图 1  (14) 式实色散频率随着波数k和漂移速度v的变化, $\theta = {{\text{π}}}/{3}$, 对应的其他参量见(11)式

Fig. 1.  Variation of the real dispersion frequency with the wave number k and drift velocity v determined by Eq. (14) for $\theta = {{\text{π}}}/{3}$. Other parameters are given in Eq. (11).

图 2  (14)式实色散频率随着波数k和倾斜角$ \theta $的变化, 对应的参量见(11)式

Fig. 2.  Variation of the real dispersion frequency with the wave number k and obliqueness angle $ \theta $ determined by Eq. (14), and the parameters given in Eq. (11).

图 3  (14)式实色散频率随着波数k和尘埃密度$n_{\rm d}$的变化, $\theta = {{\text{π}}}/{3}$, 对应的其他参量见(11)式

Fig. 3.  Variation of the real dispersion frequency with the wave number k and the dust density $n_{\rm d}$ determined by Eq. (14) for $\theta = {{\text{π}}}/{3}$. Other parameters are given in Eq. (11).

图 4  (14)式实色散频率随着波数k和磁场强度$ B_0 $的变化, $\theta = {{\text{π}}}/{3}$, 对应的其他参量见(11)式

Fig. 4.  Variation of the real dispersion frequency with the wave number k and magnetic field $ B_0 $ determined by Eq. (14) for $\theta = {{\text{π}}}/{3}$. Other parameters are given in Eq. (11).

图 5  (15)式虚色散频率随着波数k和碰撞频率$ \nu_{\rm {dn}} $的变化, $\theta = {{\text{π}}}/{3}$, 对应的其他参量见(11)式

Fig. 5.  Variation of the imaginary dispersion frequency with the wave number k and the collision frequency $ \nu_{\rm {dn}} $ determined by Eq. (15) for $\theta = {{\text{π}}}/{3}$. Other parameters are given in Eq. (11).

图 6  (18)式冲击波$ \varPhi_1 $随着尘埃密度$ n_{\rm d} $的变化. 对应的参量为$ k_{2} = 10 $, $ k_{3} = 1 $, 其他参量见(11)式

Fig. 6.  Variation of the shock wave $ \varPhi_1 $ with the dust density $ n_{\rm d} $ by Eq.(18) for $ k_{2} = 10 $, $ k_{3} = 1 $. Other parameters are given in Eq. (11).

图 7  (18)式冲击波$ \varPhi_1 $随着碰撞频率$ \nu_{\rm {dn}} $的变化. 对应的参量为$ k_{2} = 10 $, $ k_{3} = 2 $, 其他参量见(11)式

Fig. 7.  Variation of the shock wave $ \varPhi_1 $ with the collision frequency $ \nu_{\rm {dn}} $ by Eq.(18) for $ k_{2} = 10 $, $ k_{3} = 2 $. Other parameters are given in Eq. (11).

图 8  (18)式冲击波$ \varPhi_1 $随着漂移速度v的变化. 对应的参量为$ k_{2} = 5 $, $ k_{3} = 2 $, 其他参量见(11)式

Fig. 8.  Variation of the shock wave $ \varPhi_1 $ with the drift velocity v by Eq.(18) for $ k_{2} = 5 $, $ k_{3} = 2 $. Other parameters are given in Eq. (11).

图 9  (18)式冲击波$ \varPhi_1 $随着磁场强度$ B_0 $的变化. 对应的参量为$ k_{2} = 10 $, $ k_{3} = 1 $, 其他参量见(11)式

Fig. 9.  Variation of the shock wave $ \varPhi_1 $ with the magnetic field $ B_0 $ by Eq.(18) for $ k_{2} = 10 $, $ k_{3} = 1 $. Other parameters are given in Eq. (11).

图 10  (19)式爆炸波$ \varPhi_2 $随着尘埃密度$ n_{\rm d} $的变化. 对应的参量为$ k_{2} = 2 $, $ k_{3} = 1 $, $ n_{\rm d} = 1.2\times10^{18}{\ \rm{cm}^{-3}} $ (实线), $ n_{\rm d} = 1.4\times10^{18}{\ \rm{cm}^{-3}} $(虚线), 其他参量见(11)式

Fig. 10.  Profile of the explosive wave $ \varPhi_2 $ by Eq. (19) with $ k_{2} = 2 $, $ k_{3} = 1 $, $ n_{\rm d} = 1.2\times10^{18}{\ \rm{cm}^{-3}} $ (solid line), and $ n_{\rm d} = 1.4\times10^{18}{\ \rm{cm}^{-3}} $ (dash line). Other parameters are given in Eq. (11).

图 11  (19)式爆炸波$ \varPhi_2 $随着碰撞频率$ \nu_{\rm {dn}} $的变化. 对应的参量为$ k_{2} = 2 $, $ k_{3} = 1 $, $ \nu_{\rm {dn}} = 10^{6}\ \rm{Hz} $(实线), $ \nu_{\rm {dn}} = 3\times 10^{6}\ \rm{Hz} $(虚线), 其他参量见(11)式

Fig. 11.  Profile of the explosive wave $ \varPhi_2 $ given by Eq. (19) with $ k_{2} = 2 $, $ k_{3} = 1 $, $ \nu_{\rm {dn}} = 10^{6}\ \rm{Hz} $ (solid line), and $ \nu_{\rm {dn}} = 3\times10^{6}\ \rm{Hz} $ (dash line). Other parameters are given in Eq. (11).

图 12  (19)式爆炸波$ \varPhi_2 $随着漂移速度v的变化. 对应的参量为$ k_{2} = 2 $, $ k_{3} = 1 $, $ v = 10^{3}\ \rm{cm/s} $ (实线), $ v = 10^{4}\ \rm{cm/s} $(虚线), 其他参量见(11)式

Fig. 12.  Profile of the explosive wave $ \varPhi_2 $ given by Eq. (19) with $ k_{2} = 2 $, $ k_{3} = 1 $, $ v = 10^{3}\ \rm{cm/s} $ (solid line), and $ v = 10^{4}\ \rm{cm/s} $ (dash line). Other parameters are given in Eq. (11).

图 13  (19)式爆炸波$ \varPhi_2 $随着磁场强度$ B_0 $的变化. 对应的参量为$ k_{2} = 2 $, $ k_{3} = 1 $, $ B_0 = 10^{8}\ \rm{G} $(实线), 和$ B_0 = 3\times 10^{8}\ \rm{G} $(虚线), 其他参量见(11)式

Fig. 13.  Profile of the explosive wave $ \varPhi_2 $ given by Eq. (19) with $ k_{2} = 2 $, $ k_{3} = 1 $, $ B_0 = 10^{8}\ \rm{G} $ (solid line), and $ B_0 = 3\times10^{8}\ \rm{G} $ (dash line). Other parameters are given in Eq. (11).