(3+1)-dimensional localized self-accelerating Airy elegant Ince–Gaussian wave packets and their radiation forces in free space<xref rid="cpb_26_12_124202_fn1" ref-type="fn">*</xref> <fn id="cpb_26_12_124202_fn1"> <label>*</label> <p>Project supported by the National Natural Science Foundation of China (Grant Nos. 11374108, 11374107, and 11775083), the Funds from CAS Key Laboratory of Geospace Environment, University of Science and Technology of China, and the Innovation Project of Graduate School of South China Normal University (Grant No. 2016lkxm64).</p> </fn>

(3+1)-dimensional localized self-accelerating Airy elegant Ince–Gaussian wave packets and their radiation forces in free space* *

Project supported by the National Natural Science Foundation of China (Grant Nos. 11374108, 11374107, and 11775083), the Funds from CAS Key Laboratory of Geospace Environment, University of Science and Technology of China, and the Innovation Project of Graduate School of South China Normal University (Grant No. 2016lkxm64).

Li Dongdong¹, Peng Xi¹, Peng Yulian¹, Zhang Liping¹, Chen Xingyu¹, Zhuang Jingli¹, Zhao Fang¹, Yang Xiangbo¹, Deng Dongmei^{1, 2, †}

(color online) Numerical demonstrations of the even, odd, and helical AieIG wave packets' evolution with different distances when T = 0. (a1)–(a6) the even AieIG wave packets; (b1)–(b6) the odd AieIG wave packets; (c1)–(c6) the helical AieIG wave packets. (a1)–(c1) numerical simulation of the normalized intensity distributions at Z = 0; (a2)–(c2) numerical simulation of the normalized phase distributions at Z = 0; (a3)–(c3) the normalized interference intensity of the initial generated beams and a plane wave; (a4)–(c4) the computer-generated holograms; (a5)–(c5) numerical simulation of the normalized transverse intensity distributions at Z = 1, and (a6)–(c6) the corresponding numerical experimental record. The other parameters are chosen as p = 4, m = 2, and ε = 2.