Title :
Polarization states of a single-mode (microchip) Nd3+:YAG laser. I. Theory
Author :
Dalgliesh, R. ; May, A.D. ; Stéphan, G.
Author_Institution :
Dept. of Phys., Toronto Univ., Ont., Canada
fDate :
8/1/1998 12:00:00 AM
Abstract :
We present a microscopic mathematical model for the polarization states of a single-frequency Nd3+:YAG laser. It is a plane wave, mean field, vector model carried to all orders in the laser field. The crystal is assumed to be optically pumped longitudinally with a laser of specified polarization. For D2 site symmetry and an odd number of electrons, we establish the phase relationships between the components of the electric dipole matrix elements between the Kramers states. These relationships are central in determining the site-specific coupling between both, the pump and laser fields to the Nd 3+ ions. The laser cavity is assumed to be linear and quasi-isotropic. The residual optical anisotropies are included using a round-trip Jones matrix formalism
Keywords :
laser frequency stability; laser modes; light polarisation; matrix algebra; neodymium; optical bistability; optical pumping; solid lasers; symmetry; D2 site symmetry; Kramers states; YAG:Nd; YAl5O12:Nd; electric dipole matrix elements; laser field; laser fields; laser pumping; laser theory; mean field; microscopic mathematical model; odd number; optically pumped; plane wave; polarization states; single-frequency Nd3+:YAG laser; single-mode microchip Nd3+:YAG laser; site-specific coupling; specified polarization; vector model; Electron optics; Laser excitation; Laser modes; Mathematical model; Microchip lasers; Microscopy; Neodymium; Optical polarization; Optical pumping; Pump lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
