| In situ measurement of the topological charge of a perfect vortex using the phase shift method H Ma, X Li, Y Tai, H Li, J Wang, M Tang, Y Wang, J Tang, Z Nie Optics letters 42 (1), 135-138, 2017 | 94 | 2017 |
| Grafted optical vortex with controllable orbital angular momentum distribution H Zhang, X Li, H Ma, M Tang, H Li, J Tang, Y Cai Optics express 27 (16), 22930-22938, 2019 | 76 | 2019 |
| Controllable mode transformation in perfect optical vortices X Li, H Ma, C Yin, J Tang, H Li, M Tang, J Wang, Y Tai, X Li, Y Wang Optics express 26 (2), 651-662, 2018 | 75 | 2018 |
| Generation of circular optical vortex array H Ma, X Li, Y Tai, H Li, J Wang, M Tang, J Tang, Y Wang, Z Nie Annalen der Physik 529 (12), 1700285, 2017 | 57 | 2017 |
| Is it possible to enlarge the trapping range of optical tweezers via a single beam? XZ Li, HX Ma, H Zhang, MM Tang, HH Li, J Tang, YS Wang Applied Physics Letters 114 (8), 2019 | 55 | 2019 |
| Optical vortex shaping via a phase jump factor H Ma, X Li, H Zhang, J Tang, H Li, M Tang, J Wang, Y Cai Optics letters 44 (6), 1379-1382, 2019 | 54 | 2019 |
| Orientation-selective elliptic optical vortex array YK Wang, HX Ma, LH Zhu, YP Tai, XZ Li Applied Physics Letters 116 (1), 2020 | 43 | 2020 |
| Close-packed optical vortex lattices with controllable structures X Li, H Ma, H Zhang, Y Tai, H Li, M Tang, J Wang, J Tang, Y Cai Optics express 26 (18), 22965-22975, 2018 | 40 | 2018 |
| Single-particle trapping and dynamic manipulation with holographic optical surface-wave tweezers X Xie, X Wang, C Min, H Ma, Y Yuan, Z Zhou, Y Zhang, J Bu, X Yuan Photonics Research 10 (1), 166-173, 2022 | 17 | 2022 |
| Centrosymmetric optical vortex H Zhang, X Li, H Ma, M Tang, H Li, Y Cai Applied Sciences 9 (7), 1429, 2019 | 17 | 2019 |
| Controllable propagation and transformation of chiral intensity field at focus H Ma, Y Zhang, C Min, X Yuan Optics Letters 45 (17), 4823-4826, 2020 | 14 | 2020 |
| Adjustable elliptic annular optical vortex array HX Ma, XZ Li, H Zhang, J Tang, ZG Nie, HH Li, MM Tang, JG Wang, ... IEEE Photonics Technology Letters 30 (9), 813-816, 2018 | 11 | 2018 |
| Energy flow inversion in an intensity-invariant focusing field J Zhou, H Ma, Y Zhang, S Zhang, C Min, X Yuan Optics Letters 47 (6), 1494-1497, 2022 | 10 | 2022 |
| Time-varying orbital angular momentum in tight focusing of ultrafast pulses Z Zhou, C Min, H Ma, Y Zhang, X Xie, H Zhan, X Yuan Optics Express 30 (8), 13416-13433, 2022 | 9 | 2022 |
| Particle aggregation/disaggregation and sorting using woven spiral beams YP Tai, WJ Wei, H Zhang, HX Ma, XZ Li Applied Physics Letters 123 (19), 2023 | 5 | 2023 |
| Switchable rotation of metal nanostructures in an intensity chirality-invariant focus field Y Chen, J Zhou, X Xie, H Ma, S Zhang, Z Xie, C Min, Y Zhang, X Yuan Optics Letters 48 (23), 6328-6331, 2023 | 4 | 2023 |
| Generation of discrete higher-order optical vortex lattice at focus Y Wang, H Ma, Y Tai, X Li Optics Letters 48 (17), 4464-4467, 2023 | 4 | 2023 |
| annalen der H Ma, X Li, Y Tai, H Li, J Wang, M Tang, J Tang, Y n Wang, Z Nie Ann. Phys 12, x00027, 2017 | 2 | 2017 |
| On-chip manipulation of Bloch Surface Wave Y Fu, X Xiao, J Qiao, H Ma, J Gan, X Yuan, F Feng Optics Communications 535, 129362, 2023 | 1 | 2023 |
| Generation of chiral optical vortex lattice for controlled aggregation of particles XB Yang, H Zhang, MM Tang, HX Ma, YP Tai, XZ Li Applied Physics Letters 125 (1), 2024 | | 2024 |
Changjun MinShenzhen University在 szu.edu.cn 的电子邮件经过验证
Changjun MinShenzhen University在 szu.edu.cn 的电子邮件经过验证