{"title":"时空光涡旋的横向轨道角动量","authors":"M. Porras","doi":"10.2528/PIER23012203","DOIUrl":null,"url":null,"abstract":"Spatiotemporal optical vortices (STOVs) are electromagnetic wave packets that transport a phase line singularity perpendicular to their propagation direction. We address the problem of the transverse orbital angular momentum (OAM) ``per photon\"actually transported by STOVs propagating in free space or non-dispersive media, the most frequent experimental situation. Unlike longitudinal vortices in monochromatic light beams, STOVs do not carry any net transverse OAM about a fixed transverse axis crossing its center. However, STOVs transport an intrinsic transverse OAM per photon about a moving, transverse axis through its center, and an opposite extrinsic transverse OAM. Their applications would thus preclude setting particles at rest into rotation, but STOVs could transmit their intrinsic transverse OAM to photons of other waves. 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However, STOVs transport an intrinsic transverse OAM per photon about a moving, transverse axis through its center, and an opposite extrinsic transverse OAM. Their applications would thus preclude setting particles at rest into rotation, but STOVs could transmit their intrinsic transverse OAM to photons of other waves. The intrinsic transverse OAM per photon of an elliptically symmetric STOV of frequency $\\\\omega_0$ and topological charge $l$ is $\\\\gamma l/2\\\\omega_0$, where $\\\\gamma$ is the STOV ellipticity. Thus circularly symmetric STOVs ($\\\\gamma=1$) carry half the intrinsic longitudinal OAM of circularly symmetric monochromatic light beams with a vortex of the same $l$ and $\\\\omega_0$. We show that the formula $(\\\\gamma+1/\\\\gamma)l/2\\\\omega_0$ for the intrinsic transverse OAM in Phys. Rev. A 107, L031501 (2023) yields infinite values and is not conserved on propagation for a particular STOV. 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引用次数: 4
摘要
时空光涡旋(stov)是电磁波包,传输一个垂直于其传播方向的相位线奇点。我们解决了横向轨道角动量(OAM)的问题。“每光子”实际上是由在自由空间或非色散介质中传播的stov传输的,这是最常见的实验情况。与单色光束中的纵向涡旋不同,stov不携带任何关于穿过其中心的固定横轴的净横向OAM。然而,stov每光子传输一个围绕运动的横向轴通过其中心的固有横向OAM,以及一个相反的外在横向OAM。因此,它们的应用将阻止静止粒子旋转,但stov可以将其固有的横向OAM传输给其他波的光子。频率为$\omega_0$,拓扑电荷为$l$的椭圆对称STOV的每光子的本征横向OAM为$\gamma l/2\omega_0$,其中$\gamma$为STOV的椭圆度。因此,圆对称stov ($\gamma=1$)具有相同$l$和$\omega_0$涡旋的圆对称单色光束的固有纵向OAM的一半。我们证明了物理中本征横向OAM的公式$(\gamma+1/\gamma)l/2\omega_0$。Rev. A 107, L031501(2023)产生无限值,并且在特定STOV的传播上不守恒。当stov在传播过程中失去椭圆对称性时,尽管相位奇点可能会分裂,分裂奇点可能会消失,甚至改变其拓扑电荷的符号,但它们仍然保持固有的横向OAM $\gamma l/2\omega_0$。
Transverse Orbital Angular Momentum of Spatiotemporal Optical Vortices
Spatiotemporal optical vortices (STOVs) are electromagnetic wave packets that transport a phase line singularity perpendicular to their propagation direction. We address the problem of the transverse orbital angular momentum (OAM) ``per photon"actually transported by STOVs propagating in free space or non-dispersive media, the most frequent experimental situation. Unlike longitudinal vortices in monochromatic light beams, STOVs do not carry any net transverse OAM about a fixed transverse axis crossing its center. However, STOVs transport an intrinsic transverse OAM per photon about a moving, transverse axis through its center, and an opposite extrinsic transverse OAM. Their applications would thus preclude setting particles at rest into rotation, but STOVs could transmit their intrinsic transverse OAM to photons of other waves. The intrinsic transverse OAM per photon of an elliptically symmetric STOV of frequency $\omega_0$ and topological charge $l$ is $\gamma l/2\omega_0$, where $\gamma$ is the STOV ellipticity. Thus circularly symmetric STOVs ($\gamma=1$) carry half the intrinsic longitudinal OAM of circularly symmetric monochromatic light beams with a vortex of the same $l$ and $\omega_0$. We show that the formula $(\gamma+1/\gamma)l/2\omega_0$ for the intrinsic transverse OAM in Phys. Rev. A 107, L031501 (2023) yields infinite values and is not conserved on propagation for a particular STOV. When STOVs lose their elliptical symmetry upon propagation, they preserve the intrinsic transverse OAM $\gamma l/2\omega_0$ despite the phase singularity may split, the split singularities may disappear, or even change the sign of their topological charges.
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