In this paper, we explore theoretically and experimentally the laser beam shaping ability resulting from the coaxial superposition of two coherent Gaussian beams (GBs). This technique is classified under interferometric laser beam shaping techniques contrasting with the usual ones based on diffraction. The experimental setup does not involve the use of some two-wave interferometer but uses a spatial light modulator for the generation of the necessary interference term. This allows one to avoid the thermal drift occurring in interferometers and gives a total flexibility of the key parameter setting the beam transformation. In particular, we demonstrate the reshaping of a GB into a bottle beam or top-hat beam in the focal plane of a focusing lens.
Reference:
Boubaha, B, Naidoo, D, Godin, T, Fromager, M, Forbes, A and Aït-Ameur, K. 2013. Spatial properties of coaxial superposition of two coherent Gaussian beams. Applied Optics, vol. 52(23), pp 5766-5772
Boubaha, B., Naidoo, D., Godin, T., Fromager, M., Forbes, A., & Aït-Ameur, K. (2013). Spatial properties of coaxial superposition of two coherent Gaussian beams. http://hdl.handle.net/10204/7601
Boubaha, B, Darryl Naidoo, T Godin, M Fromager, A Forbes, and K Aït-Ameur "Spatial properties of coaxial superposition of two coherent Gaussian beams." (2013) http://hdl.handle.net/10204/7601
Boubaha B, Naidoo D, Godin T, Fromager M, Forbes A, Aït-Ameur K. Spatial properties of coaxial superposition of two coherent Gaussian beams. 2013; http://hdl.handle.net/10204/7601.
Copyright: 2013 Optical Society of America. This journal authorizes the publication of the information herewith contained. Published in Applied Optics, vol. 52(23), pp 5766-5772
