Fundamental symmetry origins in the chiral interactions of optical vortices

Andrews, Davıd L.

doi:10.1002/chir.23604

Cited by 6 publications

(2 citation statements)

References 180 publications

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“…Light field with orbital angular momentum (OAM) is also known as vortex beam which has been well applied in optical tweezers, [12] communication, [13] manufacturing, [14] etc. [15,16] The helical wavefront also gives vortex beam a chiral degree of freedom and its handedness is determined by the sign of the OAM munber l. [17][18][19] Interestingly, recent theoretical and experimental studies have demonstrated that the interaction between vortex beam and chiral matters depends on the sign of l. [20][21][22][23][24][25][26][27][28][29][30] This suggests that photonic OAM can provide another promising approach to investigate chiral physics. The giant helical dichroism (HD) has been achieved for a single helix, [25,29] planar-chiral nanostructure, [26] twisted stereometamaterial, [27] and chiral oligomer.…”

Section: Introductionmentioning

confidence: 99%

Observation of Magnetic Quadrupole Endowed Helical Dichroism in Artificial Propeller Meta‐Molecules

Ji,

Xu,

Liang

et al. 2023

Advanced Optical Materials

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This study demonstrates that the magnetic quadrupole (MQ) can make an indispensable contribution to helical dichroism (HD), which is distinct from HD caused by electric quadrupole (EQ). Specifically, the established multipole expansion theory of the light–matter interaction reveals that EQ‐induced HD belongs to the pure electric dipole–quadrupole (E1‐E2) excitation, while newly discovered MQ‐induced HD belongs to the pure magnetic dipole‐quadrupole (M1‐M2) excitation. Metallic propeller meta‐molecules are used to elaborate on this novel physical mechanism and demonstrate that HD can be significantly enhanced and flexibly tuned by increasing stereo twist of propeller meta‐molecules or slightly focusing the linearly polarized vortex beam to improve the orbital angular momentum number. Importantly, the aforementioned intriguing phenomena are validated by fabricating stereo twisted propeller meta‐molecules via nano‐kirigami method. The findings reveal a paradigm‐shift approach to manipulate the chiroptical response of a single metallic nanostructure via photonic orbital angular moment, opening prospects for optical encryption, communication, next‐generation chiroptical spectroscopy, and chiral vortex optical devices.

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Section: Introductionmentioning

confidence: 99%

Observation of Magnetic Quadrupole Endowed Helical Dichroism in Artificial Propeller Meta‐Molecules

Ji,

Xu,

Liang

et al. 2023

Advanced Optical Materials

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“…Chirality is a universal symmetry property of matter and waves that is important in biology, medicine, physics, , and materials science . In optics, chiral effects usually involve chiral light, characterized by helical waves carrying angular momentum. − The helical phase structure or field pattern rotation produces orbital angular momentum (OAM), while the rotation of the light polarization vector introduces spin angular momentum (SAM) . Analogies between electron and optical spin effects have recently led to the investigation of novel chiral states of light, such as photonic skyrmions. , Similar to their magnetic skyrmion counterparts, these spin-optical textures are topologically protected against external perturbations.…”

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confidence: 99%

Optical Spin Waves

Karakhanyan,

Salut,

Suarez

et al. 2024

Nano Lett.

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Chirality is inherent to a broad range of systems, including solid-state and wave physics. The precession (chiral motion) of the magnetic moments in magnetic materials, forming spin waves, has various properties and many applications in magnetism and spintronics. We show that an optical analogue of spin waves can be generated in arrays of plasmonic nanohelices. Such optical waves arise from the interaction between twisted helix eigenmodes carrying spin and orbital angular momenta. We demonstrate that these optical spin waves are reflected at the interface between successive domains of enantiomeric nanohelices, forming a heterochiral lattice regardless of the wave propagation direction within the lattice. Optical spin waves may be applied in techniques involving photon spin, ranging from data processing and storage to quantum optics.

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Topological‐Charge‐Dependent Dichroism and Birefringence of Optical Vortices

Forbes,

Green

2024

Laser & Photonics Reviews

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Material anisotropy and chirality produce polarization‐dependent light‐matter interactions. Absorption leads to linear and circular dichroism, whereas elastic forward scattering produces linear and circular birefringence. Here a form of dichroism and birefringence is highlighted whereby generic anisotropic media display locally different absorption and scattering of a focused vortex beam that depends upon the sign of the topological charge . The light‐matter interactions described in this work manifest purely through dominant electric‐dipole coupling mechanisms and depend on the paraxial parameter to first‐order. Previous topological‐charge‐dependent light‐matter interactions require the significantly weaker higher‐order multipole moments and are proportional to the paraxial parameter to second‐order. The result represents a method of probing the nano‐optics of advanced materials and the topological properties of structured light.

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Fundamental symmetry origins in the chiral interactions of optical vortices

Cited by 6 publications

References 180 publications

Observation of Magnetic Quadrupole Endowed Helical Dichroism in Artificial Propeller Meta‐Molecules

Observation of Magnetic Quadrupole Endowed Helical Dichroism in Artificial Propeller Meta‐Molecules

Optical Spin Waves

Topological‐Charge‐Dependent Dichroism and Birefringence of Optical Vortices

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