Optical physics articles within Nature Communications

Featured

• Article
  22 February 2024 | Open Access

  Nonlinear spin-orbit coupling in optical thin films

  Spin-orbit interaction, and the associated phenomena, is commonly observed in crystalline structure pumped with circularly polarised beam. Here, the authors showed that this is not the case, and used nonlinear thin film to produce vortex beams of second-harmonic light.

  • Domenico de Ceglia
  • , Laure Coudrat
  •  & Costantino De Angelis

• Article
  21 February 2024 | Open Access

  Swept coded aperture real-time femtophotography

  The researchers showcase swept-coded aperture real-time femtophotography—an all-optical single-shot computational imaging modality at up to 156.3 trillion frames per second—video-records transient absorption in a semiconductor and ultrafast demagnetization of a metal alloy.

  • Jingdan Liu
  • , Miguel Marquez
  •  & Jinyang Liang

• Article
  19 February 2024 | Open Access

  Realization of all-band-flat photonic lattices

  Here the authors experimentally realized a systematic approach to synthesize arbitrary-size two-dimensional all-band-flat photonic lattices, which pave a route for investigating flat-band related physics such as slow-light, nonlinear breathing, and dispersionless image transmission.

  • Jing Yang
  • , Yuanzhen Li
  •  & Fei Gao

• Article
  15 February 2024 | Open Access

  Integrated microcavity electric field sensors using Pound-Drever-Hall detection

  Here the authors develop a chip-scale thin-film lithium niobate microcavity electric field sensor enabling real-time amplitude and phase measurements of various electric field waveforms.

  • Xinyu Ma
  • , Zhaoyu Cai
  •  & Rong Zeng

• Article
  15 February 2024 | Open Access

  Nonlinear topological symmetry protection in a dissipative system

  Applications of spontaneous symmetry breaking are hindered by unavoidable imperfections. Here, the authors reveal how a phase defect provides topological robustness to this process, enabling a bias free realization without fine tuning of parameters.

  • Stéphane Coen
  • , Bruno Garbin
  •  & Julien Fatome

• Article
  14 February 2024 | Open Access

  Intrinsic dichroism in amorphous and crystalline solids with helical light

  Differential absorption of polarized light, called dichroism, does not exist in amorphous solids due to the disordered arrangements of atoms. Here, the authors demonstrate that dichroism is intrinsic to all solids and can be controlled using helical light beams carrying orbital angular momentum.

  • Ashish Jain
  • , Jean-Luc Bégin
  •  & Ravi Bhardwaj

• Article
  14 February 2024 | Open Access

  Giant electric field-induced second harmonic generation in polar skyrmions

  Electric modulation of second harmonic generation finds applications in integrated photonics. Here, authors introduce electric field-induced second harmonic generation by polar skyrmions in PbTiO₃/SrTiO₃ superlattices with giant modulation depth.

  • Sixu Wang
  • , Wei Li
  •  & Qian Li

• Article
  13 February 2024 | Open Access

  Real-time tracking of coherent oscillations of electrons in a nanodevice by photo-assisted tunnelling

  The authors demonstrate that the collective electron oscillations driven by light in a quantum nanodevice can be measured directly in the time domain, by recording the photo-assisted tunnelling currents using the technique of homodyne beating.

  • Yang Luo
  • , Frank Neubrech
  •  & Manish Garg

• Article
  12 February 2024 | Open Access

  Optical Tellegen metamaterial with spontaneous magnetization

  Here the authors propose an isotropic three-dimensional metamaterial with nonreciprocal magnetoelectric resonant responses at visible and mid-infrared frequencies. The proposed metamaterials do not require external magnetization.

  • Shadi Safaei Jazi
  • , Ihar Faniayeu
  •  & Viktar Asadchy

• Article
  07 February 2024 | Open Access

  Statistics of modal condensation in nonlinear multimode fibers

  The authors investigate light beam propagation in multimode optical fibers, considering linear random mode coupling and Kerr nonlinearity. They utilize a 3D mode decomposition technique, enabling them to accurately characterize modal distributions over extended lengths of graded-index fiber.

  • Mario Zitelli
  • , Fabio Mangini
  •  & Stefan Wabnitz

• Article
  07 February 2024 | Open Access

  Ultracompact mirror device for forming 20-nm achromatic soft-X-ray focus toward multimodal and multicolor nanoanalyses

  Optics used for X-ray focusing suffer from wavelength dependent effects like chromatic aberration. Here the authors demonstrate fabrication of a ultracompact Kirkpatrick-Baez mirror and use it for achromatic focusing to 20 nm spot for the soft X-ray at 2-keV photon energy.

  • Takenori Shimamura
  • , Yoko Takeo
  •  & Hidekazu Mimura

• Article
  06 February 2024 | Open Access

  Linear and phase controllable terahertz frequency conversion via ultrafast breaking the bond of a meta-molecule

  The time-varying metasurfaces show promise for exploring exotic physics and photonic applications. The authors introduce a time-varying metasurface with superconductor-metal hybrid meta-molecules, demonstrating phase-controllable frequency conversion with high efficiency.

  • Siyu Duan
  • , Xin Su
  •  & Peiheng Wu

• Article
  06 February 2024 | Open Access

  Logical rotation of non-separable states via uniformly self-assembled chiral superstructures

  The logical rotation of non-separable states with a large tunable range is demonstrated by the uniformly self-assembled chiral superstructures, which enables a set of logic gates, proof-of-principle logic network, and angular motion tracking.

  • Yi-Heng Zhang
  • , Si-Jia Liu
  •  & Yan-Qing Lu

• Comment
  31 January 2024 | Open Access

  Topological photonics: robustness and beyond

  Synthetic optical materials have been recently employed as a powerful platform for the emulation of topological phenomena in wave physics. Topological phases offer exciting opportunities, not only for fundamental physics demonstrations, but also for practical technologies. Yet, their impact has so far been primarily limited to their claimed enhanced robustness. Here, we clarify the role of robustness in topological photonic systems, and we discuss how topological photonics may offer a wider range of important opportunities in science and for practical technologies, discussing emergent and exciting research directions.

  • Alexander B. Khanikaev
  •  & Andrea Alù

• Article
  31 January 2024 | Open Access

  Floquet parity-time symmetry in integrated photonics

  Here the authors unveil an approach rooted in non-Hermitian physics to precisely control light amplification in an integrated photonic platform, paving the way for innovative on-chip functionalities, like coherent control of light amplification and routing.

  • Weijie Liu
  • , Quancheng Liu
  •  & Feng Chen

• Article
  31 January 2024 | Open Access

  Slow light topological photonics with counter-propagating waves and its active control on a chip

  Topological slow light is of fundamental importance for science and technology. Here the authors reveal that the presence of magnetic phase vortices along with glide symmetric interfaces is crucial for the existence of slow light modes in topological valley photonic crystal waveguide.

  • Abhishek Kumar
  • , Yi Ji Tan
  •  & Ranjan Singh

• Article
  29 January 2024 | Open Access

  Switchable unidirectional emissions from hydrogel gratings with integrated carbon quantum dots

  Directional emission of photoluminescence is an emerging technique for light-emitting fields and nanophotonics. Here, the authors demonstrate a hydrogel grating with integrated quantum dots for switchable unidirectional emission tuning.

  • Chenjie Dai
  • , Shuai Wan
  •  & Zhongyang Li

• Article
  26 January 2024 | Open Access

  Thermo-optic epsilon-near-zero effects

  Nonlinear epsilon-near-zero nanodevices are attractive solutions for large-scale integrated system-on-chips yet heat genearation upon operation affects their performance. Here, the authors studied the linear and nonlinear thermo-optic effects in the indium tin oxide, commonly used material for this system.

  • Jiaye Wu
  • , Marco Clementi
  •  & Camille-Sophie Brès

• Article
  26 January 2024 | Open Access

  Chirality manipulation of ultrafast phase switches in a correlated CDW-Weyl semimetal

  The charge-density-wave Weyl semimetal (TaSe₄)₂I is a candidate for an axion insulator, however it may be obscured by polaron physics. Here, using ultrafast terahertz photocurrent spectroscopy, the authors realize phase switches from the polaronic state, to the charge density wave phase, and to the Weyl phase.

  • Bing Cheng
  • , Di Cheng
  •  & Jigang Wang

• Article
  24 January 2024 | Open Access

  Manipulating hyperbolic transient plasmons in a layered semiconductor

  Here, the authors report the generation and manipulation of transient hyperbolic plasmons in black phosphorus via ultrafast photocarrier injection, demonstrating a topological transition of the non-equilibrium iso-frequency contours and the coexistence of different transient plasmonic modes.

  • Rao Fu
  • , Yusong Qu
  •  & Jianing Chen

• Article
  20 January 2024 | Open Access

  Programmable integrated photonics for topological Hamiltonians

  Topological photonics could impact the scalability of integrated photonics, but it has shown limited reconfigurability to date. Here, the authors demonstrate reprogrammable integrated photonics as a nearly universal platform for topological models.

  • Mehmet Berkay On
  • , Farshid Ashtiani
  •  & Andrea Blanco-Redondo

• Article
  18 January 2024 | Open Access

  High crosstalk suppression in InGaAs/InP single-photon avalanche diode arrays by carrier extraction structure

  Opticalelectrical crosstalk, rather than optical crosstalk, is the primary issue in InGaAs/InP single-photon avalanche diode arrays. Here, Tang et al. propose a carrier-extraction structures to replace the trenching method, effectively reducing crosstalk and maintaining device reliability.

  • Yongsheng Tang
  • , Rui Wang
  •  & Meng Zhao

• Article
  13 January 2024 | Open Access

  Photonic Stochastic Emergent Storage for deep classification by scattering-intrinsic patterns

  Photonic Stochastic Emergent Storage is a neuromorphic photonic device for image storage and classification based on scattering-intrinsic patterns. Here, the authors show emergent storage employs stochastic prototype scattering-induced light patterns to generate categories corresponding to emergent archetypes.

  • Marco Leonetti
  • , Giorgio Gosti
  •  & Giancarlo Ruocco

• Article
  13 January 2024 | Open Access

  Giant intrinsic photovoltaic effect in one-dimensional van der Waals grain boundaries

  The intrinsic photovoltaic effect (IPVE) in noncentrosymmetric materials has the potential to overcome the limitations of traditional photovoltaic devices. Here, the authors report the observation of a strong and gate-tunable IPVE in 1D grain boundaries of a van der Waals semiconductor, ReS₂.

  • Yongheng Zhou
  • , Xin Zhou
  •  & Xiaolong Chen

• Article
  11 January 2024 | Open Access

  Distributed quantum sensing of multiple phases with fewer photons

  Enhanced sensitivity is a key parameter in quantum metrology. Here the authors demonstrate a distributed quantum phase sensing method that uses fewer photons than the number of parameters needed, and an enhanced quantum sensitivity is achieved.

  • Dong-Hyun Kim
  • , Seongjin Hong
  •  & Hyang-Tag Lim

• Article
  09 January 2024 | Open Access

  Scalable nano-architecture for stable near-blackbody solar absorption at high temperatures

  Nanostructures are generally unstable above 850 ^°C in air, limiting their use in high-temperature solar thermal applications. Here, a scalable ceramic nano-architecture layer can significantly enhance and stabilise the absorption of an arbitrary solar absorber.

  • Yifan Guo
  • , Kaoru Tsuda
  •  & Juan F. Torres

• Article
  04 January 2024 | Open Access

  Creating pairs of exceptional points for arbitrary polarization control: asymmetric vectorial wavefront modulation

  The authors report the chiral inversion of exceptional points (EPs) through a structural mirror-symmetric operation, extending the application of EP to any desired polarization states, surpassing the inherent limitation of conventional EP systems.

  • Zijin Yang
  • , Po-Sheng Huang
  •  & Qinghua Song

• Article
  03 January 2024 | Open Access

  Direct laser-written optomechanical membranes in fiber Fabry-Perot cavities

  Authors showcase 3D direct laser writing to fabricate optically interfaced mechanical resonators. The membrane-type structures are placed inside fiber Fabry-Perot cavities to realize a miniaturized optical cavity. Further, the optomechanical properties reveal the coupling mechanism and a significant tuning of the mechanical resonator frequency.

  • Lukas Tenbrake
  • , Alexander Faßbender
  •  & Hannes Pfeifer

• Article
  03 January 2024 | Open Access

  Electrical tuning of branched flow of light

  Here the authors experimentally realize the electrical tuning of branched flow of light in nematic liquid crystals. The statistical properties and the polarization effect of the branched flow of light in the film are systematically studied adding fundamental insights on branched flow of light.

  • Shan-shan Chang
  • , Ke-Hui Wu
  •  & Jin-hui Chen

• Article
  03 January 2024 | Open Access

  Realization of a crosstalk-avoided quantum network node using dual-type qubits of the same ion species

  In ion-photon quantum network platforms, usually memory qubits and communication qubits are encoded in ions of different species. Here, instead, the authors show how to realise ion-photon entanglement within the same-species-dual-encoding scheme.

  • L. Feng
  • , Y.-Y. Huang
  •  & L.-M. Duan

• Article
  02 January 2024 | Open Access

  Turnkey photonic flywheel in a microresonator-filtered laser

  Here the authors demonstrate a universal approach to achieve turnkey dissipative Kerr soliton (DKS) frequency comb. Phase insensitivity, self-healing capability, deterministic selection of DKS state, and access to ultralow noise are all successfully accomplished.

  • Mingming Nie
  • , Jonathan Musgrave
  •  & Shu-Wei Huang

• Perspective
  02 January 2024 | Open Access

  Planar hyperbolic polaritons in 2D van der Waals materials

  In this Perspective, the authors illustrate the physics of hyperbolic polaritons in anisotropic 2D and 1D materials, proposing new potential material candidates, forward looking opportunities and technological applications.

  • Hongwei Wang
  • , Anshuman Kumar
  •  & Tony Low

• Article
  02 January 2024 | Open Access

  Direct and integrating sampling in terahertz receivers from wafer-scalable InAs nanowires

  Authors report on nanofacet engineering of wafer‐scalable InAs nanowires enabling the operation of THz photodetectors in direct or integrating sampling mode, with performance comparable to commercial InP technology.

  • Kun Peng
  • , Nicholas Paul Morgan
  •  & Michael B. Johnston

• Article
  02 January 2024 | Open Access

  Ultrafast entropy production in pump-probe experiments

  Ultrafast spectroscopy enables characterization and control of non-equilibrium states. Here the authors introduce a stochastic thermodynamics approach to calculate entropy production in a material under ultrafast excitation, using ionic displacement data from time-resolved X-ray scattering experiments.

  • Lorenzo Caprini
  • , Hartmut Löwen
  •  & R. Matthias Geilhufe

• Article
  02 January 2024 | Open Access

  Quantum plasmonics pushes chiral sensing limit to single molecules: a paradigm for chiral biodetections

  Chiroptic sensing of single molecule is extremely challenging. Here the authors unveil an extreme nanophotonic system based on nanoparticle-on-mirror shows exceptional high sensitivity of chiral supramolecules, which can resolve enantiomer access of a racemate monolayer, exhibiting great potential for single chiral molecule sensing.

  • Chi Zhang
  • , Huatian Hu
  •  & Tao Ding

• Article
  02 January 2024 | Open Access

  Organohydrogel-based transparent terahertz absorber via ionic conduction loss

  Transparent absorbers for electromagnetic interference shielding are sought in the terahertz frequency range. The authors demonstrate organohydrogel-elastomer composites based on permittivity gradients, with strong ionic conduction loss, showing high absorption in the 0.5–4.5 THz band.

  • Wenke Xie
  • , Qian Tang
  •  & Qiye Wen

• Article
  20 December 2023 | Open Access

  Probing optical anapoles with fast electron beams

  Optical anapoles in nanoresonators result in strong suppression of the electromagnetic radiation, which is challenging to detect in ideal settings. Here, the authors show that fast electrons are a powerful tool to circumvent this challenge due to their ability to access dark modes.

  • Carlos Maciel-Escudero
  • , Andrew B. Yankovich
  •  & Timur O. Shegai

• Article
  18 December 2023 | Open Access

  Orbital perspective on high-harmonic generation from solids

  Here the authors identify real-space contributions to the characteristics of high-harmonic generation in ReS2 and demonstrate the possibility of laser-controlled emission. They find that the spectrum is not just determined by the band structure, but also by the interference between HHG signals coming from different atoms within the unit cell.

  • Álvaro Jiménez-Galán
  • , Chandler Bossaer
  •  & Giulio Vampa

• Article
  15 December 2023 | Open Access

  All-optical geometric image transformations enabled by ultrathin metasurfaces

  Metasurfaces enable all-optical geometric coordinate transformations, converting images with altered pixel spatial relations, which can facilitate fast, energy-efficient preprocessing for tasks like object tracking, or aid in laser manufacturing.

  • Xingwang Zhang
  • , Xiaojie Zhang
  •  & Xingjie Ni

• Article
  14 December 2023 | Open Access

  Tracking exceptional points above the lasing threshold

  The authors report on the experimental observation and characterization of exceptional points above the lasing threshold in photonic crystal nanocavities.

  • Kaiwen Ji
  • , Qi Zhong
  •  & Alejandro M. Yacomotti

• Article
  13 December 2023 | Open Access

  Quantum transport of high-dimensional spatial information with a nonlinear detector

  High-dimensional quantum states allow for several advantages in quantum communication, but protocols such as teleportation require additional entangled photons as the dimension increases. Here, the authors show how to transport a high-dimensional quantum state from a bright coherent laser field to a single photon, using two entangled photons as the quantum channel.

  • Bereneice Sephton
  • , Adam Vallés
  •  & Andrew Forbes

• Article
  13 December 2023 | Open Access

  Hyperbolic exciton polaritons in a van der Waals magnet

  Hyperbolic exciton polaritons (HEPs) are anisotropic light-matter excitations with promising applications, but their steady-state observation is challenging. Here, the authors report experimental evidence of HEPs in a van der Waals magnet, CrSBr, via cryogenic infrared near-field microscopy.

  • Francesco L. Ruta
  • , Shuai Zhang
  •  & D. N. Basov

• Article
  13 December 2023 | Open Access

  A coherent phonon-induced hidden quadrupolar ordered state in Ca₂RuO₄

  Ultrafast laser excitation can generate metastable states in quantum materials, with no counterpart in equilibrium. Here the authors demonstrate a transient quadrupolar ordered state in Ca2RuO4 single crystals via excitation of a phonon mode coupled to the order parameter.

  • Honglie Ning
  • , Omar Mehio
  •  & David Hsieh

• Article
  13 December 2023 | Open Access

  Remote transport of high-dimensional orbital angular momentum states and ghost images via spatial-mode-engineered frequency conversion

  Remote transport of high-dimensional-encoded photonic states could in principle be achieved via quantum teleportation, but with considerable experimental effort. Here, instead, the authors exploit spatial-mode engineered frequency conversion between a coherent wave packet and a single photon to remotely transfer the HD OAM states, also providing a strategy for quantum imaging.

  • Xiaodong Qiu
  • , Haoxu Guo
  •  & Lixiang Chen

• Article
  11 December 2023 | Open Access

  Nanophotonics for pair production

  The authors propose electron-positron creation by scattering of gamma-rays and polaritons, enabling the synthesis of ultrafast, localized positron sources and introducing the possibility to exploit nanophotonics for particle physics.

  • Valerio Di Giulio
  •  & F. Javier García de Abajo

• Article
  11 December 2023 | Open Access

  Ultrafast THz probing of nonlocal orbital current in transverse multilayer metallic heterostructures

  By optically driving the magnetization in a magnetic system, terahertz emission can be induced from an adjacent normal metal, as a result of spin-to-charge conversion. Here, Kumar and Kumar successfully show the equivalent effect arising from orbital-to-charge conversion.

  • Sandeep Kumar
  •  & Sunil Kumar

• Article
  07 December 2023 | Open Access

  Photon-phonon collaboratively pumped laser

  Ultrahigh-efficiency and low-threshold yet tunable and compact laser devices are at the base of new functional devices. Here the authors harness a new temperature degree of freedom to realize a tunable photon-phonon collaboratively pumped laser.

  • Yu Fu
  • , Fei Liang
  •  & Yan-Feng Chen

• Article
  05 December 2023 | Open Access

  Plasmon mediated coherent population oscillations in molecular aggregates

  The authors uncover a coherent, long-range transport of excitons in organic semiconductors that are strongly coupled to spatially structured plasmon fields by tracing ultrafast Rabi oscillations using two-dimensional electronic spectroscopy.

  • Daniel Timmer
  • , Moritz Gittinger
  •  & Christoph Lienau

• Article
  04 December 2023 | Open Access

  Fluorescence lifetime Hong-Ou-Mandel sensing

  Standard techniques for Fluorescence Lifetime Imaging Microscopy are limited by the electronics to 100’s of picoseconds time resolution. Here, the authors show how to use two-photon interference to perform fluorescence lifetime sensing with picosecond-scale resolution.

  • Ashley Lyons
  • , Vytautas Zickus
  •  & Daniele Faccio

• Article
  02 December 2023 | Open Access

  Polariton design and modulation via van der Waals/doped semiconductor heterostructures

  The photonic applications of hyperbolic phonon polaritons (HPhPs) in anisotropic van der Waals materials are currently limited by their low tunability. Here, the authors report the static and ultrafast wavevector modulation of HPhPs in hexagonal boron nitride by tuning the plasma frequency of doped semiconductor substrates.

  • Mingze He
  • , Joseph R. Matson
  •  & Joshua D. Caldwell