Radial birefringence in optical resonators

Author

Ferguson, Thomas R.

Author_Institution

Phillips Lab., Kirtland AFB, NM, USA

Volume

33

Issue

1

fYear

1997

fDate

1/1/1997 12:00:00 AM

Firstpage

18

Lastpage

25

Abstract

Paraxial fields polarized in the transverse plane and represented in the polar coordinate system are expanded in an azimuthal Fourier series. For series terms with spiraling phases, the radial and azimuthal components are shown to mix during propagation. For simple rod lasers with thermally induced birefringence, this property may cause the dominant mode to be of mixed polarization rather than purely radial polarization. An explanation is given in terms of the properties of scalar field propagators and the way in which they combine to propagate the vector field components. Comparisons to other recent predictions show that the theory is correct, and the method provides a basis for understanding the complex results

Keywords

Fourier series; birefringence; laser cavity resonators; laser modes; laser theory; light polarisation; solid lasers; thermo-optical effects; azimuthal Fourier series; azimuthal components; dominant mode; mixed polarization; paraxial fields polarisation; polar coordinate system; purely radial polarization; radial birefringence; radial components; rod lasers; scalar field propagators; series terms; spiraling phases; thermally induced birefringence; transverse plane; vector field components; Azimuthal component; Birefringence; Equations; Laser modes; Laser theory; Lenses; Mirrors; Optical polarization; Optical propagation; Optical resonators;

fLanguage

English

Journal_Title

Quantum Electronics, IEEE Journal of

Publisher

ieee

ISSN

0018-9197

Type

jour

DOI

10.1109/3.554869

Filename

554869