Saved in:
Bibliographic Details
Main Authors: Huang, Shunlin, Shen, Xiong, Chen, Renjing, Liu, Jun, Li, Ruxin
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2502.11769
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916617924902912
author Huang, Shunlin
Shen, Xiong
Chen, Renjing
Liu, Jun
Li, Ruxin
author_facet Huang, Shunlin
Shen, Xiong
Chen, Renjing
Liu, Jun
Li, Ruxin
contents Spatiotemporal optical vortex (STOV) carrying transverse orbital angular momentum (OAM) enriches the family of vortex beams and exhibit unique properties. Typically, a high-order STOV with an intensity null degrades into multiple first-order STOVs embedded within a single wave packet during propagation, a phenomenon known as time diffraction or mode degradation. However, this degradation limits the applicability of STOVs in specialized fields. Therefore, the generation of mode degradation-suppressed STOVs (MDS-STOVs) is of significant for both practical applications and theoretical studies. Herein, we theoretically analyze the generation of MDS-STOVs by utilizing a conical phase to localize the energy of the STOV into a ring-shaped structure. For MDS-STOVs with large topological charges (TCs), the ring-shaped profile can be well-maintained, and the rapid expansion of the beam size with increasing TC is significantly suppressed compared to conventional STOVs. As a result, these MDS-STOVs can be regarded as quasi-perfect STOVs (QPSTOVs). Furthermore, QPSTOVs exhibit strong resistance to group delay dispersion (GDD), eliminating the need for precise dispersion control and facilitating their generation and application. This work advances our understanding of the physical properties of light carrying transverse OAM and opens up exciting avenues for the application of STOVs in diverse fields, such as optical communication and quantum information processing.
format Preprint
id arxiv_https___arxiv_org_abs_2502_11769
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quasi-perfect spatiotemporal optical vortex with suppressed mode degradation
Huang, Shunlin
Shen, Xiong
Chen, Renjing
Liu, Jun
Li, Ruxin
Optics
Spatiotemporal optical vortex (STOV) carrying transverse orbital angular momentum (OAM) enriches the family of vortex beams and exhibit unique properties. Typically, a high-order STOV with an intensity null degrades into multiple first-order STOVs embedded within a single wave packet during propagation, a phenomenon known as time diffraction or mode degradation. However, this degradation limits the applicability of STOVs in specialized fields. Therefore, the generation of mode degradation-suppressed STOVs (MDS-STOVs) is of significant for both practical applications and theoretical studies. Herein, we theoretically analyze the generation of MDS-STOVs by utilizing a conical phase to localize the energy of the STOV into a ring-shaped structure. For MDS-STOVs with large topological charges (TCs), the ring-shaped profile can be well-maintained, and the rapid expansion of the beam size with increasing TC is significantly suppressed compared to conventional STOVs. As a result, these MDS-STOVs can be regarded as quasi-perfect STOVs (QPSTOVs). Furthermore, QPSTOVs exhibit strong resistance to group delay dispersion (GDD), eliminating the need for precise dispersion control and facilitating their generation and application. This work advances our understanding of the physical properties of light carrying transverse OAM and opens up exciting avenues for the application of STOVs in diverse fields, such as optical communication and quantum information processing.
title Quasi-perfect spatiotemporal optical vortex with suppressed mode degradation
topic Optics
url https://arxiv.org/abs/2502.11769