Suppression of auto-resonant stimulated Brillouin scattering in supersonic flowing plasmas by different forms of incident lasers

S S Ban; Q Wang; Z J Liu; C Y Zheng; X T He

doi:10.1088/1674-1056/ab9c12

1. Introduction

In both direct or indirect inertial confinement, stimulated Brillouin scattering (SBS) is one of the basic problem. [1 - 3] In a homogenous plasma, the absolute growth is easy to be stimulated when the matching condition of three-wave interaction is satisfied. However, in an inhomogeneous plasma the interaction area of SBS is restricted in a small resonant region because the matching conditions can be hardly satisfied. [4 - 6]

Recently, another mechanism in inhamogeneous plasmas, called autoresonance, is investigated, which will stimulate a significant spatial-independent growth of ion acoustic waves (IAWs). The autoresonant occurs because the nonlinear frequency shift compensates the detuning caused by the flow gradient and the SBS remain resonant automatically. [7, 8] The autoresonat behavior of IAWs driven by the SBS process in supersonic flowing plasmas is performed by using the fully kinetic Vlasov code. [9] In those work, the flow velocity decreasing in the forward direction is defined as the “negative flow gradient”, and the flow velocity increasing in the forward direction is defined as the “positive flow gradient”. In the simulations, the stimulated Brillouin backscattering (SBBS) reflectivity in both positive and negative flow gradients reach the level of absolute growth which will scatter the incident light greatly.

In order to suppress the SBS in ICF, several methods have been applied. There are two mechanisms mainly proposed up to date. One is to optimize the uniformity of the incident laser spot such as spatial smoothing, spectral dispersion [10] and polarization smoothing, [11, 12] the other is to decrease the interaction length of SBS such as the spike trains of uneven duration and delay (STUD), [13] alternating-polarization light, [14] polarization rotation [15] and two perpendicular linear polarization. [16] In this article, polarization rotation and two perpendicular linear polarizations are performed to suppress the absolute growth of auto-resonant stimulated Brillouin scattering. To find the effect of them, several simulations are performed by the 1-D Vlasov code [17] and theories associated with them are deduced.

The rest of the article is organized as follows: Theories of autoresonance of SBS and two different incident lights are presented in Section 2 . Simulations based on the fully kinetic Vlasov code are shown in Section 3 . Section 4 provides the conclusions and discussions.

2. Theory

2.1. Autoresonance of SBBS

In inhomogeneous plasmas, the three-wave interaction equations involves a nonlinear kinetic frequency shift in the forms as follows: [8, 18]

$$ \begin{eqnarray}({\partial }_{t}+{v}_{{\rm{g0}}}{\partial }_{x}+{\nu }_{0}){a}_{0}=\frac{-{\rm{i}}}{4}\delta \hat{{n}_{{\rm{e}}}}{a}_{1},\end{eqnarray}$$ (1)

$$ \begin{eqnarray}({\partial }_{t}+{v}_{{\rm{g1}}}{\partial }_{x}+{\nu }_{1}){a}_{1}=\frac{-{\rm{i}}{\omega }_{0}}{4{\omega }_{1}}\delta {\hat{{n}_{{\rm{e}}}}}^{* }{a}_{0},\end{eqnarray}$$ (2)

$$ \begin{eqnarray}\left({\partial }_{t}+{v}_{{\rm{g2}}}{\partial }_{x}+{\nu }_{2}+{\rm{i}}\Delta (x)-{\rm{i}}\eta |\frac{\delta {n}_{{\rm{e}}}}{{n}_{{\rm{e}}}}{|}^{1/2}\right)\delta \hat{{n}_{{\rm{e}}}}={\rm{i}}4{\gamma }_{0}{}^{2}{a}_{0}{a}_{1}{}^{* },\end{eqnarray}$$ (3)

where a₀ = eA₀/m_ec² and a₁ = eA₁/m_ec² are the normalized vector potentials of incident light and the backscattered light; v_g0 = ck₀/ω₀, v_g1 = ck₁/ω₀, v_g2 = (C_s + V)/c are the normalized group velocities of the incident light, backscattered light and IAWs, respectively; ν₂ = γ_LD/ω₀ is the damping rate of IAWs;

δ \hat{n_{e}} = δ n_{e} / n_{c}

is the density amplitude of IAWs. Δ(x) = v_ga[k₀(x) – k₁(x) – k_a(x)] is the spatial detuning, and it can be simplified by Talor expansion at the resonant point Δ(x) = v_g2k’(x – x_r) + v_g2k"(x – x_r) = K’(x – x_r) + K"(x – x_r). Here x_r is the initial resonant point, K’ is defined as K’ = v_g2k’, K" is defined as K" = v_g2k"; and

η | \frac{δ n_{e}}{n_{e}} |^{1 / 2}

is the nonlinear kinetic frequency shift.

It is given as follows:

$$ \begin{eqnarray}\frac{\delta {\omega }_{nl}{}^{{\rm{kin}}}}{{\omega }_{{\rm{a}}}}=-\eta {\left|\frac{\delta {n}_{{\rm{e}}}}{{n}_{{\rm{e}}}}\right|}^{1/2},\end{eqnarray}$$ (4)

$$ \begin{eqnarray}\eta =\frac{1}{\sqrt{2\pi }}\left[{\alpha }_{{\rm{i}}}\sqrt{\frac{Z{T}_{{\rm{e}}}}{{T}_{{\rm{i}}}}}({v}^{4}-{v}^{2}){{\rm{e}}}^{-\frac{{v}^{2}}{2}}-{\alpha }_{{\rm{e}}}\right].\end{eqnarray}$$ (5)

η | \hat{n_{e}} |

$$ \begin{eqnarray}({\partial }_{t}+{v}_{{\rm{g0}}}{\partial }_{x}+{\nu }_{0}){a}_{0}=\frac{-{\rm{i}}}{4}\delta \hat{{n}_{{\rm{e}}}}{a}_{1},\end{eqnarray}$$ (6)

$$ \begin{eqnarray}({\partial }_{t}+{v}_{{\rm{g1}}}{\partial }_{x}+{\nu }_{1}){a}_{1}=\frac{-{\rm{i}}{\omega }_{0}}{4{\omega }_{1}}\delta {\hat{{n}_{{\rm{e}}}}}^{* }{a}_{0},\end{eqnarray}$$ (7)

$$ \begin{eqnarray}({\partial }_{t}+{v}_{{\rm{g2}}}{\partial }_{x}+{\nu }_{2}+{\rm{i}}{K}^{^{\prime\prime} }(x-{x}_{{\rm{r}}}))\delta \hat{{n}_{{\rm{e}}}}={\rm{i}}4{\gamma }_{0}{}^{2}{a}_{0}{a}_{1}{}^{* }.\end{eqnarray}$$ (8)

Then a temporally growth mode would exist when

Δ = e^{- i π / 4} 2^{- 3 / 2} {(K^{″})}^{1 / 2} {(\frac{γ_{0}^{2}}{v_{g 1} v_{g 2}})}^{- 3 / 4} ≪ 1

.^[19] The convective instability of SBS would turn to the absolute instability. The growth rate can be calculated by

γ = 2 γ_{0} (\frac{{(v_{g 1} v_{g 2})}^{1 / 2}}{v_{g 1} + v_{g 2}}) - (\frac{ν_{1} v_{g 2} + ν_{2} v_{g 1}}{v_{g 1} + v_{g 2}})

when

2 γ_{0} > (\frac{ν_{1}}{v_{g 1}} + \frac{ν_{2}}{v_{g 2}}) {(v_{g 1} v_{g 2})}^{1 / 2}

2.2. Absolute instability in the autoresonance of SBS

γ_{0} = \frac{ω_{pi} v_{os} \sqrt{k_{0}}}{2 \sqrt{2} \sqrt{ω_{0} c_{s}}}

In order to suppress the absolute growth of SBS in an inhomogenous plasma, rotation polarization and two perpendicular linear polarization with different frequencies are performed. For rotation polarization, the incident light is combined by two circle polarization lasers with different frequencies. The linear polarization of the incident light is slowly rotating, and it can be expressed as [15]

$$ \begin{eqnarray}{\boldsymbol A}_{0}={a}_{0}\cos ({\omega }_{0}t)[\cos (\varOmega t)\hat{y}+\sin (\varOmega t)\hat{z}],\end{eqnarray}$$ (9)

where Ω is the frequency difference of these two circle polarization incident lasers. The growth rate of SBS in one direction is

γ_{y, z} = γ \cos (\frac{Ω}{2} t)

As for two perpendicular linear polarizations, the incident light is formed by two linear lasers with different frequencies and their polarizations are perpendicular. This is different from the rotation polarization. The polarization of the incident laser varies between linear and ellipse and can be described exactly in theory.

$$ \begin{eqnarray}{\boldsymbol A}_{0}={\boldsymbol A}_{y}+{\boldsymbol A}_{z}=\frac{{a}_{0}}{\sqrt{2}}{{\rm{e}}}^{{\rm{i}}({k}_{1}x-{\omega }_{1}t)}\hat{y}+\frac{{a}_{0}}{\sqrt{2}}{{\rm{e}}}^{{\rm{i}}({k}_{2}x-{\omega }_{2}t)}\hat{z},\end{eqnarray}$$ (10)

where A_y, A_z, ω₁, ω₂, k₁, and k₂ are the vector potential, frequency, wave vector of incident lights with the polarization in y and z directions. The frequency difference Ω is defined as Ω = ω₁ – ω₂. The growth rate of SBS in one direction is

γ_{y, z} = γ \cos (\frac{Ω}{2} t)

, the same as rotation polarization, and the reflectivity of SBS can be calculated by the time average of γ_y,z in the growth time t_sat

$$ \begin{eqnarray}{I}_{{R}_{\varOmega }}={I}_{{\rm{seed}}}{{\rm{e}}}^{{\gamma }_{y}{t}_{{\rm{sat}}}},\end{eqnarray}$$ (11)

I_{Ω = 0} and I_seed are the intensity of backscattering light when Ω = 0 and the seed light, respectively.

The time average of γ y, z in the growth time t sat can be calculated by

$$ \begin{eqnarray}\bar{{\gamma }_{y}}=\gamma \displaystyle {\int }_{0}^{{t}_{{\rm{sat}}}}\left|\cos \left(\frac{\varOmega }{2}t\right)\right|.\end{eqnarray}$$ (12)

It can be simplified by the zero point of the cosine function as follows: [16]

$$ \begin{eqnarray}\frac{\overline{{\gamma }_{y}}}{\gamma }=\left\{\begin{array}{c}\frac{\sin \left(\frac{\varOmega }{2}{t}_{{\rm{sat}}}\right)}{\left(\frac{\varOmega }{2}{t}_{{\rm{sat}}}\right)},\frac{\varOmega }{2}\lt \frac{\pi }{2}\frac{1}{{t}_{{\rm{sat}}}},\\ \frac{4}{\pi }\frac{\frac{\pi }{2}{t}_{{\rm{sat}}}}{\frac{\varOmega }{2\pi }}-\frac{\sin \left(\frac{\varOmega }{2}{t}_{{\rm{sat}}}\right)}{\left(\frac{\varOmega }{2}{t}_{{\rm{sat}}}\right)},\,\frac{\pi }{2}\frac{1}{{t}_{{\rm{sat}}}}\le \frac{\varOmega }{2}\lt 3\frac{\pi }{2}\frac{1}{{t}_{{\rm{sat}}}},\\ \frac{8}{\pi }\frac{\frac{\pi }{2}{t}_{{\rm{sat}}}}{\frac{\varOmega }{2\pi }}-\frac{\sin \left(\frac{\varOmega }{2}{t}_{{\rm{sat}}}\right)}{\left(\frac{\varOmega }{2}{t}_{{\rm{sat}}}\right)},\,3\frac{\pi }{2}\frac{1}{{t}_{{\rm{sat}}}}\le \frac{\varOmega }{2}\lt 5\frac{\pi }{2}\frac{1}{{t}_{{\rm{sat}}}},\\ \begin{array}{c}\frac{12}{\pi }\frac{\frac{\pi }{2}{t}_{{\rm{sat}}}}{\frac{\varOmega }{2\pi }}-\frac{\sin \left(\frac{\varOmega }{2}{t}_{{\rm{sat}}}\right)}{\left(\frac{\varOmega }{2}{t}_{{\rm{sat}}}\right)},5\frac{\pi }{2}\frac{1}{{t}_{{\rm{sat}}}}\le \frac{\varOmega }{2}\lt 7\frac{\pi }{2}\frac{1}{{t}_{{\rm{sat}}}},\\ \ldots \end{array}\end{array}\right.\end{eqnarray}$$ (13)

3. Simulation

V (x) = c_{s} (\frac{x}{L} - \frac{7}{4})

Figure 1.Plasma flow profiles (orange-dashed lines) with the corresponding density profiles (blue-solid lines) of the positive flow gradient used in simulations.

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In the simulations, the amplitude of incident laser is a 0 = 0.015 and the seed light is introduced from the right boundary with the same frequency as the incident laser, and its amplitude is set to be a 1 (x = L) = 0.01 a 0 to eliminate interference of the reflected light (0.001 a 0) at the right boundary. The electron and ion temperatures are T e = 1.5 keV and T i = 0.5 keV. The ion charge and mass are Z = 2 and m i = 7344 m e . Thus, ZT e / T i = 6, the negative kinetic nonlinear frequency shift due to ion trapping would be dominant. Here x r = 300 λ 0 is the initial resonant point where the plasma flow is V (x r) = - C s = 1.15 \times 10 -3 c, plasma density is n e = 0.1 n c and kλ De = 0.33.

At the initial resonant point, the frequency of IAWs in the homogeneous plasmas is ω a = 2.1 \times 10 -3 ω 0 and the growth rate of SBS is γ 0 / ω 0 = 0.054 a 0 . Then, the Rosenbluth gain of SBS in the presence of the normalized amplitude of the pump can be obtained by the first Talor expansion of spatial detuning K 7#x0027;

$$ \begin{eqnarray}{G}_{{\rm{r}}}=\frac{{\gamma }_{0}^{2}}{{v}_{{\rm{g1}}}{v}_{{\rm{g2}}}{K}^{^{\prime} }}.\end{eqnarray}$$ (14)

For backscattering of SBS under the condition in the simulation, we have

$$ \begin{eqnarray}{K}^{^{\prime} }=\left[\frac{1+M}{2M}\frac{\hat{{n}_{{\rm{e}}}}}{1-\hat{{n}_{{\rm{e}}}}}+1\right]\frac{{\omega }_{{\rm{a}}}}{{v}_{{\rm{g2}}}{L}_{v}}\approx \frac{{\omega }_{{\rm{a}}}}{{v}_{{\rm{g2}}}{L}_{v}}.\end{eqnarray}$$ (15)

G_{SBS} \approx \frac{γ_{0}^{2} L_{v}}{v_{g 1} ω_{a}} = 2.34 \times 10^{- 4} a_{0}^{2}

For backscattering of SRS,

$$ \begin{eqnarray}{K}^{^{\prime} }=\frac{{\omega }_{{\rm{pe}}}^{2}}{6{k}_{0}{L}_{{\rm{n}}}{v}_{{\rm{e}}}^{2}}\left(\frac{1}{2}-\frac{6{v}_{{\rm{e}}}^{2}}{{c}^{2}}\right),\end{eqnarray}$$ (16)

$$ \begin{eqnarray}{G}_{{\rm{SRS}}}\approx {\left(\frac{{v}_{{\rm{os}}}}{c}\right)}^{2}{k}_{0}{L}_{{\rm{n}}},\end{eqnarray}$$ (17)

where L_n is the scale length of density gradient and it is defined as L_n = n_e/(∂ n_e/∂ x). Because

\frac{G_{SRS}}{G_{SBS}} \approx 4 \frac{{(ω_{i})}^{2}}{{(ω_{pi})}^{2}} = 4 \frac{m_{i}}{m_{e}} \frac{{(ω_{i})}^{2}}{{(ω_{pe})}^{2}} ≪ 1

, the growth of SRS in the expanding inhomogeneous plasma can be ignored.

In the simulations, with specific parameters G r = 5.27 and γ 0 = 8.1 \times 10 -4 ω 0, the theoretical reflectivity of SBS can be predicted to be about 0.018, and the growth time of SBBS is about 2000 T 0 .

The reflectivity variation of SBS is shown in Fig. 2 . Obviously, the reflectivity of SBBS is consistent with the Rosenbluth gain at first but turn to be about 0.15 after about 15000 T 0 . Another simulation under the same condition of the resonant point while n e = 0.1 n c in all the simulation box is performed, and it is shown in Fig. 3 . Because of the existance of SRS, SBBS grows up after about 6000 T 0 . The absolute growth reflectivity of SBBS in the homogeneous plasma is about 0.2. With the similar absolute growth processes, the wave-wave interaction in the resonant region in the inhomogeneous plasma when the growth turns to be the absolute growth can be deduced based on the equations in the homogeneous plasma.

Figure 2.Reflectivity of autoresonant SBS taken from the Vlasov simulations. The small graph shows the reflectivity and its average value when SBS saturates.

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Figure 3.Reflectivity of SBS in the homogeneous plasma when n_e = 0.1n_c.

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\hat{y}

Figure 4.Reflectivity versus polarization rotation frequency when Ω/ω₀ = 0.00002, 0.0001, 0.0004, 0.0008.

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\hat{y}

\hat{y}

Figure 5.Reflectivity versus the frequency difference by two perpendicular linear polarizations with different frequencies when Ω/ω₀ = 0.0001, 0.0002, 0.0004, 0.0013.

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The physical mechanism of the two perpendicular linear polarizations is similar with the rotation polarization, but the polarization of the incident light varies between linear and ellipse instead of rotating around the x axis. Similarly, when Ω is small, most of the incident light is of linear polarization in y or z direction, and the SBBS will be enhanced till the saturation. When Ω becomes larger, SBBS will be suppressed because of the reduction of the incident light which matches the wave-wave equations. Saturation will appear when the Ω is large enough for several linear-ellipse cycles involved in the same growth interval.

\frac{π}{2} \frac{1}{t_{sat}} = 0.0004 ω_{0}

Figure 6.Reflectivity versus the frequency difference for different forms of incident lasers.

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Meanwhile, there are also some differences. The reflectivity by rotation polarization is suppressed faster and the minimum reflectivity is slightly smaller than the reflectivity of two perpendicular linear polarizations with different frequencies. In addition, for rotation polarization, the reflectivity of SBS has periodic oscillations because of the periodic oscillations of incident light. For two perpendicular linear polarizations with different frequencies, there is not any periodic oscillation in the reflectivity because of the constant amplitude of the incident light in y or z direction.

4. Conclusion

In summary, two different incident lights are performed to suppress the absolute instability caused by the auto-resonance of SBS. The suppression is obviously by adopting both methods with the increase of frequency difference. The reflectivity of SBBS decreases monotonically when Ω is small and reaches the saturation when Ω / ω 0 = 10 -3 under the condition of the simulation parameters with the increase of frequency difference. Considering that only two linear polarization lights are required by the method of two perpendicular linear polarizations, this method can be more conveniently used in experiment although the minimum of reflectivity by rotation polarization is slightly smaller.

Moreover, the reflectivity of convection growth of SBS is also suppressed in the simulations, it requires more further work to verify the suppression by different forms of incident lights.