Featured
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News & Views |
Good vibrations for quantum computing
Quantum computing operations are realized using acoustic devices, paving the way for a new type of quantum processor.
- Amy Navarathna
- & Warwick P. Bowen
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News & Views |
Topological interface of light
Upon combining dissipative and nonlinear effects in a bipartite lattice of cavity polaritons, dissipatively stabilized bulk gap solitons emerge, which create a topological interface.
- Flore K. Kunst
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Article |
Gap solitons in a one-dimensional driven-dissipative topological lattice
Drive engineering in optical systems can be used to stabilize new nonlinear phases in topological systems. Dissipatively stabilized gap solitons in a polariton lattice establish drive engineering as a resource for nonlinear topological photonics.
- Nicolas Pernet
- , Philippe St-Jean
- & Jacqueline Bloch
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Article |
Direct observations of thermalization to a Rayleigh–Jeans distribution in multimode optical fibres
Optical nonlinearities in multimodal systems lead to a complex behaviour that can be described as a thermalization process, which is expected to lead to a Rayleigh–Jeans distribution. This process has now been observed in graded-index fibres.
- Hamed Pourbeyram
- , Pavel Sidorenko
- & Frank Wise
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News & Views |
A controlled cascade interference
Nonlinear optical effects enable sophisticated functionalities to generate and manipulate light. The precise control of two distinct nonlinear phenomena in a photonic chip can enhance a key optical nonlinearity that makes single-photon sources more efficient.
- Thiago P. Mayer Alegre
- & Gustavo S. Wiederhecker
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Letter |
In situ control of effective Kerr nonlinearity with Pockels integrated photonics
Many nanophotonic devices rely on optical nonlinearities, which can be indirectly engineered. The quantum interference of different nonlinear pathways directly controls the Kerr nonlinearity without changing the device design.
- Chaohan Cui
- , Liang Zhang
- & Linran Fan
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Article
| Open AccessBand transport by large Fröhlich polarons in MXenes
The charge transport mechanism in MXenes—an emerging class of layered materials—is not yet fully understood. A combination of terahertz spectroscopy and transport measurements shows that the formation of large polarons play a crucial role.
- Wenhao Zheng
- , Boya Sun
- & Mischa Bonn
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News & Views |
Loss leads the way to utopia
The interactions between coupled photonic resonators influence the properties of the whole network. Dissipative coupling extends the ability to engineer photonic networks and brings fully controllable, ‘utopian’ networks within reach.
- Hrvoje Buljan
- , Dario Jukić
- & Zhigang Chen
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Article |
All-optical attoclock for imaging tunnelling wavepackets
Whether or not an electron wavepacket accumulates a time delay when tunnelling out of an atom is still under debate. Improved all-optical characterization of the tunnelling dynamics by combining one- and two-colour driving fields may shed light on this question.
- Ihar Babushkin
- , Álvaro Jiménez Galán
- & Misha Ivanov
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Article |
Topological dissipation in a time-multiplexed photonic resonator network
Topological phenomena have mostly been studied in conservative systems. Experiments on optical resonator networks now show that topologically non-trivial characteristics can also emerge in dissipation.
- Christian Leefmans
- , Avik Dutt
- & Alireza Marandi
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Article |
Cyclotron resonance overtones and near-field magnetoabsorption via terahertz Bernstein modes in graphene
Electrons in an external magnetic field absorb electromagnetic radiation via cyclotron resonance. Deviations from this behaviour in the form of overtone resonances due to ultraslow magnetoplasmonic excitations are now reported for graphene.
- D. A. Bandurin
- , E. Mönch
- & S. D. Ganichev
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Article |
Error correction of a logical grid state qubit by dissipative pumping
Physical systems with continuous degrees of freedom can be used to implement quantum error correction codes. An autonomous correction protocol has now been used to extend the lifetime of a qubit encoded in the motion of a trapped ion.
- Brennan de Neeve
- , Thanh-Long Nguyen
- & Jonathan P. Home
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News & Views |
Optical energy on demand
Light travels through disordered media on a random path that is hard to control. A comprehensive study has now shown that optical energy can be deposited at a desired depth in a disordered waveguide by injecting a light field with a particular shape.
- Oluwafemi S. Ojambati
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Article |
Depth-targeted energy delivery deep inside scattering media
Optimally depositing optical energy into an extended region of a diffusive medium, such as biological tissue, is a challenging task. A matrix that maps the incoming wavefront to the field distribution inside the material can predict the energy enhancement that occurs at a given depth.
- Nicholas Bender
- , Alexey Yamilov
- & Hui Cao
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Article |
Riemannian geometry of resonant optical responses
The modern understanding of quantum transport relies on geometric concepts such as the Berry phase. The geometric approach has now been extended to the theory of optical transitions.
- Junyeong Ahn
- , Guang-Yu Guo
- & Ashvin Vishwanath
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News & Views |
A fast push to photon pairs
Solid-state sources of entangled photons with tailored properties are key elements for integrated quantum computing. Refractive-index perturbations propagating faster than the speed of light may offer a practical approach for generating entangled photon pairs.
- Nahid Talebi
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News & Views |
Nonlinear effects get into shape
Nonlinear optical effects are by default weak but they can be enhanced by sculpting the resulting spectrally periodic pulses from a fibre laser into an optimal shape.
- Thibaut Sylvestre
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Article |
Controlling two-photon emission from superluminal and accelerating index perturbations
Despite their relevance for quantum technology, photon-pair sources are difficult to control. A theoretical proposal shows how photon pairs can be created from vacuum fluctuations in time-dependent systems, potentially enabling heralded single-photon frequency combs.
- Jamison Sloan
- , Nicholas Rivera
- & Marin Soljačić
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Article |
Spectrally periodic pulses for enhancement of optical nonlinear effects
The nonlinear optical effects underlying many applications are typically weak, but linear dispersion engineering allows the generation of pulses comprising equidistant frequency components, which enhances the effective nonlinearity.
- Joshua P. Lourdesamy
- , Antoine F. J. Runge
- & C. Martijn de Sterke
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News & Views |
Optomechanics joins the soliton club
Solitary waves — solitons — occur in a wide range of physical systems with a broad array of attributes and applications. Carefully engineered light–matter interactions have now produced an optomechanical dissipative soliton with promising properties.
- Alessia Pasquazi
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News & Views |
Mix and match
It has long been assumed that the quantum statistics of light are preserved when photons interact with plasmons. An analysis of the scattering process shows that this is not always the case, as light can mix and match different plasmonic pathways.
- Mark Tame
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News & Views |
Spins strain to see the light
Integrating quantum technology with existing telecom infrastructure is hampered by a mismatch in operating frequencies. An optomechanical resonator now offers a strain-mediated spin–photon interface for long-distance quantum networks.
- Lilian Childress
- & Jack Sankey
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Article |
Witnessing quantum correlations in a nuclear ensemble via an electron spin qubit
Atoms in a semiconductor can have non-zero nuclear spins, creating a large ensemble with many quantum degrees of freedom. An electron spin coupled to the nuclei of a semiconductor quantum dot can witness the creation of entanglement within the ensemble.
- Dorian A. Gangloff
- , Leon Zaporski
- & Mete Atatüre
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Article |
Optomechanical interface between telecom photons and spin quantum memory
Quantum networks require a connection between quantum memories and optical links, which often operate in different frequency ranges. An optomechanical device exploiting the strain dependence of a colour-centre spin provides such a spin–optics interface at room temperature.
- Prasoon K. Shandilya
- , David P. Lake
- & Paul E. Barclay
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News & Views |
A light imprint
In a study on high-harmonic generation from a dense atomic xenon gas, the strong-field light–matter interaction is shown to leave a quantum mechanical imprint on the incident light that escapes the semiclassical picture of strong-field physics.
- Thomas Fennel
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Article |
Observation of interband collective excitations in twisted bilayer graphene
Moiré potentials substantially alter the electronic properties of twisted bilayer graphene at a magic twist angle. A propagating plasmon mode, which can be observed with optical nano-imaging, is associated with transitions between the moiré minibands.
- Niels C. H. Hesp
- , Iacopo Torre
- & Frank H. L. Koppens
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News & Views |
Polaritons on a plane
Polaritons are hybrid states of light and matter that occur in a wide range of physical platforms. When a nanosphere is levitated inside an optical cavity, light can hybridize with the motion on a plane rather than along an axis, resulting in ‘vectorial’ polaritons.
- Tania S. Monteiro
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Letter |
Vectorial polaritons in the quantum motion of a levitated nanosphere
A levitated nanosphere that is strongly coupled to an optical cavity mode forms an optomechanical system with three degrees of freedom, which supports hybrid light–mechanical states of a vectorial nature.
- A. Ranfagni
- , P. Vezio
- & F. Marin
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News & Views |
Matryoshka frequency combs
Light propagating in the topological edge channel of an array of ring resonators is predicted to generate nested frequency combs: like a Matryoshka doll containing a set of smaller dolls, each ‘tooth’ of the comb comprises another frequency comb.
- Vittorio Peano
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Article |
Topological frequency combs and nested temporal solitons
Optical frequency combs are a key technology in precision time keeping, spectroscopy and metrology. A theoretical proposal shows that introducing topological principles into their design makes on-chip combs more efficient and robust against fabrication defects.
- Sunil Mittal
- , Gregory Moille
- & Mohammad Hafezi
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Letter |
Coherent spin-wave transport in an antiferromagnet
Ultrashort light pulses generate nanometre-scale wavepackets of magnons that propagate coherently and at high speed in an antiferromagnet. This pushes antiferromagnetic magnonics forward as a future platform for information processing.
- J. R. Hortensius
- , D. Afanasiev
- & A. D. Caviglia
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Comment |
Physics for a better world
The United Nations Sustainable Development Goals outline a roadmap towards a more equitable future for humanity. Along with other scientists, physicists have long made valuable contributions to this endeavour.
- Joseph J. Niemela
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News & Views |
Topology puts solitons in the corner
Nonlinearity and topology are both linked to symmetries, but what happens when the two are combined is not a trivial question. In a nonlinear photonic higher-order topological insulator, solitons localize on the corners together with the topological modes.
- Grazia Salerno
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Letter
| Open AccessNonlinear second-order photonic topological insulators
The nonlinear properties of photonic topological insulators remain largely unexplored, as band topology is linked to linear systems. But nonlinear topological corner states and solitons can form in a second-order topological insulator, as shown by experiments.
- Marco S. Kirsch
- , Yiqi Zhang
- & Matthias Heinrich
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Letter |
Ultrafast switching to an insulating-like metastable state by amplitudon excitation of a charge density wave
Ultrafast optical excitation of a charge density wave leads to the formation of a metastable gapped state that synchronizes with the underlying correlated phase.
- Naotaka Yoshikawa
- , Hiroki Suganuma
- & Ryo Shimano
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Letter |
Absolute 13C/12C isotope amount ratio for Vienna PeeDee Belemnite from infrared absorption spectroscopy
Isotope ratio measurements are complicated by the instabilities of composition in reference samples. Now a calibration-free method relying on infrared spectroscopy provides measurements that are traceable to International System of Units standards.
- Adam J. Fleisher
- , Hongming Yi
- & Joseph T. Hodges
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News & Views |
Polarization out of the vortex
The virtual photons that are exchanged when a free-electron vortex beam interacts with a nanoscopic target unlock an explicit connection between polarized optical spectroscopy and the inelastic scattering of scalar electron waves.
- David J. Masiello
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Article |
Optical polarization analogue in free electron beams
The functionality of electron energy loss spectroscopy can be extended to include a polarization analogue constructed via the dipole transition vector between two electronic states, bringing it closer to its optical counterpart.
- Hugo Lourenço-Martins
- , Davy Gérard
- & Mathieu Kociak
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News & Views |
Multitudes of twists
Multiplexing increases the capacity of optical communication, but it is limited by the number of modes and their orbital angular momentum. A robust vortex laser now solves this problem by emitting several beams, all carrying large topological charges.
- Ren-Min Ma
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Letter |
Photonic quantum Hall effect and multiplexed light sources of large orbital angular momenta
A topological photonic crystal design directly generates light that carries orbital angular momentum with high quantum numbers. The beam contains several different states at the same time, promising integrated and multiplexed light sources.
- Babak Bahari
- , Liyi Hsu
- & Boubacar Kanté
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Letter |
Gain-induced topological response via tailored long-range interactions
Non-Hermitian concepts together with optical gain allow the tailoring of short- and long-range exchange interactions in integrated topological photonics, and an exact Haldane model can be realized in this way.
- Yuzhou G. N. Liu
- , Pawel S. Jung
- & Mercedeh Khajavikhan
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Article |
Emergent nonlinear phenomena in a driven dissipative photonic dimer
A pair of strongly coupled photonic microresonators shows nonlinear emergent behaviour, which can be understood by incorporating interactions in the theoretical description of nonlinear optical systems.
- A. Tikan
- , J. Riemensberger
- & T. J. Kippenberg
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Article |
Probing bulk topological invariants using leaky photonic lattices
Topological materials are characterized by the topological invariants of filled bands, which cannot be used for bosonic systems. Instead, their topological invariants can be found via the transition from bound to leaky modes in photonic lattices.
- Daniel Leykam
- & Daria A. Smirnova