Abstract
The research presented over the following 128 pages is a re-invention of the electrically pumped gas laser, dragging it kicking and screaming into the 21st century by replacing the cumbersome laser tube with new, state of the art hollow core optical fibres.
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References
J. Hecht, Understanding Lasers: An Entry-Level Guide (Wiley, 2008)
S.M. Hooker, C.E. Webb, Laser Physics (Oxford University Press, 2010)
C.S. Willett, Introduction to Gas Lasers: Population Inversion Mechanisms (Pergamon Press, 1974)
A. Javan, W.R. Bennett, D.R. Herriott, Population inversion and continuous optical maser oscillation in a gas discharge containing a He–Ne mixture. Phys. Rev. Lett. 6(3), 106 (1961)
C. Patel, W. Bennett, W. Faust, R. McFarlane, Infrared spectroscopy using stimulated emission techniques. Phys. Rev. Lett. 9(3), 102 (1962)
R.A. Paananen, D.L. Bobroff, Very high gain gaseous (Xe–He) optical maser at 3.5\(\,\upmu \)m. Appl. Phys. Lett. 2(5), 99 (1963)
H. Van Bueren, J. Haisma, H. De Lang, A small and stable continuous gas laser. Phys. Lett. 2(7), 340 (1962)
P.W. Smith, On the optimum geometry of a 6328Ã… laser oscillator. IEEE J. Quan. Electr. 2(4), 77 (1966)
P.O. Clark, Investigation of the operating characteristics of the 3.5\(\,\upmu \)m xenon laser. IEEE J. Quant. Electr. 1(3), 109 (1965)
P.W. Smith, A waveguide gas laser. Appl. Phys. Lett. 19, 132 (1971)
E.A.J. Marcatili, R.A. Schmeltzer, Hollow metallic and dielectric waveguides for long distance optical transmission and lasers. Bell Syst. Tech. J. 43(4), 1783 (1964)
P.W. Smith, P.J. Maloney, A self-stabilized 3.5\(\,\upmu \)m waveuide He–Xe laser. Appl. Phys. Lett. 22, 667 (1973)
R.F. Cregan, Single-mode photonic band gap guidance of light in air. Science 285(5433), 1537 (1999)
A.M. Jones, A.V.V. Nampoothiri, A. Ratanavis, T. Fiedler, N.V. Wheeler, F. Couny, R. Kadel, F. Benabid, B.R. Washburn, K.L. Corwin, W. Rudolph, Mid-infrared gas filled photonic crystal fiber laser based on population inversion. Opt. Exp. 19(3), 2309 (2011)
M.R.A. Hassan, F. Yu, W.J. Wadsworth, J.C. Knight, Cavity-based mid-IR fiber gas laser pumped by a diode laser. Optica 3(3), 218 (2016)
F. Vial, K. Gadonna, B. Debord, F. Delahaye, F. Amrani, O. Leroy, F. Gérôme, F. Benabid, Generation of surface-wave microwave microplasmas in hollow-core photonic crystal fiber based on a split-ring resonator. Opt. Lett. 41(10), 2286 (2016)
X. Shi, X.B. Wang, W. Jin, M.S. Demokan, Investigation of glow discharge of gas in hollow-core fibers. Appl. Phys. B Lasers Opt. 91(2), 377 (2008)
F. Yu, W.J. Wadsworth, J.C. Knight, Low loss silica hollow core fibers for 3–4\(\,\upmu \)m spectral region. Opt. Exp. 20(10), 11153 (2012)
W. Belardi, J.C. Knight, Hollow antiresonant fibers with low bending loss. Opt. Exp. 22(8), 10091 (2014)
F. Yu, J.C. Knight, Negative curvature hollow-core optical fiber. IEEE J. Sel. Top. Quant. Electr. 22(2) (2016)
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Love, A. (2018). Introduction. In: Hollow Core Optical Fibre Based Gas Discharge Laser Systems. Springer Theses. Springer, Cham. https://doi.org/10.1007/978-3-319-93970-4_1
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DOI: https://doi.org/10.1007/978-3-319-93970-4_1
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