[1] D. McGloin, K. Dholakia. Bessel beams: diffraction in a new light. Contemp. Phys., 46, 15(2005).

[2] Y.-X. Ren, H. He, H. Tang, K. K. Wong. Non-diffracting light wave: fundamentals and biomedical applications. Front. Phys., 9, 698343(2021).

[3] A. Aiello, G. S. Agarwal. Wave-optics description of self-healing mechanism in Bessel beams. Opt. Lett., 39, 6819(2014).

[4] J. Durnin, J. Miceli, J. Eberly. Diffraction-free beams. Phys. Rev. Lett., 58, 1499(1987).

[5] V. Garcés-Chávez, D. McGloin, H. Melville, W. Sibbett, K. Dholakia. Simultaneous micromanipulation in multiple planes using a self-reconstructing light beam. Nature, 419, 145(2002).

[6] Y. A. Ayala, A. V. Arzola, K. Volke-Sepúlveda. Comparative study of optical levitation traps: focused Bessel beam versus Gaussian beams. J. Opt. Soc. Am. B, 33, 1060(2016).

[7] F. O. Fahrbach, P. Simon, A. Rohrbach. Microscopy with self-reconstructing beams. Nat. Photonics, 4, 780(2010).

[8] L. Gao, L. Shao, B.-C. Chen, E. Betzig. 3D live fluorescence imaging of cellular dynamics using Bessel beam plane illumination microscopy. Nat. Protoc., 9, 1083(2014).

[9] M. Duocastella, C. B. Arnold. Bessel and annular beams for materials processing. Laser Photonics Rev., 6, 607(2012).

[10] U. Levy, S. Derevyanko, Y. Silberberg. Light modes of free space. Prog. Opt., 61, 237(2016).

[11] J. C. Gutiérrez-Vega, M. Iturbe-Castillo, S. Chávez-Cerda. Alternative formulation for invariant optical fields: Mathieu beams. Opt. Lett., 25, 1493(2000).

[12] M. A. Bandres, B. Rodríguez-Lara. Nondiffracting accelerating waves: Weber waves and parabolic momentum. New J. Phys., 15, 013054(2013).

[13] C. W. McCutchen. Generalized aperture and the three-dimensional diffraction image. J. Opt. Soc. Am., 54, 240(1964).

[14] A. A. Kovalev, V. V. Kotlyar. Lommel modes. Opt. Commun., 338, 117(2015).

[15] Q. Zhao, L. Gong, Y.-M. Li. Shaping diffraction-free Lommel beams with digital binary amplitude masks. Appl. Opt., 54, 7553(2015).

[16] W. Zuo, Y.-S. Han, Z.-L. Zhou, H.-F. Xu, Z.-X. Zhou, J. Qu. Optical trapping force on two types of particles with a focused partially coherent Lommel-Gaussian beam. Results Phys., 32, 105076(2022).

[17] J. Tu, X. Wang, X. Yu, H. Wang, D. Deng. Free space realization of the symmetrical tunable auto-focusing Lommel Gaussian vortex beam. Ann. Phys., 534, 2100419(2021).

[18] L. Yu, Y. Zhang. Analysis of modal crosstalk for communication in turbulent ocean using Lommel-Gaussian beam. Opt. Express, 25, 22565(2017).

[19] Z. Lu, B. Yan, K. Chang, Y. Qiao, C. Li, J. Hu, T. Xu, H. Zhang, W. Lin, Y. Yue. Space division multiplexing technology based on transverse wavenumber of Lommel–Gaussian beam. Opt. Commun., 488, 126835(2021).

[20] Y. Hui, Z. Cui, P. Song. Propagation characteristics of non-diffracting Lommel beams in a gradient-index medium. Waves Random Complex Medium, 31, 2514(2020).

[21] Q. Liang, Y. Zhu, Y. Zhang. Approximations wander model for the Lommel Gaussian-Schell beam through unstable stratification and weak ocean-turbulence. Results Phys., 14, 102511(2019).

[22] Q. Suo, Y. Han, Z. Cui. The spectral properties of a partially coherent Lommel-Gaussian beam in turbulent atmosphere. Opt. Laser Technol., 123, 105940(2020).

[23] H. Li, C. M. Woo, T. Zhong, Z. Yu, Y. Luo, Y. Zheng, X. Yang, H. Hui, P. Lai. Adaptive optical focusing through perturbed scattering media with a dynamic mutation algorithm. Photonics Res., 9, 202(2021).

[24] Y. Shen, Y. Liu, C. Ma, L. V. Wang. Focusing light through biological tissue and tissue-mimicking phantoms up to 9.6 cm in thickness with digital optical phase conjugation. J. Biomed Opt., 21, 085001(2016).

[25] T. Peng, R. Li, S. An, X. Yu, M. Zhou, C. Bai, Y. Liang, M. Lei, C. Zhang, B. Yao, P. Zhang. Real-time optical manipulation of particles through turbid media. Opt. Express, 27, 4858(2019).

[26] A. Boniface, M. Mounaix, B. Blochet, R. Piestun, S. Gigan. Transmission-matrix-based point-spread-function engineering through a complex medium. Optica, 4, 54(2017).

[27] C. Ma, J. Di, Y. Zhang, P. Li, F. Xiao, K. Liu, X. Bai, J. Zhao. Reconstruction of structured laser beams through a multimode fiber based on digital optical phase conjugation. Opt. Lett., 43, 3333(2018).

[28] L. Li, Y. Zheng, H. Liu, X. Chen. Reconstitution of optical orbital angular momentum through strongly scattering media via feedback-based wavefront shaping method. Chin. Opt. Lett., 19, 100101(2021).

[29] Z. Chen, X. Hu, X. Ji, J. Pu. Needle beam generated by a laser beam passing through a scattering medium. IEEE Photonics J., 10, 6501108(2018).

[30] W. Yuan, Y. Xu, K. Zheng, S. Fu, Y. Wang, Y. Qin. Experimental generation of perfect optical vortices through strongly scattering media. Opt. Lett., 46, 4156(2021).

[31] S.-J. Tu, X. Zhao, Q.-Y. Yue, Y.-J. Cai, C.-S. Guo, Q. Zhao. Shaping the illumination beams for STED imaging through highly scattering media. Appl. Phys. Lett., 119, 211105(2021).

[32] S. Popoff, G. Lerosey, R. Carminati, M. Fink, A. Boccara, S. Gigan. Measuring the transmission matrix in optics: an approach to the study and control of light propagation in disordered media. Phys. Rev. Lett., 104, 100601(2010).

[33] S. A. Goorden, J. Bertolotti, A. P. Mosk. Superpixel-based spatial amplitude and phase modulation using a digital micromirror device. Opt. Express, 22, 17999(2014).