受激后向散射中的稳态光脉冲

International Laser Science Conference Pub Date : 2008-06-04 DOI:10.1063/1.36757

D. Roy, D. Rao

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摘要

在速率方程近似失效的极限下分析反向受激光脉冲的特性，必须考虑波动动力学(拉曼振荡位移和布里渊声子振幅)。在此极限下，散射光子通量N s为N s = a(dN l /dt)， (d/dt + γ f) a f = bN l /Af，(d/dt + γ l) = dN l /Af，其中f、/分别指波动和泵浦;波动强度和常数A、b和d取决于介质特性。Maier et al.1给出了这组方程在极限γ f→0和γ l = 0下的解析解。除去这些限制条件后，解析解是困难的。在这里，我们考虑一个解析解，通过将方程组简化为具有实振幅的三次薛定谔方程，并使用Backlund变换。初步计算表明孤波解是可能的(双曲正割平方形式的纯孤子解是不允许的)。

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Steady-state light pulses in stimulated backward scattering

Characteristics of backward, stimulated light pulses are analyzed in the limit where rate equation approximation breaks down, and fluctuation dynamics (oscillator displacements for Raman and phonon amplitudes for Brillouin) must beconsidered. In this limit, the scattered photon flux N s is N s = a(dN l /dt), (d/dt + γ f )A f = bN l /Af,(d/dt + γ l ) = dN l /Af, where f,/referto fluctuations and pump, respectively; A f the fluctuation intensity, and constants a, b, and d depend on the medium characteristics. An analytical solution to this set of equations has been given by Maier et al.1 in the limit γ f →0 and γ l = 0. With these restrictions removed, analytical solution is difficult. Here, we are considering an analytical solution by reducing the set of equations to that of the cubic Schrodinger equation with real amplitude and by using Backlund transform. Preliminary calculations show that the solitary wave solutions are possible (a purely soliton solution is not admissible2 in the form of hyperbolic secant square).

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International Laser Science Conference

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