Energy-Transfer Kinetics Driven by Midinfrared Amplified Spontaneous Emission after Two-Photon Excitation from Xe (s0) to the Xe (6p[1/2]0) State.

In optically pumped laser systems, rare gas lasers (RGLs) are a field of great interest for researchers. Gas laser regimes with metastable Ne, Ar, and Kr atoms have been investigated, while studies of RGLs based on metastable Xe are sparse. In this work, when a strong excitation laser (2.92 mJ/pulse, 7.44 × 105 W/cm2) was applied to excite Xe atoms from the ground state to the 6p[1/2]0 state, an interesting phenomenon emerged: An intense fluorescence of 980 nm (6p[1/2]1-6s[3/2]2) was produced. However, when the energy of excitation laser was decreased to 0.50 mJ/pulse (1.27 × 105 W/cm2), the fluorescence of 980 nm became very weak. Besides, lifetime and decay rate constant of the 6p[1/2]0 state under the condition of E = 2.92 mJ are significantly different from either those measured by other groups or those of E = 0.50 mJ. These phenomena indicate that the high energy of excitation laser should trigger some new kinetic mechanisms. Further works identified that the new kinetic mechanism is the MIR ASE of 3408 nm (6p[1/2]0-6s'[1/2]1). The mechanisms are proposed as follows. Substantial 6p[1/2]0 atoms are produced by laser excitation. Then, the ASE of 3408 nm (6p[1/2]0-6s'[1/2]1) is quickly produced to populate substantial 6s'[1/2]1 atoms. The 6s'[1/2]1 atoms can readily arrive at the 6p[1/2]1 states through collision by virtue of the small energy difference (84 cm-1) and high collision rate constant of the transition from the 6s'[1/2]1 state to the 6p[1/2]1 state. As a result, the intense fluorescence of 980 nm is generated.

[1]  Andrew C. Tam,et al.  Particle formation by resonant laser light in alkali-metal vapor , 1975 .

[2]  D. Setser,et al.  Quenching Rate Constants and Product Assignments for Reactions of Xe(7p[3/2]2, 7p[5/2]2, and 6p‘[3/2]2) Atoms with Rare Gases, CO, H2, N2O, CH4, and Halogen-Containing Molecules , 1996 .

[3]  N. Bowering,et al.  Collisional deactivation of two‐photon laser excited xenon 5p5 6p. II. Lifetimes and total quench rates , 1986 .

[4]  V. K. Kanz,et al.  End-pumped continuous-wave alkali vapor lasers: experiment, model, and power scaling , 2004 .

[5]  N. Bowering,et al.  Collisional deactivation of two‐photon laser excited xenon 5p5 6p. I. State‐to‐state reaction rates , 1986 .

[6]  D. K. Anderson Lifetimes of the ( 5 p 5 6 s ) P 1 1 and P 1 3 States of Xenon , 1965 .

[7]  T. O. Nelson,et al.  Quenching Rate Constants of the Xe(5p56p and 6p') States and the Energy-Pooling Ionization Reaction of Xe(5p56s) Atoms , 1995 .

[8]  Michael C Heaven,et al.  Energy transfer kinetics of the np5(n + 1)p excited states of Ne and Kr. , 2011, The journal of physical chemistry. A.

[9]  V. A. Alekseev,et al.  A pulsed source for Xe(6s[3/2]1) and Xe(6s′[1/2]1) resonance state atoms using two‐photon driven amplified spontaneous emission from the Xe(6p) and Xe(6p′) states , 1996 .

[10]  P A Mikheyev Optically pumped rare-gas lasers , 2015 .

[11]  S. J. Davis,et al.  Laser excitation dynamics of argon metastables generated in atmospheric pressure flows by microwave frequency microplasma arrays , 2014, Photonics West - Lasers and Applications in Science and Engineering.

[12]  Jiande Han,et al.  Gain and lasing of optically pumped metastable rare gas atoms. , 2012, Optics letters.

[13]  Jiande Han,et al.  Kinetics of optically pumped Ar metastables. , 2014, Optics letters.

[14]  Leonid Glebov,et al.  Demonstration of a diode-pumped metastable Ar laser. , 2013, Optics letters.

[15]  Sugiyama,et al.  Shapes of laser-produced CsH particles. , 1989, Physical review letters.

[16]  D. Hanna,et al.  Stimulated hyper-Raman emission from sodium vapour , 1977 .

[17]  W. J. Alford State‐to‐state rate constants for quenching of xenon 6p levels by rare gases , 1992 .

[18]  Xiaojun Xu,et al.  Modeling of diode pumped metastable rare gas lasers. , 2015, Optics express.

[19]  J. Xu,et al.  Collisional deactivation studies of the Xe(6p) states in He and Ne , 1991 .

[20]  Leonid B. Glebov,et al.  Kinetics of an optically pumped metastable Ar laser , 2014, Photonics West - Lasers and Applications in Science and Engineering.

[21]  Christopher A. Rice,et al.  Near infrared rubidium 62P3/2,1/2→62S1/2 laser , 2016 .

[22]  M. Heaven,et al.  Kinetics of optically pumped Kr metastables. , 2015, Optics letters.

[23]  S. Davis,et al.  Optically pumped microplasma rare gas laser. , 2015, Optics express.

[24]  J. Ku,et al.  Collisional deactivation of Xe(5p56p) states in Xe and Ar , 1986 .

[25]  A. Kanaev,et al.  Collisional energy transfer in gaseous xenon with vacuum ultraviolet laser excitation of the 5d[1/2]1 atomic level , 1994 .

[26]  J. Xu,et al.  Deactivation rate constants and product branching in collisions of the Xe(6p) states with Kr and Ar , 1990 .

[27]  N. Sadeghi,et al.  Collisional transfer between the 6s'[12] 0,1 and 6p[12] 1 xenon levels , 1977 .

[28]  Xiaojun Xu,et al.  Experimental research of a chain of diode pumped rubidium amplifiers. , 2015, Optics express.

[29]  J. Ku,et al.  Laser induced fluorescence study of Xe(5p56p, 5p56p′, 5p57p, and 5p56d) states in Ne and Ar: Radiative lifetimes and collisional deactivation rate constants , 1984 .

[30]  J. Keto,et al.  Radiative lifetimes and collisional deactivation of two‐photon excited xenon in argon and xenon , 1990 .