[1] Ashkin A. Acceleration and trapping of particles by radiation pressure[J]. Physical Review Letters, 24, 156-159(1970).

[2] Hänsch T W, Schawlow A L. Cooling of gases by laser radiation[J]. Optics Communications, 13, 68-69(1975).

[3] Ashkin A, Dziedzic J M, Bjorkholm J E et al. Observation of a single-beam gradient force optical trap for dielectric particles[J]. Optics Letters, 11, 288-290(1986).

[4] Ashkin A, Dziedzic J M. Optical trapping and manipulation of viruses and bacteria[J]. Science, 235, 1517-1520(1987).

[5] Zhu R X, Avsievich T, Popov A et al. Optical tweezers in studies of red blood cells[J]. Cells, 9, 545(2020).

[6] Zheng H X, Chen H J, Ng J et al. Optical gradient force in the absence of light intensity gradient[J]. Physical Review B, 103, 035103(2021).

[7] Descheemaeker L, Ginis V, Viaene S et al. Optical force enhancement using an imaginary vector potential for photons[J]. Physical Review Letters, 119, 137402(2017).

[8] Li B J, Xin H B, Zhang Y et al. Progress of optical trapping and manipulation[J]. Acta Optica Sinica, 31, 0900126(2011).

[9] Rong S, Liu H S, Zhong Y et al. Enhancement of Raman spectra based on optical trapping of gold nanocubes[J]. Acta Optica Sinica, 41, 1730003(2021).

[10] Gao D L, Ding W Q, Nieto-Vesperinas M et al. Optical manipulation from the microscale to the nanoscale: fundamentals, advances and prospects[J]. Light: Science & Applications, 6, e17039(2017).

[11] Kumar P, Sarma A K. Optical force on two-level atoms by few-cycle-pulse Gaussian laser fields beyond the rotating-wave approximation[J]. Physical Review A, 84, 043402(2011).

[12] Liu J C, Cheng F, Zhao Y N et al. Atom-subjected optical dipole force exerted by femtosecond laser field[J]. Acta Physica Sinica, 68, 033701(2019).

[13] Chakraborty S, Sarma A K. Optical trap potential control in N-type four-level atoms by femtosecond Gaussian pulses[J]. Journal of the Optical Society of America B, 32, 270-274(2015).

[14] Gong L P, Gu B, Rui G H et al. Optical forces of focused femtosecond laser pulses on nonlinear optical Rayleigh particles[J]. Photonics Research, 6, 138-143(2018).

[15] Zhu X Y, Qiu S, Ding Y et al. Rotational doppler effect analysis of multi-radial index Laguerre-Gaussian beam[J]. Acta Optica Sinica, 43, 0726003(2023).

[16] Liu J, Wang J. Research progress of vortex laser[J]. Chinese Journal of Lasers, 49, 1201001(2022).

[17] Cai T, Zhang X B, Ye F W et al. Experimental study of the holographic grating to produce the Laguerre-Gaussian modes[J]. Acta Optica Sinica, 25, 1457-1460(2005).

[18] Feng R Y, Qian J Y, Peng Y J et al. Femtosecond infrared optical vortex lasers based on optical parametric amplification[J]. High Power Laser Science and Engineering, 10, e29(2022).

[19] Chen Z K, Zheng S Q, Lu X M et al. Forty-five terawatt vortex ultrashort laser pulses from a chirped-pulse amplification system[J]. High Power Laser Science and Engineering, 10, e32(2022).

[20] Busleev N I, Kudryashov S I, Danilov P A et al. Symmetric nanostructuring and plasmonic excitation of gold nanostructures by femtosecond Laguerre–Gaussian laser beams[J]. Quantum Electronics, 49, 666-671(2019).

[21] Li J E, Guan W H, Yuan S et al. Laser shaping and optical power limiting of pulsed Laguerre-Gaussian laser beams of high-order radial modes in fullerene C60[J]. Chinese Physics B, 32, 024203(2023).

[22] Simpson N B, Allen L, Padgett M J. Optical tweezers and optical spanners with Laguerre-Gaussian modes[J]. Journal of Modern Optics, 43, 2485-2491(1996).

[23] Bougouffa S, Babiker M. Atom trapping and dynamics in the interaction of optical vortices with quadrupole-active transitions[J]. Physical Review A, 101, 043403(2020).

[24] Lu W L, Chen H J, Liu S Y et al. Circular Airy beam with an arbitrary conical angle beyond the paraxial approximation[J]. Physical Review A, 105, 043516(2022).

[25] Zhou L M, Shi Y Z, Zhu X Y et al. Recent progress on optical micro/nanomanipulations: structured forces, structured particles, and synergetic applications[J]. ACS Nano, 16, 13264-13278(2022).

[26] Kumar P, Kumar P, Sarma A K. Simultaneous control of optical dipole force and coherence creation by super-Gaussian femtosecond pulses in Λ‑like atomic systems[J]. Physical Review A, 89, 033422(2014).

[27] Liu J C, Guo F F, Zhao Y N et al. Time-frequency analysis of ultrafast dynamics in cascade three-level system driven by hyper-Gaussian pulses[J]. Optics Communications, 438, 25-33(2019).

[28] Liu J C, Guo F F, Zhao Y N et al. Optical power limiting of ultrashort hyper-Gaussian pulses in cascade three-level system[J]. Chinese Physics B, 27, 104209(2018).

[29] Martin W C, Zalubas R. Energy levels of sodium Na I through Na XI[J]. Journal of Physical and Chemical Reference Data, 10, 153-196(1981).

[30] Sansonetti J E. Wavelengths, transition probabilities, and energy levels for the spectra of sodium (Na I-Na XI)[J]. Journal of Physical and Chemical Reference Data, 37, 1659-1763(2008).