图 1  不同等离子体密度下的自聚焦临界功率$P_{\mathrm{c}}^{(m)}$与拓扑荷数m的关系曲线

Fig. 1.  The relationship between the critical power for self-focusing $P_{\mathrm{c}}^{(m)}$and the topological charge m at different plasma densities

图 2  不同功率下${\text{L}}G_0^4$涡旋光束峰值光强随传输距离变化的模拟对比图　(a)$P = P_{\rm{c}}^{(4)} ;$ (b)$P = 5 P_{\rm{c}}^{(4)} ;$ (c)$P = 6 P_{\rm{c}}^{(4)} ;$ (d)$P = 7 P_{\rm{c}}^{(4)}$

Fig. 2.  Normalized maximum intensity of vortex beams with different input powers versus propagation distance for ${m}=4$: (a)$P = P_{\rm{c}}^{(4)} ;$ (b)$P = 5 P_{\rm{c}}^{(4)} ;$ (c)$P = 6 P_{\rm{c}}^{(4)} ;$ (d)$P = $$ 7 P_{\rm{c}}^{(4)}$

图 3  不同功率下涡旋光束传输至不同位置的光强横向分布图　(a)—(c) $P = 5 P_{\mathrm{c}}^{(4)}$; (d)—(f) $P = 6 P_{\mathrm{c}}^{(4)}$; (g)—(i) $P = $$ 7 P_{\mathrm{c}}^{(4)}$

Fig. 3.  Intensity distribution of vortex beams with different input powers at different positions: (a)–(c) $P = 5 P_{\mathrm{c}}^{(4)}$; (d)–(f) $P = 6 P_{\mathrm{c}}^{(4)}$; (g)–(i) $P = 7 P_{\mathrm{c}}^{(4)}$. The initial parameters are the same as in Fig. 1

图 4  $P = 7 P_{\mathrm{c}}^{(4)}$条件下${\text{L}}{\rm{G}}_0^4$涡旋光束由自聚焦过程向成丝过程演化的三维光强分布图

Fig. 4.  Evolution of the self-focusing and filament formation of a vortex beam as a function of propagation distance, where ${m}=4$ and $P \approx 7 P_{\rm{c}}^{(4)}$ are taken

图 5  $P=10 P_{\rm{c}}^{(4)}$, $15 P_{\rm{c}}^{(4)}$两组参数下${\text{L}}{\rm{G}}_0^4$涡旋光束成丝现象的模拟结果　(a)—(c) $P = 10 P_{\mathrm{c}}^{(4)}$; (d)—(f) $P = 15 P_{\mathrm{c}}^{(4)}$

Fig. 5.  Filament formation of the vortex beams that has different high powers: (a)–(c) $P = 10 P_{\mathrm{c}}^{(4)}$; (d)–(f) $P = 15 P_{\mathrm{c}}^{(4)}$, where ${m}=4$ are taken

图 6  ${\text{L}}{\rm{G}}_0^2$模、${\text{L}}{\rm{G}}_0^6$模涡旋光束成丝现象的模拟结果对比图　(a)—(c)$m=2, P = 5 P_{\mathrm{c}}^{(2)} $; (d)—(f) $m=6, P = 7 P_{\mathrm{c}}^{(7)} $

Fig. 6.  Evolution of vortex beams with different values of the topological charge when the initial power is just enough to generate filaments: (a)–(c)$m=2, P = 5 P_{\mathrm{c}}^{(2)} $; (d)–(f) $m=6, P = 7 P_{\mathrm{c}}^{(7)} $