搜索

x

留言板

尊敬的读者、作者、审稿人, 关于本刊的投稿、审稿、编辑和出版的任何问题, 您可以本页添加留言。我们将尽快给您答复。谢谢您的支持!

姓名
邮箱
手机号码
标题
留言内容
验证码

热效应作用下高功率薄片涡旋激光器的模场结构

连天虹 窦逸群 周磊 刘芸 寇科 焦明星

引用本文:
Citation:

热效应作用下高功率薄片涡旋激光器的模场结构

连天虹, 窦逸群, 周磊, 刘芸, 寇科, 焦明星

Modal structure of high power thin-disk vortex laser under thermal effect

Lian Tian-Hong, Dou Yi-Qun, Zhou Lei, Liu Yun, Kou Ke, Jiao Ming-Xing
PDF
HTML
导出引用
  • 激光介质热效应引起的谐振腔模场结构变化成为高功率涡旋激光器的一个关键问题. 本文建立了环形光泵浦薄片激光晶体的温度场及热形变计算模型, 将热效应像差作为谐振腔衍射积分方程的微扰, 研究热效应对激光器模场结构的影响规律. 具体研究了Nd:YAG, Nd:YLF和Nd:YVO4薄片涡旋激光器的模场结构随泵浦功率、晶体吸收系数、晶体厚度的变化规律. 研究结果表明, 热效应使涡旋激光器模谱产生径向展宽, 模式纯净度下降. 泵浦功率越大, 高阶径向模式占比越大, 模场结构越复杂. 泵浦功率升高时, Nd:YVO4激光器的模谱展宽最大, Nd:YAG激光器的模谱展宽最小. 晶体吸收系数越大, 模谱展宽越严重; 激光晶体厚度减小时, 模谱展宽呈增宽趋势.
    Optical vortex beam has wide applications in areas of optical communication, lidar detection and optical trapping. To increase the operating distance, a high-power vortex laser source is necessary in these applications. However, the purity of the output vortex beam decreases with the pump power increasing due to the thermal effect of the laser medium. Therefore, modal field degeneration induced by thermal effect of laser medium has become a key problem in high-power vortex solid-state laser. To investigate this modal field degeneration, the heat transfer and thermal deformation model of an annular beam end pumped thin-disk vortex laser (Fig. (a)) is established. The phase difference of the thermal effect is calculated based on this model. Then, the quadratic term is separated from the phase difference. The non-quadratic term, as a small perturbation, is substituted into the diffraction integral equation of the laser cavity. The modal field structure is obtained by using the perturbation method. The variations of the modal structure with pump power, absorption coefficient and crystal thickness are investigated for three kinds of laser crystals, i.e. Nd:YAG, Nd:YLF and Nd:YVO4. The results show that the modal field under thermal effect presents obvious deviation from the ideal mode at high power, and the modal structure shows that it contains many higher-order radial modes, with the angular mode order unchanged. Hence, the radial modal spectrum is broadened by the thermal effect. For an ideal vortex laser without thermal effect operating on the radial mode order 0 and angular mode order 1, Fig. (b) shows the modal structures with thermal effect under different pump power values with a laser crystal thickness of 1 mm. The ratio of the higher-order modes increases and the modal structure becomes more and more complex with the pump power increasing. The ratios of the ideal mode are 0.99, 0.97, 0.90, 0.79 and 0.61, under the pump power of 10 W, 20 W, 40 W, 60 W and 100 W, respectively. Moreover, the Nd:YVO4 laser has the largest and the Nd:YAG laser has the smallest modal spectrum broadening under the same pump power. Figure (c) shows the variation of the modal purity with the pump power. The modal purity of the Nd:YVO4 and the Nd:YLF laser decrease to 0.35 and 0.44 at the pump power of 100 W, respectively. We also investigate the modal structures under different absorption coefficients and crystal thickness values. A larger absorption coefficient or a smaller crystal thickness leads to a larger radial modal spectrum broadening and a smaller modal purity. These results indicate that in the design of high-power thin-disk vortex laser, it is necessary to comprehensively optimize the disk thickness and the absorption coefficient, and consider modal spectrum broadening as well.
      通信作者: 连天虹, tianhongl@126.com
    • 基金项目: 国家自然科学基金(批准号: 61805196, 51875455)资助的课题.
      Corresponding author: Lian Tian-Hong, tianhongl@126.com
    • Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 61805196, 51875455).
    [1]

    Wang J, Yang J Y, Fazal I M, et al. 2012 Nat. Photonics 6 488Google Scholar

    [2]

    Gibson G, Courtial J, Padgett M J, Vasnetsov M, Pas’ko V, Barnett S M, Franke-Arnold S, 2004 Opt. Express 12 5448Google Scholar

    [3]

    Willner A E, Zhao Z, Ren Y X, Li L, Xie G D, Song H Q, Liu C, Zhang R Z, Bao C J, Pang K 2018 Opt. Commun. 408 21Google Scholar

    [4]

    Lavery M P J, Speirits F C, Barnett S M, Padgett M J 2013 Science 341 537Google Scholar

    [5]

    Belmonte A, Rosales-Guzman C, Torres J P 2015 Optica 2 1002Google Scholar

    [6]

    杨伟东, 邱晓东, 陈理想 2020 中国激光 47 0500013Google Scholar

    Yang W D, Qiu X D, Chen L X 2020 Chin. J. Lasers 47 0500013Google Scholar

    [7]

    杨苏辉, 廖英琦, 林学彤, 刘欣宇, 齐若伊, 郝燕 2021 红外与激光工程 50 20211040Google Scholar

    Yang S H, Liao Y Q, Lin X T, Liu X Y, Qi R Y, Hao Y 2021 Infrared Laser Eng. 50 20211040Google Scholar

    [8]

    Jantzi A, Jemison W, Laux A, Mullen L, Cochenour B 2018 Opt. Express 26 2668Google Scholar

    [9]

    Baghdady J, Miller K, Morgan K, et al. 2016 Opt. Express 24 9794Google Scholar

    [10]

    Shen Y J, Wang X J, Xie Z W, Min C J, Fu X, Liu Q, Gong M L, Yuan X C 2019 Light Sci. Appl. 8 90Google Scholar

    [11]

    柳强, 潘婧, 万震松, 申艺杰, 张恒康, 付星, 巩马理 2020 中国激光 47 0500006Google Scholar

    Liu Q, Pan J, Wan Z S, Shen Y J, Zhang H K, Fu X, Gong M L 2020 Chin. J. Lasers 47 0500006Google Scholar

    [12]

    Forbes A 2019 Laser Photonics Rev. 13 1900140Google Scholar

    [13]

    Forbes A, Oliveira M D, Dennis M R 2021 Nat. Photonics 15 253Google Scholar

    [14]

    孙喜博, 朱启华, 刘兰琴, 黄晚晴, 张颖, 王文义, 耿远超 2017 激光与光电子学进展 54 070001Google Scholar

    Sun X B, Zhu Q H, Liu L Q, Huang W Q, Zhang Y, Wang W Y, Geng Y C 2017 Laser Optoelectron. P. 54 070001Google Scholar

    [15]

    付时尧, 高春清 2019 光学学报 39 0126014Google Scholar

    Fu S Y, Gao C Q 2019 Acta Opt. Sin. 39 0126014Google Scholar

    [16]

    常宁, 金立伟, 高玮 2019 光学学报 39 0319001Google Scholar

    Chang N, Jin L W, Gao W 2019 Acta Opt. Sin. 39 0319001Google Scholar

    [17]

    Zhao Y G, Chen B, Zheng C S, Jia D W, Dong J F, Guo J, Wang Z X, Yu H H, Zhang H J 2024 Laser Photonics Rev. 18 2301089Google Scholar

    [18]

    Pan J, Shen Y J, Wan Z S, Fu X, Zhang H K, Liu Q 2020 Phys. Rev. Appl. 14 044048Google Scholar

    [19]

    Zhao Y G, Wang L, Chen W D, et al. 2021 Photonics Res. 9 357Google Scholar

    [20]

    Qiao Z, Xie G Q, Wu Y H, Yuan P, Ma J G, Qian L J, Fan D Y 2018 Laser Photonics Rev. 12 1800019Google Scholar

    [21]

    宋小鹿, 李兵斌, 王石语, 蔡德芳, 文建国, 过振 2008 红外与激光工程 37 73Google Scholar

    Song X L, Li B B, Wang S Y, Cai D F, Wen J G, Guo Z 2008 Infrared Laser Eng. 37 73Google Scholar

    [22]

    姚育成, 刘丹琳, 黄楚云, 徐国旺, 王贝 2016 光子学报 45 131Google Scholar

    Yao Y C, Liu D L, Huang C Y, Xu G W, Wang B 2016 Acta Photonica Sin. 45 131Google Scholar

    [23]

    方洪烈 2014 光学谐振腔与引力波探测 (北京: 科学出版社) 第78—80页

    Fang H L 2014 Optical Resonators and Gravitational Wave Detection (Beijing: Science Press ) pp78–80

    [24]

    Koechner W 2013 Solid-State Laser Engineering (New York: Springer) pp46–83

  • 图 1  环形光端面泵浦薄片涡旋激光器结构

    Fig. 1.  Schematic of an annular beam end pumped thin-disk vortex laser.

    图 2  Nd:YAG温度和热形变分布 (a)三维温度分布; (b)三维热形变分布; (c)剖面温度; (d)剖面形变

    Fig. 2.  Temperature and thermal deformation of Nd:YAG crystal: (a) 3D temperature distribution; (b) 3D deformation distribution; (c) temperature in the section plane; (d) deformation in the section plane.

    图 3  不同泵浦功率下3种晶体的温度及热形变 (a) Nd:YAG温度; (b) Nd:YAG形变; (c) Nd:YLF温度; (d) Nd:YLF形变; (e) Nd:YVO4温度; (f) Nd:YVO4形变

    Fig. 3.  Temperature and thermal deformation of the three laser crystals under different pump power: (a) Temperature of Nd:YAG; (b) deformation of Nd:YAG; (c) temperature of Nd:YLF; (d) deformation of Nd:YLF; (e) temperature of Nd:YVO4; (f) deformation of Nd:YVO4.

    图 4  温度及热形变随泵浦功率的变化 (a) 最高温度; (b) 最高温度与中心温差; (c) 最大热形变; (d) 最大热形变与中心热形变差

    Fig. 4.  Variation of temperature and thermal deformation with pump power: (a) Maximum temperature; (b) difference between the maximum temperature and the center temperature; (c) maximum thermal deformation; (d) difference between the maximum thermal deformation and the center thermal deformation.

    图 5  不同泵浦功率下的模场分布和模谱结构 (a) Nd:YAG模场; (b) Nd:YAG模谱; (c) Nd:YLF模场; (d) Nd:YLF模谱; (e) Nd:YVO4模场; (f) Nd:YVO4模谱

    Fig. 5.  Mode distribution and mode structure under different pump power: (a) Nd:YAG mode distribution; (b) Nd:YAG mode structure; (c) Nd:YLF mode distribution; (d) Nd:YLF mode structure; (e) Nd:YVO4 mode distribution; (f) Nd:YVO4 mode structure.

    图 6  模式纯净度随泵浦功率的变化

    Fig. 6.  Variation of the modal purity with pump power.

    图 7  不同吸收系数下3种晶体的温度及形变 (a) Nd:YAG温度; (b) Nd:YAG形变; (c) Nd:YLF温度; (d) Nd:YLF形变; (e) Nd:YVO4温度; (f) Nd:YVO4形变

    Fig. 7.  Temperature and deformation of the three laser crystals under different absorption coefficient: (a) Temperature of Nd:YAG; (b) deformation of Nd:YAG; (c) temperature of Nd:YLF; (d) deformation of Nd:YLF; (e) temperature of Nd:YVO4; (f) deformation of Nd:YVO4.

    图 8  温度及热形变随吸收系数的变化 (a) 最高温度; (b) 最高温度与中心温度差值; (c) 最大热形变; (d) 最大热形变与中心热形变差值

    Fig. 8.  Variation of temperature and thermal deformation with absorption coefficient: (a) Maximum temperature; (b) difference between the maximum temperature and the center temperature; (c) maximum thermal deformation; (d) difference between the maximum thermal deformation and the center thermal deformation.

    图 9  不同吸收系数下的模场分布和模谱结构 (a) Nd:YAG模场; (b) Nd:YAG模谱; (c) Nd:YLF模场; (d) Nd:YLF模谱; (e) Nd:YVO4模场; (f) Nd:YVO4模谱

    Fig. 9.  Mode distribution and mode structure under different absorption coefficient: (a) Nd:YAG mode distribution; (b) Nd:YAG mode structure; (c) Nd:YLF mode distribution; (d) Nd:YLF mode structure; (e) Nd:YVO4 mode distribution; (f) Nd:YVO4 mode structure.

    图 10  模式纯净度随吸收系数的变化

    Fig. 10.  Variation of the modal purity with absorption coefficient.

    图 11  不同厚度下3种晶体的温度及热形变 (a) Nd:YAG温度; (b) Nd:YAG形变; (c) Nd:YLF温度; (d) Nd:YLF形变; (e) Nd:YVO4温度; (f) Nd:YVO4形变

    Fig. 11.  Temperature and thermal deformation of the three laser crystals under different crystal thickness: (a) Temperature of Nd:YAG; (b) deformation of Nd:YAG; (c) temperature of Nd:YLF; (d) deformation of Nd:YLF; (e) temperature of Nd:YVO4; (f) deformation of Nd:YVO4.

    图 12  温度及热形变随晶体厚度的变化 (a) 最高温度; (b) 最高温度与中心温度差值; (c) 最大热形变; (d) 最大热形变与中心热形变差值

    Fig. 12.  Variation of temperature and thermal deformation with crystal thickness: (a) Maximum temperature; (b) difference between the maximum temperature and the center temperature; (c) maximum thermal deformation; (d) difference between the maximum thermal deformation and the center thermal deformation.

    图 13  不同厚度下的模场分布和模谱结构 (a) Nd:YAG模场; (b) Nd:YAG模谱; (c) Nd:YLF模场; (d) Nd:YLF模谱; (e) Nd:YVO4模场; (f) Nd:YVO4模谱

    Fig. 13.  Mode distribution and mode structure under different thickness: (a) Nd:YAG mode distribution; (b) Nd:YAG mode structure; (c) Nd:YLF mode distribution; (d) Nd:YLF mode structure; (e) Nd:YVO4 mode distribution; (f) Nd:YVO4 mode structure.

    图 14  模式纯净度随晶体厚度的变化

    Fig. 14.  Variation of modal purity with crystal thickness.

    表 1  激光晶体参数[24]

    Table 1.  Parameters of laser crystals[24].

    激光晶体 密度/
    (kg·m–3)
    杨氏模量/GPa 泊松比 热膨胀系数/K–1 热导率/
    (W·m–1·K–1)
    $ {{{\text{d}}n} \mathord{\left/ {\vphantom {{{\text{d}}n} {{\text{d}}T}}} \right. } {{\text{d}}T}} $/K–1
    Nd:YAG 4560 317 0.25 7.5×106 14 7.3×10–6
    Nd:YLF 3990 85 0.33 8.3×106 6.3 –6.6×10–6
    Nd:YVO4 4220 133 0.33 4.43×106 5.2 8.5×10–6
    下载: 导出CSV
  • [1]

    Wang J, Yang J Y, Fazal I M, et al. 2012 Nat. Photonics 6 488Google Scholar

    [2]

    Gibson G, Courtial J, Padgett M J, Vasnetsov M, Pas’ko V, Barnett S M, Franke-Arnold S, 2004 Opt. Express 12 5448Google Scholar

    [3]

    Willner A E, Zhao Z, Ren Y X, Li L, Xie G D, Song H Q, Liu C, Zhang R Z, Bao C J, Pang K 2018 Opt. Commun. 408 21Google Scholar

    [4]

    Lavery M P J, Speirits F C, Barnett S M, Padgett M J 2013 Science 341 537Google Scholar

    [5]

    Belmonte A, Rosales-Guzman C, Torres J P 2015 Optica 2 1002Google Scholar

    [6]

    杨伟东, 邱晓东, 陈理想 2020 中国激光 47 0500013Google Scholar

    Yang W D, Qiu X D, Chen L X 2020 Chin. J. Lasers 47 0500013Google Scholar

    [7]

    杨苏辉, 廖英琦, 林学彤, 刘欣宇, 齐若伊, 郝燕 2021 红外与激光工程 50 20211040Google Scholar

    Yang S H, Liao Y Q, Lin X T, Liu X Y, Qi R Y, Hao Y 2021 Infrared Laser Eng. 50 20211040Google Scholar

    [8]

    Jantzi A, Jemison W, Laux A, Mullen L, Cochenour B 2018 Opt. Express 26 2668Google Scholar

    [9]

    Baghdady J, Miller K, Morgan K, et al. 2016 Opt. Express 24 9794Google Scholar

    [10]

    Shen Y J, Wang X J, Xie Z W, Min C J, Fu X, Liu Q, Gong M L, Yuan X C 2019 Light Sci. Appl. 8 90Google Scholar

    [11]

    柳强, 潘婧, 万震松, 申艺杰, 张恒康, 付星, 巩马理 2020 中国激光 47 0500006Google Scholar

    Liu Q, Pan J, Wan Z S, Shen Y J, Zhang H K, Fu X, Gong M L 2020 Chin. J. Lasers 47 0500006Google Scholar

    [12]

    Forbes A 2019 Laser Photonics Rev. 13 1900140Google Scholar

    [13]

    Forbes A, Oliveira M D, Dennis M R 2021 Nat. Photonics 15 253Google Scholar

    [14]

    孙喜博, 朱启华, 刘兰琴, 黄晚晴, 张颖, 王文义, 耿远超 2017 激光与光电子学进展 54 070001Google Scholar

    Sun X B, Zhu Q H, Liu L Q, Huang W Q, Zhang Y, Wang W Y, Geng Y C 2017 Laser Optoelectron. P. 54 070001Google Scholar

    [15]

    付时尧, 高春清 2019 光学学报 39 0126014Google Scholar

    Fu S Y, Gao C Q 2019 Acta Opt. Sin. 39 0126014Google Scholar

    [16]

    常宁, 金立伟, 高玮 2019 光学学报 39 0319001Google Scholar

    Chang N, Jin L W, Gao W 2019 Acta Opt. Sin. 39 0319001Google Scholar

    [17]

    Zhao Y G, Chen B, Zheng C S, Jia D W, Dong J F, Guo J, Wang Z X, Yu H H, Zhang H J 2024 Laser Photonics Rev. 18 2301089Google Scholar

    [18]

    Pan J, Shen Y J, Wan Z S, Fu X, Zhang H K, Liu Q 2020 Phys. Rev. Appl. 14 044048Google Scholar

    [19]

    Zhao Y G, Wang L, Chen W D, et al. 2021 Photonics Res. 9 357Google Scholar

    [20]

    Qiao Z, Xie G Q, Wu Y H, Yuan P, Ma J G, Qian L J, Fan D Y 2018 Laser Photonics Rev. 12 1800019Google Scholar

    [21]

    宋小鹿, 李兵斌, 王石语, 蔡德芳, 文建国, 过振 2008 红外与激光工程 37 73Google Scholar

    Song X L, Li B B, Wang S Y, Cai D F, Wen J G, Guo Z 2008 Infrared Laser Eng. 37 73Google Scholar

    [22]

    姚育成, 刘丹琳, 黄楚云, 徐国旺, 王贝 2016 光子学报 45 131Google Scholar

    Yao Y C, Liu D L, Huang C Y, Xu G W, Wang B 2016 Acta Photonica Sin. 45 131Google Scholar

    [23]

    方洪烈 2014 光学谐振腔与引力波探测 (北京: 科学出版社) 第78—80页

    Fang H L 2014 Optical Resonators and Gravitational Wave Detection (Beijing: Science Press ) pp78–80

    [24]

    Koechner W 2013 Solid-State Laser Engineering (New York: Springer) pp46–83

  • [1] 王滔宁, 姜玲玲, 程庭清, 王礼, 江海河. 2.94 μm LiNbO3声光调Q Er:YAG激光输出脉冲特性. 物理学报, 2024, 73(4): 044205. doi: 10.7498/aps.73.20231616
    [2] 刘俊杰, 盛泉, 王盟, 张钧翔, 耿兴宁, 石争, 王爱华, 史伟, 姚建铨. 基于腔内球差选模产生高阶拉盖尔-高斯模式激光. 物理学报, 2022, 71(1): 014204. doi: 10.7498/aps.71.20211514
    [3] 连天虹, 王石语, 寇科, 刘芸. 离轴抽运厄米-高斯模固体激光器. 物理学报, 2020, 69(11): 114202. doi: 10.7498/aps.69.20200086
    [4] 杨文海, 刁文婷, 蔡春晓, 宋学瑞, 冯付攀, 郑耀辉, 段崇棣. 1064 nm固体激光器和光纤激光器在制备压缩真空态光场实验中的对比研究. 物理学报, 2019, 68(12): 124201. doi: 10.7498/aps.68.20182304
    [5] 张羚翔, 魏薇, 张志明, 廖文英, 杨振国, 范万德, 李乙钢. 环形光子晶体光纤中涡旋光的传输特性研究. 物理学报, 2017, 66(1): 014205. doi: 10.7498/aps.66.014205
    [6] 陈桂波, 张佳佳, 王超群, 毕娟. 一种基于激光辐照热效应的薄膜参数反演方法. 物理学报, 2016, 65(12): 124401. doi: 10.7498/aps.65.124401
    [7] 胡淼, 张慧, 张飞, 刘晨曦, 徐国蕊, 邓晶, 黄前锋. 用于光生毫米波的双频微片激光器热致频差特性研究. 物理学报, 2013, 62(20): 204205. doi: 10.7498/aps.62.204205
    [8] 周英, 戴玉, 姚淑娜, 刘军, 陈家斌, 陈淑芬, 辛建国. 激光二极管抽运Nd:YVO4晶体的三维热效应分析. 物理学报, 2013, 62(2): 024210. doi: 10.7498/aps.62.024210
    [9] 何广源, 郭靖, 焦中兴, 王彪. 固体激光器热透镜效应的调控. 物理学报, 2012, 61(9): 094217. doi: 10.7498/aps.61.094217
    [10] 刘海强, 过振, 王石语, 林林, 郭龙成, 李兵斌, 蔡德芳. 二极管端面抽运固体激光器晶体棒与热沉接触热导研究. 物理学报, 2011, 60(1): 014212. doi: 10.7498/aps.60.014212
    [11] 刘全喜, 钟鸣. 激光二极管阵列端面抽运复合棒状激光器热效应的有限元法分析. 物理学报, 2010, 59(12): 8535-8541. doi: 10.7498/aps.59.8535
    [12] 宋小鹿, 过振, 李兵斌, 王石语, 蔡德芳, 文建国. 脉冲激光二极管侧面抽运Nd∶YAG激光器晶体时变热效应. 物理学报, 2009, 58(3): 1700-1708. doi: 10.7498/aps.58.1700
    [13] 张秋琳, 苏红新, 孙 江, 郭庆林, 付广生. LD抽运被动调Q固体激光器的脉冲稳定性. 物理学报, 2007, 56(10): 5818-5820. doi: 10.7498/aps.56.5818
    [14] 吴 坚. AlInGaAs垂直谐振腔顶面发射半导体激光器横向温度效应的解析热模型及其表征. 物理学报, 2006, 55(11): 5848-5854. doi: 10.7498/aps.55.5848
    [15] 季小玲, 陶向阳, 吕百达. 光束控制系统热效应与球差对激光光束质量的影响. 物理学报, 2004, 53(3): 952-960. doi: 10.7498/aps.53.952
    [16] 关 俊, 李金萍, 程光华, 陈国夫, 侯 洵. 端面抽运固体激光器热透镜效应的实验研究. 物理学报, 2004, 53(6): 1804-1809. doi: 10.7498/aps.53.1804
    [17] 尚连聚. 端面抽运固体激光器的腔模匹配分析. 物理学报, 2003, 52(6): 1408-1411. doi: 10.7498/aps.52.1408
    [18] 张潮波, 宋峰, 孟凡臻, 丁欣, 张光寅, 商美茹. 利用输出功率测量激光二极管端面抽运的固体激光器热透镜焦距. 物理学报, 2002, 51(7): 1517-1520. doi: 10.7498/aps.51.1517
    [19] 冯衍, 宋峰, 赵丽娟, 张潮波, 郭红沧, 张光寅. LD抽运Nd:YVO4晶体中的上转换及其影响. 物理学报, 2001, 50(2): 335-340. doi: 10.7498/aps.50.335
    [20] 张光寅, 宋 峰, 冯 衍, 许京军. 可自适应补偿热透镜效应的固体激光谐振腔. 物理学报, 2000, 49(8): 1495-1498. doi: 10.7498/aps.49.1495
计量
  • 文章访问数:  1312
  • PDF下载量:  48
  • 被引次数: 0
出版历程
  • 收稿日期:  2024-05-28
  • 修回日期:  2024-07-01
  • 上网日期:  2024-07-25
  • 刊出日期:  2024-08-20

/

返回文章
返回