Intense infrared lasers for strong-field science

Zenghu Chang; Zenghu Chang; Li Fang; Vladimir Fedorov; Chase Geiger; Chase Geiger; Shambhu Ghimire; Christian Heide; Nobuhisa Ishii; Jiro Itatani; Chandrashekhar Joshi; Yuki Kobayashi; Prabhat Kumar; Alphonse Marra; Alphonse Marra; Sergey Mirov; Irina Petrushina; Mikhail Polyanskiy; David A. Reis; Sergei Tochitsky; Sergey Vasilyev; Lifeng Wang; Lifeng Wang; Yi Wu; Yi Wu; Fangjie Zhou; Fangjie Zhou

doi:10.1364/AOP.454797

Advances in Optics and Photonics
Vol. 14,
Issue 4,
pp. 652-782
(2022)
•https://doi.org/10.1364/AOP.454797

Intense infrared lasers for strong-field science

Zenghu Chang, Li Fang, Vladimir Fedorov, Chase Geiger, Shambhu Ghimire, Christian Heide, Nobuhisa Ishii, Jiro Itatani, Chandrashekhar Joshi, Yuki Kobayashi, Prabhat Kumar, Alphonse Marra, Sergey Mirov, Irina Petrushina, Mikhail Polyanskiy, David A. Reis, Sergei Tochitsky, Sergey Vasilyev, Lifeng Wang, Yi Wu, and Fangjie Zhou

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Zenghu Chang, Li Fang, Vladimir Fedorov, Chase Geiger, Shambhu Ghimire, Christian Heide, Nobuhisa Ishii, Jiro Itatani, Chandrashekhar Joshi, Yuki Kobayashi, Prabhat Kumar, Alphonse Marra, Sergey Mirov, Irina Petrushina, Mikhail Polyanskiy, David A. Reis, Sergei Tochitsky, Sergey Vasilyev, Lifeng Wang, Yi Wu, and Fangjie Zhou, "Intense infrared lasers for strong-field science," Adv. Opt. Photon. 14, 652-782 (2022)

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- Ultrafast Optics
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About this Article
History
- Original Manuscript: January 25, 2022
- Revised Manuscript: July 31, 2022
- Manuscript Accepted: August 2, 2022
- Published: November 1, 2022

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Abstract

The advent of chirped-pulse amplification in the 1980s and femtosecond Ti:sapphire lasers in the 1990s enabled transformative advances in intense laser–matter interaction physics. Whereas most of experiments have been conducted in the limited near-infrared range of 0.8–1 μm, theories predict that many physical phenomena such as high harmonic generation in gases favor long laser wavelengths in terms of extending the high-energy cutoff. Significant progress has been made in developing few-cycle, carrier-envelope phase-stabilized, high-peak-power lasers in the 1.6–2 μm range that has laid the foundation for attosecond X ray sources in the water window. Even longer wavelength lasers are becoming available that are suitable to study light filamentation, high harmonic generation, and laser–plasma interaction in the relativistic regime. Long-wavelength lasers are suitable for sub-bandgap strong-field excitation of a wide range of solid materials, including semiconductors. In the strong-field limit, bulk crystals also produce high-order harmonics. In this review, we first introduce several important wavelength scaling laws in strong-field physics, then describe recent breakthroughs in short- (1.4–3 μm), mid- (3–8 μm), and long-wave (8–15 μm) infrared laser technology, and finally provide examples of strong-field applications of these novel lasers. Some of the broadband ultrafast infrared lasers will have profound effects on medicine, environmental protection, and national defense, because their wavelengths cover the water absorption band, the molecular fingerprint region, as well as the atmospheric infrared transparent window.

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	Near Infrared	Short-Wave Infrared	Mid-Wave Infrared	Long-Wave Infrared	Far Infrared
Abbreviation	NIR	SWIR	MWIR	LWIR	FIR
Wavelength (μm)	0.75–1.4	1.4–3	3–8	8–15	15–1000

	Tm:YLF	Tm:YAG	Tm:fiber (silica)	Ho:YLF	Ho:YAG	Yb:YAG
Laser wavelength (μm)	1.88 (π)	2.013	1.86	2.05 (π)	2.09	1.03
Emission cross-section
(10⁻²⁰cm²)	0.37 (π)	0.18	0.39	1.555 (π)	1.0	2.2
Absorption peak wavelength (μm)	0.792	0.785		1.94	1.908	0.94
Absorption cross-section at peak (10⁻²⁰cm²)	0.8	0.75	0.45	1.0 (π)	1.09	0.82
Fluorescence lifetime (ms)	15.6	10	6.6	14	7	1.2
Quantum defect (%)	15.7	22		5.4	9.1	8.7
Nonlinear index of refraction (10⁻¹⁶cm²/W)				1.72 at 1 μm	6.2 at 1 μm	6.02 at 1 μm 8.00 at 0.8 μm
Bulk damage threshold at 4.6–10 ns (GW/cm²)	15			18.9	10.1
dn/dT (10⁻⁶ /K)	–4.6 (//c) –6.6 (//a)	7.3		–4.6 (//c) –6.6 (//a)	7.3	7.3
Thermal conductivity(W/m/K)	6	13		6	13	13

Host	ZnS	ZnSe
Crystal symmetry	ZB	ZB
Transparency window, μm	0.4–14	0.5–20
Max optical phonon ν, cm^–1	350	250
Thermal conductivity, W/cm·K	0.27	0.19
Refractive index @3 μm	2.26	2.44
n^-1 dn/dT, 10⁻⁵K^-1	1.9	2.6
Max d₁₄= d₂₅= d₂₆, pV/m @1.3 μm	8 [134]	30 [134]
γ at 2.4 µm, ×10²⁰m²/W	48 [135]	113 [135]

Gas Species	λ = 0.8 μm [29]	λ = 2.4 μm [534]	λ = 10.6 μm [30]
	n₂,_eff (10⁻¹⁹cm²/W)	n₂,_eff (10⁻¹⁹cm²/W)	n₂,_eff (10⁻¹⁹cm²/W)
N₂	3 ± 0.7	3.2 ± 0.5^b	4.5 ± 0.9
O₂	8 ± 2.2	6.4 ± 0.8^b	8.4 ± 1.3
Air	3 ± 0.7^a	-	5.0 ± 0.9

	Near Infrared	Short-Wave Infrared	Mid-Wave Infrared	Long-Wave Infrared	Far Infrared
Abbreviation	NIR	SWIR	MWIR	LWIR	FIR
Wavelength (μm)	0.75–1.4	1.4–3	3–8	8–15	15–1000

Abstract

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Figures (38)

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Equations (64)

Advances in Optics and Photonics