2 F = 2→5D_3/2 F = 3	172.2 (ms⁻¹)
⁸⁷Rb line 7	5S_1/2 F = 1→5P_3/2 F = 2→5D_5/2 F = 3	181.2 (ms⁻¹)
¹³³Cs line 7’	6S_1/2 F = 3→6P_3/2 F = 2→8S_1/2 F = 3	192.4 (ms⁻¹)
¹³³Cs line 8'	6S_1/2 F = 4→6P_3/2 F = 3→8S_1/2 F = 3 6S_1/2 F = 3→6P_3/2 F = 3→8S_1/2 F = 3*	317.1 (ms⁻¹)
¹³³Cs line 9'	^a6S_1/2 F = 4→6P_3/2 F = 4→8S_1/2 F = 3 6S_1/2 F = 3→6P_3/2 F = 4→8S_1/2 F = 3	482.5 (ms⁻¹)

Cell/Cold Finger (°C)	Line 7^b Shift (kHz)	Line 7^c Width (MHz)	Line 8’^b Shift (kHz)	Line 8’^c Width (MHz)
95.8/77.4	0	1.86 (4)	0	2.21 (4)
74.0/61.9	45 (4)	1.36 (6)	10 (6)	2.15 (2)
53.6/47.5	62 (3)	1.35 (6)	-67 (10)	1.75 (6)
26.1/26.1	20 (3)	1.5 (1)	-123 (8)	1.52 (8)

Lines in Fig. 2	Transition Pathways	Velocity^a
⁸⁷Rb line 6	5S_1/2 F = 1→5P_3/2 F = 2→5D_3/2 F = 3	172.2 (ms⁻¹)
⁸⁷Rb line 7	5S_1/2 F = 1→5P_3/2 F = 2→5D_5/2 F = 3	181.2 (ms⁻¹)
¹³³Cs line 7’	6S_1/2 F = 3→6P_3/2 F = 2→8S_1/2 F = 3	192.4 (ms⁻¹)
¹³³Cs line 8'	6S_1/2 F = 4→6P_3/2 F = 3→8S_1/2 F = 3 6S_1/2 F = 3→6P_3/2 F = 3→8S_1/2 F = 3*	317.1 (ms⁻¹)
¹³³Cs line 9'	^a6S_1/2 F = 4→6P_3/2 F = 4→8S_1/2 F = 3 6S_1/2 F = 3→6P_3/2 F = 4→8S_1/2 F = 3	482.5 (ms⁻¹)

Cell/Cold Finger (°C)	Line 7^b Shift (kHz)	Line 7^c Width (MHz)	Line 8’^b Shift (kHz)	Line 8’^c Width (MHz)
95.8/77.4	0	1.86 (4)	0	2.21 (4)
74.0/61.9	45 (4)	1.36 (6)	10 (6)	2.15 (2)
53.6/47.5	62 (3)	1.35 (6)	-67 (10)	1.75 (6)
26.1/26.1	20 (3)	1.5 (1)	-123 (8)	1.52 (8)

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Optics Letters