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地基激光空间碎片清除等激光烧蚀推进在太空中的应用中, 激光功率已远超过大气非线性自聚焦临界功率, 因此自聚焦效应是影响光束质量的重要因素. 此外, 由于高功率激光产生过程中的非线性效应, 光束常伴有球差. 本文采用数值模拟方法, 研究了球差对高功率激光上行大气传输光束质量的影响. 研究表明: 对于大尺寸(光束发射尺寸)光束, 利用正球差可提高靶面光强. 然而, 对于小尺寸光束, 则需利用负球差提高靶面光强. 并且, 大尺寸比小尺寸光束更适合地基激光空间碎片清除等应用. 在线性衍射效应和非线性自聚焦效应共同作用下, 存在一个最佳发射功率使得靶面光强最大化, 本文拟合出了大尺寸光束的最佳发射功率的公式. 另一方面, 由于衍射、自聚焦和球差均导致焦移, 这使得靶面光束质量变差. 本文推导出了大尺寸光束情况下透镜修正焦距公式, 这样可把将实际焦点移至靶面, 从而提高靶面光束质量. 本文所得结论具有重要的理论和实际应用意义.
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关键词:
- 球差 /
- 非线性自聚焦效应 /
- 高功率激光上行大气传输 /
- 光束质量
For laser ablation propulsion’s applications in space (e.g., space-debris removal, etc.), the laser power is well above the critical power for self-focusing in the atmosphere. Therefore, the self-focusing effect on the beam quality is very significant. In addition, a high-power laser beam is usually accompanied with spherical aberration due to nonlinear effects in its generation process. In this paper, the influence of spherical aberration on the beam quality of high-power laser beams propagating upwards in the atmosphere is studied by using numerical simulation. It is shown that for the large beam size case, the target intensity may be improved by applying the positive spherical aberration. However, for the small beam size case, the target intensity may be improved by using the negative spherical aberration. Furthermore, a laser beam with a large size is more suitable for laser ablation propulsion’s applications in space than that with a small size. Owing to the linear diffraction effect and the nonlinear self-focusing effect, there exists optimal beam power to maximize the target intensity. The formula of the optimal beam power is fitted for the large beam size case in this paper. On the other hand, the focal shift appears due to diffraction, self-focusing and spherical aberration, which results in a degradation of the beam quality on the target. For the large beam size case, to move the actual focus to the target and improve the beam quality on the target, the formula of the modified focal length is also derived in this paper. The results obtained in this paper are of important theoretical significance and practical value.-
Keywords:
- spherical aberration /
- nonlinear self-focusing effect /
- high-power laser beam propagation upwards in the atmosphere /
- beam quality
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[4] Phipps C R 2018 Laser Ablation Propulsion and Its Applications in Space (Switzerland: Springer Cham) pp217−246
[5] Rubenchik A M, Fedoruk M P, Turitsyn S K 2014 Light Sci. Appl. 3 e159Google Scholar
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[13] Dabby F W, Whinnery J R 1968 Appl. Phys. Lett. 13 284Google Scholar
[14] 季小玲, 陶向阳, 吕百达 2004 物理学报 53 952Google Scholar
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Zhao G P, Lü B D 2004 Acta Phys. Sin. 53 2974Google Scholar
[16] 雍康乐, 闫家伟, 唐善发, 张蓉竹 2020 物理学报 69 014201Google Scholar
Yong K L, Yan J W, Tang S F, Zhang Z R 2020 Acta Phys. Sin. 69 014201Google Scholar
[17] 李晓庆, 王涛, 季小玲 2014 物理学报 63 134209Google Scholar
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[26] Phipps C R, Baker K L, Libby S B, Liedahl D A, Olivier S S, Pleasance L D, Rubenchik A M, Trebes J E, George E V, Marcovici B, Reilly J P, Valley M T 2012 Adv. Space Res. 49 1283Google Scholar
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图 2 靶面峰值光强I (r = 0, z = L)随相对发射功率P/PcrGs的变化 (a) 大尺寸光束, w0 = 1.414 m, β = 5.9275; (b) 小尺寸光束: w0 = 0.821 m, β = 1.03
Fig. 2. Peak intensity on the target I (r = 0, z = L) versus the relative beam power P/PcrGs: (a) For a large beam size, w0 = 1.414 m, β = 5.9275; (b) for a small beam size, w0 = 0.821 m, β = 1.03.
图 3 (5)式的验证. 相对最佳发射功率Popt/PcrGs随初始束宽w0和球差系数kC4的变化. 黑点: 数值模拟计算结果, 曲面: (5)式计算结果
Fig. 3. Confirmation of the formula of Eq. (5). Relative optimal beam power Popt/PcrGs versus the initial beam radius. w0 and the spherical aberration coefficient kC4. Black dots: results by using numerical simulation method; surfaces: results by using Eq. (5).
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[1] Kessler D J, Cour-Palais B G 1978 J. Geophys. Res. 83 2637Google Scholar
[2] Esmiller B, Jacquelard C, Eckel H A, Wnuk E 2014 Appl. Opt. 53 I45Google Scholar
[3] Phipps C R, Albrecht G, Friedman H, Gavel D, George E V, Murray J, Ho C, Priedhorsky W, Michaelis M M, Reilly J P 1996 Laser Part. Beams 14 1Google Scholar
[4] Phipps C R 2018 Laser Ablation Propulsion and Its Applications in Space (Switzerland: Springer Cham) pp217−246
[5] Rubenchik A M, Fedoruk M P, Turitsyn S K 2014 Light Sci. Appl. 3 e159Google Scholar
[6] Vaseva I A, Fedoruk M P, Rubenchik A M, Turitsyn S K 2016 Sci. Rep. 6 30697Google Scholar
[7] Zhang Y Q, Ji X L, Zhang H, Li X Q, Wang T, Wang H, Deng Y 2018 Opt. Express 26 14617Google Scholar
[8] Deng Y, Ji X L, Li X Q, Wang H, Huang Z Y, Zhang H 2021 IEEE Photonics J. 13 6500110Google Scholar
[9] Wang H, Ji X L, Deng Y, Li X Q, Wang T, Yu H, Li Q 2019 J. Quant. Spectrosc. Radiat. Transfer 235 244Google Scholar
[10] Fan X L, Ji X L, Wang H, Deng Y, Zhang H 2020 J. Opt. Soc. Am. A: 38 168
[11] Deng Y, Wang H, Ji X L, Li X Q, Yu H, Chen L F 2020 Opt. Express 28 27927Google Scholar
[12] Klein, Claude A 1990 Opt. Eng. 29 343Google Scholar
[13] Dabby F W, Whinnery J R 1968 Appl. Phys. Lett. 13 284Google Scholar
[14] 季小玲, 陶向阳, 吕百达 2004 物理学报 53 952Google Scholar
Ji X L, Tao X Y, Lü B D 2004 Acta Phys. Sin. 53 952Google Scholar
[15] 赵光普, 吕百达 2004 物理学报 53 2974Google Scholar
Zhao G P, Lü B D 2004 Acta Phys. Sin. 53 2974Google Scholar
[16] 雍康乐, 闫家伟, 唐善发, 张蓉竹 2020 物理学报 69 014201Google Scholar
Yong K L, Yan J W, Tang S F, Zhang Z R 2020 Acta Phys. Sin. 69 014201Google Scholar
[17] 李晓庆, 王涛, 季小玲 2014 物理学报 63 134209Google Scholar
Li X Q, Wang T, Ji X L 2014 Acta Phys. Sin. 63 134209Google Scholar
[18] Yoshida A, Asakura T 1996 Opt. Commun. 123 694Google Scholar
[19] Pu J X 1998 J. Mod. Opt. 45 239Google Scholar
[20] Lü B D, Ji X L, Luo S R 2001 J. Mod. Opt. 48 1171Google Scholar
[21] 张翔, 苏礼坤, 蔡青 2010 光学学报 30 802Google Scholar
Zhang X, Su L K, Cai Q 2010 Acta Optic. Sin. 30 802Google Scholar
[22] 蒲继雄 1998 光子学报 27 234Google Scholar
Pu J X 1998 Acta Photonica Sin. 27 234Google Scholar
[23] 苏亚辉, 汪超炜, 韩蒙蒙, 汪金礼, 傅旭川, 代维, 刘畅 2014 光学学报 34 s122005Google Scholar
Su Y H, Wang C W, Hang M M, Wang J L, Fu X C, Dai W, Liu C 2014 Acta Optic. Sin. 34 s122005Google Scholar
[24] Deng H L, Ji X L, Li X Q, Wang X Q 2015 Opt. Lett. 40 3881Google Scholar
[25] Rubenchik A M, Fedoruk M P, Turitsyn S K 2009 Phys. Rev. Lett. 102 233902Google Scholar
[26] Phipps C R, Baker K L, Libby S B, Liedahl D A, Olivier S S, Pleasance L D, Rubenchik A M, Trebes J E, George E V, Marcovici B, Reilly J P, Valley M T 2012 Adv. Space Res. 49 1283Google Scholar
[27] Chekalin S V, Kandidov V P 2013 Phys. Uspekhi 56 123Google Scholar
[28] Pare C, Belanger P A 1992 Opt. Quantum Electron. 24 S1051Google Scholar
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