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| Open AccessReply to: Quantum mechanical rules for observed observers and the consistency of quantum theory
- Lídia del Rio
- & Renato Renner
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Article
| Open AccessQuantum simulation of the bosonic Kitaev chain
Interesting non-Hermitian quantum dynamics can be accessed in analogue quantum simulators consisting of Hermitian bosonic systems with squeezing and antisqueezing terms. Here, the authors use a coplanar waveguide resonator connected to a SQUID to simulate the bosonic version of the Kitaev chain.
- Jamal H. Busnaina
- , Zheng Shi
- & Christopher M. Wilson
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Article
| Open AccessAnderson critical metal phase in trivial states protected by average magnetic crystalline symmetry
The authors identify a novel delocalization mechanism for topologically trivial obstructed insulators. In transitioning from two topologically trivial states, where one would expect Anderson’s localization to take place, a delocalized ‘critical metal phase’ appears.
- Fa-Jie Wang
- , Zhen-Yu Xiao
- & Zhi-Da Song
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Matters Arising
| Open AccessQuantum mechanical rules for observed observers and the consistency of quantum theory
- Alexios P. Polychronakos
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Article
| Open AccessThree-dimensional spin-wave dynamics, localization and interference in a synthetic antiferromagnet
The techniques we typically employ to study spin-waves in magnetic materials, such as Brillouin Light Scattering, are two-dimensional. Spin waves, however, are manifestly three-dimensional. Here, Girardi et al. succeed in such three-dimensional imaging of spin waves in a synthetic antiferromagnet using Time-Resolved Soft X-ray Laminography.
- Davide Girardi
- , Simone Finizio
- & Edoardo Albisetti
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Article
| Open AccessFast joint parity measurement via collective interactions induced by stimulated emission
Parity detection is essential in quantum error correction. Here, authors propose a reliable joint parity measurement (JPM) scheme inspired by stimulated emission and experimentally implement the weight-2(4) JPM scheme in a tunable coupling superconducting circuit, which shows comparable performance to the standard CNOT-gate based scheme.
- Sainan Huai
- , Kunliang Bu
- & Yicong Zheng
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Article
| Open AccessWide field-of-hearing metalens for aberration-free sound capture
Achieving a wide angular response in single layer acoustic metalenses is challenging. By leveraging perfect acoustic symmetry conversion, the authors realize an aberration free metalens with a wide field-of-hearing, up to 140 degrees.
- Dongwoo Lee
- , Beomseok Oh
- & Junsuk Rho
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Article
| Open AccessNonlinear optical diode effect in a magnetic Weyl semimetal
Here the authors demonstrate a broadband nonlinear optical diode effect and its electric control in the magnetic Weyl semimetal CeAlSi. Their findings advance ongoing research to identify novel optical phenomena in topological materials.
- Christian Tzschaschel
- , Jian-Xiang Qiu
- & Su-Yang Xu
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Article
| Open AccessFerrielectricity controlled widely-tunable magnetoelectric coupling in van der Waals multiferroics
Two-dimensional multiferroics with effective magnetoelectric coupling has not been realized. Here, the authors find a magnetoelectric coupling mechanism in two-dimensional CuCrP2S6 interlocked with heterogeneous ferrielectric state.
- Qifeng Hu
- , Yuqiang Huang
- & Yi Zheng
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Article
| Open AccessThermodiffusive desalination
Current desalination technologies are energy intensive and suffer from membrane degradation and fouling. Here, authors propose and explore the potential of thermodiffusion as a means of membrane-free, single-phase thermal desalination. A pathway towards a feasible thermodiffusive desalination is provided.
- Shuqi Xu
- , Alice J. Hutchinson
- & Juan F. Torres
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Article
| Open AccessAsymmetric magnetization switching and programmable complete Boolean logic enabled by long-range intralayer Dzyaloshinskii-Moriya interaction
The authors find a magnetization switching mechanism and the long-range intralayer Dzyaloshinskii-Moriya interaction effect, which enables asymmetric magnetization switching and complete Boolean logic operations.
- Qianbiao Liu
- , Long Liu
- & Lijun Zhu
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Article
| Open AccessThe impact of low-mode symmetry on inertial fusion energy output in the burning plasma state
Recent improvements in the indirect-drive inertial confinement fusion experiments include the achievement of burning plasma state. Here the authors report the scaling of neutron yield in a burning plasma of Deuterium-Tritium fusion reaction by including the mode-2 asymmetry.
- J. E. Ralph
- , J. S. Ross
- & G. B. Zimmerman
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Article
| Open AccessEmissive brightening in molecular graphene nanoribbons by twilight states
The authors demonstrate that the band structure of graphene nanoribbons is modulated by cove edges, brightening the luminescence 4-fold via emission from otherwise dark twilight states. High spectral resolution of the optical response reveals strong vibron-electron coupling
- Bernd K. Sturdza
- , Fanmiao Kong
- & Robin J. Nicholas
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Article
| Open AccessRewritable printing of ionic liquid nanofilm utilizing focused ion beam induced film wetting
With a helium focused ion beam, an ionic liquid can undergo induced wetting to flow into a desired pattern on a surface in a controllable, rewriteable manner. Combined with electrochemical deposition, patterned solid materials can be produced.
- Haohao Gu
- , Kaixin Meng
- & Hao Wang
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Article
| Open AccessCompact meta-differentiator for achieving isotropically high-contrast ultrasonic imaging
High-contrast ultrasonic imaging holds significant importance in biomedical and engineering applications. Here, the authors present a compact spatial differentiator tailored for underwater isotropic edge-enhanced imaging, facilitating the realization of high-contrast ultrasonic imaging.
- Yurou Jia
- , Suying Zhang
- & Xiaojun Liu
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Article
| Open AccessObservation of Kekulé vortices around hydrogen adatoms in graphene
Kekulé vortices in hexagonal lattices can host fractionalized charges at zero magnetic field, but have remained out of experimental reach. Here, the authors report a Kekulé vortex in the local density states of graphene around a chemisorbed hydrogen adatom.
- Yifei Guan
- , Clement Dutreix
- & Vincent T. Renard
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Article
| Open AccessIntercavity polariton slows down dynamics in strongly coupled cavities
Band engineering in optics allows the design of unconventional forms of light with potential optoelectronic applications. Here, the authors realize slow-light intercavity polaritons in an array of coupled cavities, the photonic architecture enables the spatial segregation of photons and excitons
- Yesenia A. García Jomaso
- , Brenda Vargas
- & Giuseppe Pirruccio
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Article
| Open AccessAluminum corrosion–passivation regulation prolongs aqueous batteries life
Aqueous batteries have a short lifespan due to Al current collector corrosion and Li loss from side reactions on the anode. Here, the authors propose a prototype of self-prolonging aqueous Li-ion batteries by introducing hydrolyzation-type anodic additives to regulate Al corrosion-passivation.
- Binghang Liu
- , Tianshi Lv
- & Liumin Suo
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Article
| Open AccessSwitching the spin cycloid in BiFeO3 with an electric field
Previous understanding of the coupling between ferroelectric structure and magnetic texture in BiFeO3 has relied on mesoscale measurements. Here, the authors image coupling directly, showing a complex spin cycloid controlled with electric field.
- Peter Meisenheimer
- , Guy Moore
- & Ramamoorthy Ramesh
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Article
| Open AccessIntrinsic exchange biased anomalous Hall effect in an uncompensated antiferromagnet MnBi2Te4
Exchange bias occurs in a variety of magnetic materials and heterostructures. The quintessential example occurs in antiferromagnetic/ferromagnetic heterostructures and has been employed extensively in magnetic memory devices. Here, via a specific field training protocol, the authors demonstrate an exchange bias of up to 400mT in odd layered MnBi2Te4.
- Su Kong Chong
- , Yang Cheng
- & Kang L. Wang
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Article
| Open AccessShaping active matter from crystalline solids to active turbulence
Earlier research has shown that controlling activity in the active matter can lead to either a phase change or a laminar-turbulent transition in active fluids. Authors demonstrate that it is possible to control both the phase transitions between solid, liquid, and gas states and the laminar-to-turbulent transitions in fluid phases by adjusting the activity of a phoretic medium.
- Qianhong Yang
- , Maoqiang Jiang
- & Lailai Zhu
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Article
| Open AccessEnhanced polarization switching characteristics of HfO2 ultrathin films via acceptor-donor co-doping
Ferroelectric HfO2 is faced with an oxygen vacancy dilemma, which favors the polar phase but harm to switching behaviors. Here, the authors propose a donor-acceptor co-doping method to enhance polarization switching characteristics of the HfO2 films.
- Chao Zhou
- , Liyang Ma
- & Zuhuang Chen
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Article
| Open AccessEnhancement of electrocatalysis through magnetic field effects on mass transport
Magnetic fields can enhance electrocatalysis, yet its effect on mass transport has been overlooked. Here, the authors track the motion induced on the electrolyte ions, demonstrating that mass transport effects can double the catalyst activity with low reactant availability, as in oxygen reduction.
- Priscila Vensaus
- , Yunchang Liang
- & Magalí Lingenfelder
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Article
| Open AccessUltrafast photoinduced C-H bond formation from two small inorganic molecules
The formation of C–H bonds via reaction of small inorganic molecules is of great interest for understanding the transition from inorganic to organic matter, but the detailed mechanisms remain elusive. Here, the authors demonstrate real-time visualization and coherent control of the ultrafast C–H bond formation dynamics in a light-induced bimolecular reaction from inorganic species.
- Zhejun Jiang
- , Hao Huang
- & Jian Wu
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Article
| Open AccessPassive frequency comb generation at radiofrequency for ranging applications
In contrast to the commonly studied optical frequency combs, here, the authors demonstrate a radio frequency system able to wirelessly and passively generate frequency combs as a battery-free solution for far-field ranging of unmanned vehicles in GPS-denied settings.
- Hussein M. E. Hussein
- , Seunghwi Kim
- & Cristian Cassella
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Article
| Open AccessReconstructing the evolution history of networked complex systems
Evolution processes of complex networked systems in biology and social sciences, and their underlying mechanisms, still need better understanding. The authors propose a machine learning approach to reconstruct the evolution history of complex networks.
- Junya Wang
- , Yi-Jiao Zhang
- & Yanqing Hu
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Article
| Open AccessThree-stage ultrafast demagnetization dynamics in a monolayer ferromagnet
Ultrafast demagnetization refers to the process where an intense optical drive can destroy the magnetic order in a magnetic material on a femto-second timescale. Here, Wu et al resolve a three-stage ultrafast demagnetization process in a monolayer of Fe3GeTe2.
- Na Wu
- , Shengjie Zhang
- & Sheng Meng
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Article
| Open AccessDeuteration-enhanced neutron contrasts to probe amorphous domain sizes in organic photovoltaic bulk heterojunction films
The use of conventional X-ray scattering techniques is challenging to detect donor-acceptor contrast within amorphous intermixing regions. Here, the authors apply neutron scattering and targeted deuteration to enhance the contrast by one order of magnitude and reveal short-range aggregations of d-Y6.
- Guilong Cai
- , Yuhao Li
- & Xinhui Lu
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Article
| Open AccessCorrelating fluorescence microscopy, optical and magnetic tweezers to study single chiral biopolymers such as DNA
It is hard to correlate force, torque and localization information. The authors report Combined Optical and Magnetic BIomolecule TWEEZers, COMBI-Tweez, that integrates optical trapping, time-resolved electromagnetic tweezers, and fluorescence microscopy: they demonstrate visualisation of higher order structural motifs in DNA.
- Jack W. Shepherd
- , Sebastien Guilbaud
- & Mark C. Leake
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Article
| Open AccessEnhancing combinatorial optimization with classical and quantum generative models
Solving combinatorial optimization problems using quantum or quantum-inspired machine learning models would benefit from strategies able to work with arbitrary objective functions. Here, the authors use the power of generative models to realise such a black-box solver, and show promising performances on some portfolio optimization examples.
- Javier Alcazar
- , Mohammad Ghazi Vakili
- & Alejandro Perdomo-Ortiz
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Article
| Open AccessReversible non-volatile electronic switching in a near-room-temperature van der Waals ferromagnet
The controlled manipulation of the topological phases of electronic materials is a central goal of modern condensed matter research. Here, the authors demonstrate controllable switching between two distinct topological phases in a layered ferromagnet via thermal cycling.
- Han Wu
- , Lei Chen
- & Ming Yi
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Article
| Open AccessCharge state-dependent symmetry breaking of atomic defects in transition metal dichalcogenides
The microscopic structure of quantum defects in 2D materials is crucial to understand their optical properties and spin-photon interface. Here, the authors report the direct imaging of charge state-dependent symmetry breaking of sulfur vacancies and rhenium dopants in 2D MoS2, showing evidence of a Jahn-Teller effect.
- Feifei Xiang
- , Lysander Huberich
- & Bruno Schuler
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Article
| Open AccessRaman time-delay in attosecond transient absorption of strong-field created krypton vacancy
The advent of isolated attosecond XUV pulse sources marks a new era in attosecond science, pivotal for the investigation of core electron dynamics. Here the authors discover that the coherent Raman coupling between the cation states leads to extra timedelay between different transition channels by applying the attosecond transient absorption spectroscopy on the investigation of complex dynamics of strong field ionization of Krypton.
- Li Wang
- , Guangru Bai
- & Zengxiu Zhao
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Article
| Open AccessStrongly interacting Rydberg atoms in synthetic dimensions with a magnetic flux
Weak and non-interacting systems have been previously explored in synthetic dimensions. Here the authors demonstrate strong atomic interaction in synthetic dimensions using an array of Rydberg atoms.
- Tao Chen
- , Chenxi Huang
- & Bryce Gadway
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Article
| Open AccessBenchtop mesoSPIM: a next-generation open-source light-sheet microscope for cleared samples
The demand to image large biological samples at high resolution requires improvement in current light-sheet microscopy tools. Here, the authors present an improved, benchtop mesoSPIM with a significantly increased field-of-view, improved resolution and improved throughput.
- Nikita Vladimirov
- , Fabian F. Voigt
- & Fritjof Helmchen
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Article
| Open AccessTopological minibands and interaction driven quantum anomalous Hall state in topological insulator based moiré heterostructures
Moiré patterns have been experimentally observed in heterostructures comprised of topological insulator films. Here, the authors propose that topological insulator-based moiré heterostructures could be a host of isolated topologically non-trivial moiré minibands for the study of the interplay between topology and correlation.
- Kaijie Yang
- , Zian Xu
- & Chao-Xing Liu
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Article
| Open AccessVelocities of transmission eigenchannels and diffusion
Wave scattering can be described with a diffusion model in which the velocity is randomized by scattering. Here the authors find that the velocities of different transmission eigenchannels are distinct on all length scales.
- Azriel Z. Genack
- , Yiming Huang
- & Zhou Shi
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Article
| Open AccessDemonstration of hypergraph-state quantum information processing
Usual multiqubit entangled states can be described using the graph formalism, where each edge connects only two qubits. Here, instead, the authors use a reprogrammable silicon photonics chip to showcase preparation, verification and processing of arbitrary four-qubit hypergraph states, where hyperedges describe entanglement within a subset of many qubits.
- Jieshan Huang
- , Xudong Li
- & Jianwei Wang
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Article
| Open AccessDefect-induced helicity dependent terahertz emission in Dirac semimetal PtTe2 thin films
Defect engineering of topological materials provides an avenue for the controllable manipulation of optoelectronic properties. Here, the authors introduce a defect gradient into a Dirac semimetal to control the Berry curvature dipole-driven THz emission in the material.
- Zhongqiang Chen
- , Hongsong Qiu
- & Xuefeng Wang
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Article
| Open AccessDynamical order and many-body correlations in zebrafish show that three is a crowd
Active matter systems, such as zebrafish groups, demonstrate similar collective dynamics to assemblies of particles, or interacting agents. The authors show that majority of dynamics patterns seen in large zebrafish groups are exhibited by a minimal group of three fish.
- Alexandra Zampetaki
- , Yushi Yang
- & C. Patrick Royall
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Article
| Open AccessLayer-polarized ferromagnetism in rhombohedral multilayer graphene
Rhombohedral multilayer graphene has emerged as an exciting solid-state platform for studying correlated electron physics. Here, the authors demonstrate field-tunable layer-polarized ferromagnetism and isolated surface flat bands engineered with a moiré potential.
- Wenqiang Zhou
- , Jing Ding
- & Shuigang Xu
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Article
| Open AccessEffective light cone and digital quantum simulation of interacting bosons
Studying bounds on the speed of information propagation across interacting boson systems is notoriously difficult. Here, the authors find tight bounds for both the transport of boson particles and information propagation, for arbitrary time-dependent Bose-Hubbard-type Hamiltonians in arbitrary dimensions.
- Tomotaka Kuwahara
- , Tan Van Vu
- & Keiji Saito
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Article
| Open AccessUniversal control of a bosonic mode via drive-activated native cubic interactions
Manipulating quantum information encoded in a bosonic mode requires sizeable and controllable nonlinearities, but superconducting devices’ strong nonlinearities are normally static. Here, the authors use a SNAIL to suppress static nonlinearities and use drive-dependent ones to reach universal control of a bosonic mode.
- Axel M. Eriksson
- , Théo Sépulcre
- & Simone Gasparinetti
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Article
| Open AccessElectrically driven amplification of terahertz acoustic waves in graphene
Electron–phonon interactions are a crucial aspect of high-quality graphene devices. Here, the authors show that graphene resistivity grows strongly in the direction of the carrier flow when the drift velocity exceeds the speed of sound due to the electrical amplification of acoustic terahertz phonons.
- Aaron H. Barajas-Aguilar
- , Jasen Zion
- & Javier D. Sanchez-Yamagishi
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Article
| Open AccessDirect visualization of stacking-selective self-intercalation in epitaxial Nb1+xSe2 films
The interplay between stacking configurations and atom intercalation in van der Waals materials has been rarely characterized at the microscopic level. Here, the authors report an electron microscopy study of stacking-selective self-intercalation in Nb1+xSe2 films, showing potential for nanoscale engineering of electronic properties in van der Waals materials and devices.
- Hongguang Wang
- , Jiawei Zhang
- & Hidenori Takagi
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Article
| Open AccessToward sub-second solution exchange dynamics in flow reactors for liquid-phase transmission electron microscopy
In liquid-phase TEM, microfluidic reactors are used to monitor nanoscale (electro)chemical dynamics in liquid environments. Here, the authors develop a reactor design with accelerated mass transport, facilitating quantitative in-situ and in-operando studies.
- Stefan Merkens
- , Christopher Tollan
- & Andrey Chuvilin
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Article
| Open AccessDynamics of the charge transfer to solvent process in aqueous iodide
Solvated electrons can be formed through photo-induced charge-transfer-to-solvent electronic states of halide ions in water. Here, the authors use machine learning accelerated molecular dynamics simulations to follow the evolution of these states for aqueous iodide in detail.
- Jinggang Lan
- , Majed Chergui
- & Alfredo Pasquarello
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Article
| Open AccessHigher-order Granger reservoir computing: simultaneously achieving scalable complex structures inference and accurate dynamics prediction
For reservoir computing, improving prediction accuracy while maintaining low computing complexity remains a challenge. Inspired by the Granger causality, Li et al. design a data-driven and model-free framework by integrating the inference process and the inferred results on high-order structures.
- Xin Li
- , Qunxi Zhu
- & Wei Lin
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Article
| Open AccessStructural phase transition, s±-wave pairing, and magnetic stripe order in bilayered superconductor La3Ni2O7 under pressure
Recently superconductivity with Tc of about 80 K was discovered in a bilayer nickelate La3Ni2O7 under high pressure. Here the authors report a density functional theory and random phase approximation study of structural and electronic properties as a function of pressure and discuss the pairing mechanism.
- Yang Zhang
- , Ling-Fang Lin
- & Elbio Dagotto
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