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Main Authors: Ni, Jielei, Zhang, Yao, Wei, Qianyi, Zhou, Zhangyu, Zhang, Shuoshuo, Zhang, Yuquan, Jin, Qi, Tan, Zhiyong, Pan, Jiahui, Cheng, Ya, Zhan, Qiwen, Yuan, Xiaocong, Min, Changjun
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.25154
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author Ni, Jielei
Zhang, Yao
Wei, Qianyi
Zhou, Zhangyu
Zhang, Shuoshuo
Zhang, Yuquan
Jin, Qi
Tan, Zhiyong
Pan, Jiahui
Cheng, Ya
Zhan, Qiwen
Yuan, Xiaocong
Min, Changjun
author_facet Ni, Jielei
Zhang, Yao
Wei, Qianyi
Zhou, Zhangyu
Zhang, Shuoshuo
Zhang, Yuquan
Jin, Qi
Tan, Zhiyong
Pan, Jiahui
Cheng, Ya
Zhan, Qiwen
Yuan, Xiaocong
Min, Changjun
contents Spatiotemporal optical vortices (STOVs) carry transverse orbital angular momentum and offer new degrees of freedom for light-matter interactions. Yet conventional focusing of STOVs introduces spatiotemporal astigmatism: the beam diffracts while the pulse duration stays constant, causing the vortex to deform away from focus. Here we overcome this limitation by introducing spectral phase modulation into a temporal focusing configuration, where angular dispersion forces the pulse to compress only at the geometric focus so that the spatial and temporal dimensions focus and defocus together. Our approach generates stable STOVs with self-similar, distortion-free evolution over an extended focal region. Besides, the orbital angular momentum vector can be continuously steered from purely longitudinal to strongly tilted orientations by adjusting the spatial dispersion, objective focal length, or input beam size. More importantly, our method offers full compatibility with high NA focusing geometry, allowing high-intensity and high-resolution applications. We validate these properties through femtosecond laser ablation under high-NA conditions and interferometric spatiotemporal field reconstruction under low-NA conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2603_25154
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Temporal Focusing Enables Distortion-Resistant high-intensity Spatiotemporal Optical Vortices
Ni, Jielei
Zhang, Yao
Wei, Qianyi
Zhou, Zhangyu
Zhang, Shuoshuo
Zhang, Yuquan
Jin, Qi
Tan, Zhiyong
Pan, Jiahui
Cheng, Ya
Zhan, Qiwen
Yuan, Xiaocong
Min, Changjun
Optics
Spatiotemporal optical vortices (STOVs) carry transverse orbital angular momentum and offer new degrees of freedom for light-matter interactions. Yet conventional focusing of STOVs introduces spatiotemporal astigmatism: the beam diffracts while the pulse duration stays constant, causing the vortex to deform away from focus. Here we overcome this limitation by introducing spectral phase modulation into a temporal focusing configuration, where angular dispersion forces the pulse to compress only at the geometric focus so that the spatial and temporal dimensions focus and defocus together. Our approach generates stable STOVs with self-similar, distortion-free evolution over an extended focal region. Besides, the orbital angular momentum vector can be continuously steered from purely longitudinal to strongly tilted orientations by adjusting the spatial dispersion, objective focal length, or input beam size. More importantly, our method offers full compatibility with high NA focusing geometry, allowing high-intensity and high-resolution applications. We validate these properties through femtosecond laser ablation under high-NA conditions and interferometric spatiotemporal field reconstruction under low-NA conditions.
title Temporal Focusing Enables Distortion-Resistant high-intensity Spatiotemporal Optical Vortices
topic Optics
url https://arxiv.org/abs/2603.25154