[1] Lichtman J W, Conchello J A. Fluorescence microscopy[J]. Nature Methods, 2, 910-919(2005).

[2] Betzig E, Patterson G H, Sougrat R et al. Imaging intracellular fluorescent proteins at nanometer resolution[J]. Science, 313, 1642-1645(2006).

[3] Rust M, Bates M, Zhuang X. Stochastic optical reconstruction microscopy (STORM) provides subdiffraction-limit image resolution[J]. Nature Methods, 3, 793-795(2006).

[4] Vicidomini G, Bianchini P, Diaspro A. STED super-resolved microscopy[J]. Nature Methods, 15, 173-182(2018).

[5] Allen J R, Ross S T, Davidson M W. Structured illumination microscope for superresolution[J]. Chemphyschem, 15, 566-576(2014).

[6] Helmchen F, Denk W. Deep-tissue two-photon microscopy[J]. Nature Methods, 2, 932-940(2005).

[7] König K. Multiphoton microscopy in life sciences[J]. Journal of Microscopy, 200, 83-104(2000).

[8] Santi P A. The light sheet fluorescence microscope: a review[J]. The Journal of Histochemistry and Cytochemistry, 59, 129-138(2011).

[9] Prevedel R, Yoon Y G, Hoffmann M et al. Simultaneous whole-animal 3D imaging of neuronal activity using light-field microscopy[J]. Nature Methods, 11, 727-730(2014).

[10] Javidi B, Moon I, Yeom S et al. Three-dimensional imaging and recognition of microorganisms using single-exposure on-line (SEOL) digital holography[J]. Optics Express, 13, 4492-4506(2005).

[11] Oldenbourg R. A new view on polarization microscopy[J]. Nature, 318, 811-812(1996).

[12] Durnin J, Miceli J, Eberly J H. Diffraction-free beams[J]. Physical Review Letters, 58, 1499-1501(1987).

[13] Bouchal Z. Nondiffracting optical beams: physical properties, experiments, and applications[J]. Czechoslovak Journal of Physics, 53, 537-578(2003).

[14] Mazilu M, Stevenson D J, Gunn-Moore F et al. Light beats the spread: “non-diffracting” beams[J]. Laser & Photonics Reviews, 4, 529-547(2010).

[15] Brown B R, Lohmann A W. Computer-generated binary holograms[J]. IBM Journal of Research and Development, 13, 160-168(1969).

[16] López-Mariscal C, Gutiérrez-Vega J C. The generation of non-nondiffracting beams using inexpensive computer-generated holograms[J]. American Journal of Physics, 75, 36-42(2007).

[17] Haist T, Schönleber M, Tiziani H J. Computer-generated holograms from 3D-objects written on twisted-nematic liquid crystal displays[J]. Optics Communications, 140, 299-308(1997).

[18] Litvin I A, McLaren M G, Forbes A. The propagation of obstructed Bessel and Bessel-Gauss beams[J]. Proceedings of SPIE, 7062, 706218(2008).

[19] Zhang Q N, Wu F T, Zheng W T et al. Self-reconstructing properties of high-order Besssel-Gauss beam[J]. Scientia Sinica Physica, Mechanica & Astronomica, 41, 1131-1137(2011).

[20] Chu X. An analytical study of the self-healing properties of the Bessel beam[J]. The European Physical Journal D, 66, 259(2012).

[21] Aiello A, Agarwal G S, Paúr M et al. Unraveling beam self-healing[J]. Optics Express, 25, 19147-19157(2017).

[22] Xie J, Xu H S, Yu W H et al. Numerical Simulation and Experimental Confirmation on Reconstruction of Bessel Beam[J]. Laser & Optoelectronics Progress, 59, 0617021(2022).

[23] Khonina S N, Kazanskiy N L, Karpeev S V et al. Bessel beam: significance and applications-a progressive review[J]. Micromachines, 11, 997(2020).

[24] Chen Y, Liu J T C. Characterizing the beam steering and distortion of Gaussian and Bessel beams focused in tissues with microscopic heterogeneities[J]. Biomedical Optics Express, 6, 1318-1330(2015).

[25] Chremmos I D, Chen Z G, Christodoulides D N et al. Bessel-like optical beams with arbitrary trajectories[J]. Optics Letters, 37, 5003-5005(2012).

[26] Berry M V, Balazs N L. Nonspreading wave packets[J]. American Journal of Physics, 47, 264-267(1979).

[27] Siviloglou G A, Broky J, Dogariu A et al. Observation of accelerating airy beams[J]. Physical Review Letters, 99, 213901(2007).

[28] Bandres M A. Accelerating parabolic beams[J]. Optics Letters, 33, 1678-1680(2008).

[29] Hu Y, Zhang P, Lou C B et al. Optimal control of the ballistic motion of Airy beams[J]. Optics Letters, 35, 2260-2262(2010).

[30] Efremidis N K, Chen Z G, Segev M et al. Airy beams and accelerating waves: an overview of recent advances[J]. Optica, 6, 686-701(2019).

[31] Salandrino A, Christodoulides D N. Airy plasmon: a non-nondiffracting surface wave[J]. Optics Letters, 35, 2082-2084(2010).

[32] Eichelkraut T J, Siviloglou G A, Besieris I M et al. Oblique Airy wave packets in bidispersive optical media[J]. Optics Letters, 35, 3655-3657(2010).

[33] Li Y, Chu X C, Tang H L et al. Propagation, evolution properties of finite energy Airy beams[J]. Laser & Optoelectronics Progress, 59, 1326001(2022).

[34] Li L, Li T, Wang S M et al. Plasmonic Airy beam generated by in-plane diffraction[J]. Physical Review Letters, 107, 126804(2011).

[35] Longhi S. Airy beams from a microchip laser[J]. Optics Letters, 36, 716-718(2011).

[36] Porat G, Dolev I, Barlev O et al. Airy -beam laser[J]. Optics Letters, 36, 4119-4121(2011).

[37] Cao R, Yang Y, Wang J G et al. Microfabricated continuous cubic phase plate-induced Airy beams for optical manipulation with high power efficiency[J]. Applied Physics Letters, 99, 261106(2011).

[38] Voloch-Bloch N, Lereah Y, Lilach Y et al. The generation of electron Airy beams[J]. Nature, 494, 331-335(2013).

[39] Müllenbroich M C, Silvestri L, Turrini L et al. High-fidelity imaging with Bessel-beam light-sheet microscopy for whole-brain structural and functional studies[C], BrW4B.2(2017).

[40] Zhao T, Lau S C, Wang Y et al. Multicolor 4D fluorescence microscopy using ultrathin Bessel light sheets[J]. Scientific Reports, 6, 1-6(2016).

[41] Fahrbach F O, Simon P, Rohrbach A. Microscopy with self-reconstructing beams[J]. Nature Photonics, 4, 780-785(2010).

[42] Vettenburg T, Dalgarno H I C, Nyla J et al. Light-sheet microscopy using an Airy beam[J]. Nature Methods, 11, 541-544(2014).

[43] Dufour P, Piché M, De Koninck Y et al. Two-photon excitation fluorescence microscopy with a high depth of field using an axicon[J]. Applied Optics, 45, 9246-9252(2006).

[44] Thériault G, De Koninck Y, McCarthy N. Extended depth of field microscopy for rapid volumetric two-photon imaging[J]. Optics Express, 21, 10095-10104(2013).

[45] Takanezawa S, Saitou T, Imamura T. Wide -field light-sheet microscopy with lens-axicon -controlled two-photon Bessel beam illumination[J]. Nature Communications, 12, 1-15(2021).

[46] Rodríguez C, Liang Y J, Lu R W et al. Three-photon fluorescence microscopy with an axially elongated Bessel focus[J]. Optics Letters, 43, 1914-1917(2018).

[47] Chen B Y, Huang X S, Gou D Z et al. Rapid volumetric imaging with Bessel-Beam three-photon microscopy[J]. Biomedical Optics Express, 9, 1992-2000(2018).

[48] He H S, Kong C H, Chan K Y et al. Resolution enhancement in an extended depth of field for volumetric two-photon microscopy[J]. Optics Letters, 45, 3054-3057(2020).

[49] Tan X J, Kong C H, Ren Y X et al. Volumetric two-photon microscope with a non-diffracting Airy beam[J]. Optics Letters, 44, 391-394(2019).

[50] Chen X L, Zhang C, Lin P et al. Volumetric chemical imaging by stimulated Raman projection microscopy and tomography[J]. Nature Communications, 8, 1-12(2017).

[51] Zhang P, Goodwin P M, Werner J H. Fast, super resolution imaging via Bessel-beam stimulated emission depletion microscopy[J]. Optics Express, 22, 12398-12409(2014).

[52] Hua X W, Guo C L, Wang J et al. Depth-extended, high-resolution fluorescence microscopy: whole-cell imaging with double-ring phase (DRiP) modulation[J]. Biomedical Optics Express, 10, 204-214(2018).

[53] Jia S, Vaughan J C, Zhuang X W. Isotropic 3D super-resolution imaging with a self-bending point spread function[J]. Nature Photonics, 8, 302-306(2014).

[54] Wang J, Hua X W, Guo C L et al. Airy-beam tomographic microscopy[J]. Optica, 7, 790-793(2020).

[55] Wang J, Guo Z L, Zhang R Q et al. Spectrum modulation-based field - of - view extension in Airy-beam tomographic microscopy[J]. Optics Letters, 47, 3928-3931(2022).

[56] Vetter C, Eichelkraut T, Ornigotti M et al. Generalized radially self-accelerating Helicon beams[J]. Physical Review Letters, 113, 183901(2014).

[57] Schroeder B, Zhu Z H, Guo C L et al. Evolutionary optimization of nondiffracting Helicon beams[C], MTu2C.4(2017).

[58] López-Mariscal C, Gutiérrez-Vega J C, Milne G et al. Orbital angular momentum transfer in helical Mathieu beams[J]. Optics Express, 14, 4182-4187(2006).

[59] Zhang P, Hu Y, Li T C et al. Nonparaxial Mathieu and weber-accelerating beams[J]. Physical Review Letters, 109, 193901(2012).

[60] Baumgartl J, Mazilu M, Dholakia K. Optically mediated particle clearing using Airy wavepacket[J]. Nature Photonics, 2, 675-678(2008).

[61] Polynkin P, Kolesik M, Moloney J V et al. Curved plasma channel generation using ultraintense Airy beams[J]. Science, 324, 229-232(2009).

[62] Mathis A, Courvoisier F, Froehly L et al. Micromachining along a curve: Femtosecond laser micromachining of curved profiles in diamond and silicon using accelerating beams[J]. Applied Physics Letters, 101, 071110(2012).

[63] Ellenbogen T, Voloch N, Ganany-Padowicz A et al. Nonlinear generation and manipulation of Airy beams[J]. Nature Photonics, 3, 395-398(2009).

[64] Voloch-Bloch N, Lereah Y, Lilach Y et al. The generation of electron Airy beams[J]. Nature, 494, 331-335(2013).

[65] Salandrino A, Christodoulides D N. Airy plasmon: a non-diffracting surface wave[J]. Optics Letters, 35, 2082-3806(2010).

[66] Zhang P, Li T C, Zhu J et al. Generation of acoustic self-bending and bottle beams by phase engineering[J]. Nature Communications, 5, 1-9(2014).

[67] Kaminer I, Nemirovsky J, Rechtsman M et al. Self-accelerating Dirac particles and prolonging the lifetime of relativistic fermions[J]. Nature Physics, 11, 261-267(2015).