TY - GEN
T1 - Compositional tuning of glass for the suppression of nonlinear and parasitic fiber laser phenomena
AU - Dragic, Peter D.
AU - Ballato, John
AU - Hawkins, Thomas
PY - 2014
Y1 - 2014
N2 - Fiber lasers are susceptible to a number of nonlinear and parasitic effects that can significantly inhibit performance. From a system perspective, requirements of a fiber laser may cover average or peak power, amplitude stability, and spectral content of the source. Nonlinear and parasitic phenomena, including Brillouin scattering, Raman scattering, mode stability, self-phase modulation, four-wave mixing in multi-wavelength lasers, etc. can each influence one or all of these performance characteristics. Conventionally, these system-limiting undesirables have been addressed with complex waveguide designs. However, each of these light-medium interactions can be described by material coefficients that lead to estimates of 'threshold' values where these phenomena become significant. For example, this may be the Brillouin gain coefficient for Brillouin scattering, the nonlinear refractive index, n 2, for self-phase modulation, or the thermo-optic coefficient, dn/dT, for mode stability. Furthermore, these coefficients tend to be strong functions of the material, and surprisingly wide ranges of values exist between known material systems. For example, both the Pockels' photoelastic constant, p 12, and thermo-optic coefficient may be either positive or negative for a material. It follows logically that mixtures of materials with coefficients of opposing signs would then give rise to compositions where these coefficients may be zero. Example of such effect negation may include the barium aluminosilicate system for p12 and the phosphosilicate or titanosilicate system for dn/dT. Compositional tailoring of the optical fiber is therefore suggested as an alternative means to suppressing these parasitics, and methods to do so will be discussed at the conference.
AB - Fiber lasers are susceptible to a number of nonlinear and parasitic effects that can significantly inhibit performance. From a system perspective, requirements of a fiber laser may cover average or peak power, amplitude stability, and spectral content of the source. Nonlinear and parasitic phenomena, including Brillouin scattering, Raman scattering, mode stability, self-phase modulation, four-wave mixing in multi-wavelength lasers, etc. can each influence one or all of these performance characteristics. Conventionally, these system-limiting undesirables have been addressed with complex waveguide designs. However, each of these light-medium interactions can be described by material coefficients that lead to estimates of 'threshold' values where these phenomena become significant. For example, this may be the Brillouin gain coefficient for Brillouin scattering, the nonlinear refractive index, n 2, for self-phase modulation, or the thermo-optic coefficient, dn/dT, for mode stability. Furthermore, these coefficients tend to be strong functions of the material, and surprisingly wide ranges of values exist between known material systems. For example, both the Pockels' photoelastic constant, p 12, and thermo-optic coefficient may be either positive or negative for a material. It follows logically that mixtures of materials with coefficients of opposing signs would then give rise to compositions where these coefficients may be zero. Example of such effect negation may include the barium aluminosilicate system for p12 and the phosphosilicate or titanosilicate system for dn/dT. Compositional tailoring of the optical fiber is therefore suggested as an alternative means to suppressing these parasitics, and methods to do so will be discussed at the conference.
KW - Brillouin scattering
KW - Raman scattering
KW - fiber lasers
KW - higher order mode instability
KW - nonlinear fiber optics
KW - novel fabrication techniques
KW - optical fiber design
KW - optical fiber materials
KW - photoelastic constant
KW - pulsed amplifiers
KW - rare earth doped fibers
KW - specialty optical fibers
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U2 - 10.1117/12.2052959
DO - 10.1117/12.2052959
M3 - Conference contribution
AN - SCOPUS:84904761130
SN - 9781628410181
T3 - Proceedings of SPIE - The International Society for Optical Engineering
BT - Laser Technology for Defense and Security X
PB - SPIE
T2 - Laser Technology for Defense and Security X
Y2 - 6 May 2014 through 7 May 2014
ER -