Title :
Self-channeling and pulse shortening of femtosecond pulses in multiphotonionized dielectric solids
Author :
Henz, S. ; Herrmann, I.
Author_Institution :
Max-Born-Inst. fur Nichtlineare Opt. und Kurzeitspektroskopie, Berlin, Germany
Abstract :
Summary form only given.We present a numerical study of the spatio-temporal evolution of femtosecond pulses in dielectric solids. In solids the role of the group-velocity dispersion (GVD) is more dominant, and the characteristic parameters for the optical Kerr effect as well as for the multiphoton ionization differ by some orders of magnitude in comparison to those in gases. Despite these distinct physical conditions, the results of our numerical investigation show the possibility of self-channeling of high-peak power femtosecond pulses with powers somewhat above the critical power of self-focusing. We consider the case that multiphoton ionization dominates compared with the tunneling ionization and where the avalanche ionization plays no significant role because of the shortness of the pulses.
Keywords :
dielectric materials; laser beams; multiphoton processes; optical Kerr effect; optical dispersion; optical pulse compression; photoionisation; avalanche ionization; characteristic parameters; critical power; distinct physical conditions; femtosecond pulses; group-velocity dispersion; high-peak power femtosecond pulses; multiphoton ionization; multiphotonionized dielectric solids; numerical investigation; numerical study; optical Kerr effect; pulse shortening; self-channeling; self-focusing; spatio-temporal evolution; tunneling ionization; Dielectrics; Dispersion; Gases; Ionization; Kerr effect; Nonlinear optics; Optical pulses; Solids; Tunneling; Ultrafast optics;
Conference_Titel :
Quantum Electronics Conference, 1998. IQEC 98. Technical Digest. Summaries of papers presented at the International
Conference_Location :
San Francisco, CA, USA
Print_ISBN :
1-55752-541-2
DOI :
10.1109/IQEC.1998.680507
