All Stories

  1. Modeling of static and flowing-gas diode pumped alkali lasers
  2. Flowing-gas diode pumped alkali lasers: theoretical analysis of transonic vs supersonic and subsonic devices
  3. Modeling of pulsed K DPAL taking into account the spatial variation of the pump and laser intensities in the transverse direction
  4. Supersonic diode pumped alkali lasers: Computational fluid dynamics modeling
  5. CFD assisted simulation of temperature distribution and laser power in pulsed and CW pumped static gas DPALs
  6. 3D CFD modeling of subsonic and transonic flowing-gas DPALs with different pumping geometries
  7. Modeling of supersonic diode pumped alkali lasers
  8. Modeling of pulsed K diode pumped alkali laser: Analysis of the experimental results
  9. Semi-analytical and CFD model calculations of subsonic flowing-gas DPALs and their comparison to experimental results
  10. Computational fluid dynamics modeling of subsonic flowing-gas diode-pumped alkali lasers: comparison with semi-analytical model calculations and with experimental results
  11. Theoretical studies of the feasibility of supersonic DPALs
  12. CFD DPAL modeling for various schemes of flow configurations
  13. Comparison of semi-analytical to CFD model calculations and to experimental results of subsonic flowing-gas and static DPALs
  14. Enhanced stimulated Raman scattering in temperature controlled liquid water
  15. Structure, dynamics, and light localization in self-induced plasma photonic lattices
  16. Kinetic and fluid dynamic processes in diode pumped alkali lasers: semi-analytical and 2D and 3D CFD modeling
  17. Semi-analytical and 3D CFD DPAL modeling: feasibility of supersonic operation
  18. Model calculations of kinetic and fluid dynamic processes in diode pumped alkali lasers
  19. What can we gain from supersonic operation of diode pumped alkali lasers: model calculations
  20. Computational modeling of laser-plasma interactions: Pulse self-modulation and energy transfer between intersecting laser pulses
  21. Feasibility of supersonic diode pumped alkali lasers: Model calculations
  22. Detailed analysis of kinetic and fluid dynamic processes in diode-pumped alkali lasers
  23. Static diode pumped alkali lasers: Model calculations of the effects of heating, ionization, high electronic excitation and chemical reactions
  24. Modeling of static and flowing-gas diode pumped alkali lasers
  25. Modeling of flowing gas diode pumped alkali lasers: dependence of the operation on the gas velocity and on the nature of the buffer gas
  26. The I2 dissociation mechanisms in the chemical oxygen-iodine laser revisited
  27. I2 Dissociation Mechanisms In the Chemical Oxygen-Iodine Laser Revisited Using Three- And One- Dimensional Computational Fluid Dynamics Modeling
  28. Comparison of one- and three-dimensional computational fluid dynamics models of the supersonic chemical oxygen–iodine laser
  29. A historical overview on the mechanism of the COIL kinetics
  30. Lasing in supersonic chemical oxygen-iodine lasers: recent modeling and comparison with experiment
  31. Comparing modeling and measurements of the output power in chemical oxygen-iodine lasers: A stringent test of I2 dissociation mechanisms
  32. Modeling of the Gain and the Power in Chemical Oxygen-Iodine Lasers
  33. Kinetic-fluid dynamics modeling of I2 dissociation in supersonic chemical oxygen-iodine lasers
  34. Experiments and Modeling of Supersonic COILs
  35. Analysis of lasing in chemical oxygen-iodine lasers with unstable resonators using a geometric-optics model
  36. Supersonic COILs at Ben-Gurion University: (1) experiments on 10-cm gain-length device and (2) computational fluid dynamics modelling
  37. A computational fluid dynamics simulation of a high pressure ejector COIL and comparison to experiments
  38. Analysis of lasing in COILs with positive and negative branch unstable resonators using a simple geometrical-optics model
  39. Modeling of the gain and temperature in high pressure, ejector type chemical oxygen-iodine lasers and comparison to experiments
  40. Toward understanding the dissociation of I2 in chemical oxygen-iodine lasers: Combined experimental and theoretical studies
  41. Combined Experimental and Theoretical Studies of I2 Dissociation in Supersonic COILs
  42. Dissociation of I 2 in chemical oxygen-iodine lasers: experiment, modeling, and pre-dissociation by electrical discharge
  43. Power enhancement in chemical oxygen-iodine lasers by iodine predissociation via corona/glow discharge
  44. Studies of iodine dissociation in the chemical oxygen-iodine laser
  45. A computational fluid dynamics simulation of a supersonic chemical oxygen-iodine laser
  46. How many O2(Δ1) molecules are consumed per dissociated I2 in chemical oxygen-iodine lasers?
  47. Detailed gain measurements and analysis of a highly efficient supersonic COIL
  48. Parametric study of a highly efficient chemical oxygen-iodine laser with supersonic mixing of iodine and oxygen
  49. Diagnostic Studies of Ben-Gurion University High Efficiency Supersonic COIL
  50. Recent studies of Ben-Gurion Univ. high efficiency supersonic chemical oxygen-iodine laser
  51. Nearly attaining the theoretical efficiency of supersonic chemical oxygen-iodine lasers
  52. Parametric study of the Ben-Gurion University efficient chemical oxygen-iodine laser
  53. Mechanisms of COIL operation: experiment and modeling
  54. Comparative Studies of Different Schemes of Iodine Injection in a High Efficiency Supersonic COIL
  55. A 33% efficient chemical oxygen–iodine laser with supersonic mixing of iodine and oxygen
  56. Spatial distribution of the gain and temperature across the flow in a slit-nozzle supersonic chemical oxygen-iodine laser with transonic and supersonic schemes of iodine injection
  57. Gain and temperature in a slit nozzle supersonic chemical oxygen-iodine laser with transonic and supersonic injection of iodine
  58. Modeling of the gain, temperature, and iodine dissociation fraction in a supersonic chemical oxygen-iodine laser
  59. One-dimensional modeling of the gain and temperature in a supersonic chemical oxygen-iodine laser with transonic injection of iodine
  60. Current status of chemical oxygen-iodine laser research
  61. Supersonic COIL with iodine injection in transonic and supersonic sections of the nozzle
  62. Iodine dissociation in supersonic COILs with different schemes of iodine mixing
  63. Parametric study of small-signal gain in a slit nozzle, supersonic chemical oxygen-iodine laser operating without primary buffer gas
  64. Gain, yield and water vapor diagnostics in supersonic COILs with different schemes of iodine injection
  65. Iodine dissociation and small signal gain in supersonic COILs
  66. Gain diagnostic in a supersonic COIL with transonic injection of iodine
  67. Small-signal gain and iodine dissociation in a supersonic chemical oxygen–iodine laser with transonic injection of iodine
  68. Diode-laser-based absorption spectroscopy diagnostics of a jet-type O/sub 2/(/sup 1/Δ) generator for chemical oxygen-iodine lasers
  69. Chemical oxygen-iodine laser investigations in Israel
  70. Analysis of lasing in gas-flow lasers with stable resonators
  71. Parametric study of an efficient supersonic chemical oxygen-iodine laser/jet generator system operating without buffer gas
  72. Parametric studies of a small-scale chemical oxygen-iodine laser/jet generator system: recent achievements
  73. Modeling of lasing in COILS with stable resonators
  74. An efficient supersonic chemical oxygen–iodine laser operating without buffer gas and with simple nozzle geometry
  75. Analysis of lasing in COILs with wide aperture of the mirrors in the resonator
  76. Experimental study of a small scale COIL using a jet type generator of singlet oxygen
  77. Analysis of the optical extraction efficiency in gas-flow lasers with different types of resonator
  78. Power dependence of chemical oxygen-iodine lasers on iodine dissociation
  79. Power optimization of small-scale chemical oxygen-iodine laser with jet-type singlet oxygen generator
  80. Optical extraction efficiency in gas-flow lasers
  81. Experiment and modeling of a small-scale, supersonic chemical oxygen-iodine laser
  82. Theoretical modeling of iodine dissociation in COILs (chemical oxygen-iodine laser)
  83. Simple analytical expressions for the optical extraction efficiency from COILs with different kinds of resonators
  84. Parametric study of the gain in a small scale, grid nozzle, supersonic chemical oxygen-iodine laser
  85. Parametric studies of a small-scale supersonic chemical oxygen-iodine laser (COIL)
  86. Gain and power in COILs - Theory and experiment
  87. Modeling of mixing in chemical oxygen‐iodine lasers: Analytic and numerical solutions and comparison with experiments
  88. The sudden expansion of a gas cloud into vacuum revisited
  89. Dynamics of the detonation products of lead azide: III. Laser‐induced hole burning and flow visualization
  90. Modeling of high-pressure O2(1^) generators for chemical oxygen-iodine lasers
  91. Effect of mixing on iodine dissociation, population inversion and lasing in chemical oxygen-iodine lasers
  92. Theoretical modeling of chemical generators producing O2(1Δ) at high pressure for chemically pumped iodine lasers
  93. Possibility of long population inversion in active media for IR chemical lasers
  94. The possibility of “long” population inversion in active media for IR chemical lasers
  95. Formation Of Active Medium For IR And Visible Chemical Lasers During The Combustion Of Finely Dispersed Metal Particles In The Oxidizer
  96. IR chemical lasers: Active medium formation via the combustion of finely disperse metal particles in an oxidizing atmosphere
  97. Singlet oxygen generator of the atomizer type
  98. Amplification of radiation behind the front of a shock wave in high-pressure H 2 –F 2 mixtures
  99. Nonequilibrium gas-surface-solid in problems of relaxation gasdynamics
  100. Chemical lasers: COIL
  101. An extremely efficient supersonic chemical oxygen-iodine laser