Article
|
Open Access
Featured
-
-
Article
| Open AccessLarge out-of-plane spin–orbit torque in topological Weyl semimetal TaIrTe4
Topological semimetals offer the potential for new-generation spintronic devices. Here, the authors demonstrate a large out-of-plane damping-like spin–orbit torque efficiency in a heterostructure based on the Weyl semimetal TaIrTe4.
- Lakhan Bainsla
- , Bing Zhao
- & Saroj P. Dash
-
Article
| Open AccessMemristor-based adaptive neuromorphic perception in unstructured environments
Perception methods that enable control systems to understand and adapt to unstructured environments are desired. Wang et. al. develop a memristor-based differential neuromorphic computing, perceptual signal processing, and online adaptation method providing neuromorphic style adaptation to external sensory stimuli.
- Shengbo Wang
- , Shuo Gao
- & Luigi Giuseppe Occhipinti
-
Article
| Open AccessA zinc oxide resonant nano-accelerometer with ultra-high sensitivity
The authors report a zinc oxide resonant nano-accelerometer with sensitivity up to 16.818 kHz/g, which is attributed to the nano-resonators using zinc oxide nanowires and the optimized microleverages and push-pull structures.
- Pengfei Xu
- , Dazhi Wang
- & Yan Cui
-
Article
| Open AccessThe quantum geometric origin of capacitance in insulators
The authors reveal a link between the quantum metric and the dielectric constant of insulators, determining the geometric capacitance of insulators and revealing the intrinsic delocalization of electrons in the lattice.
- Ilia Komissarov
- , Tobias Holder
- & Raquel Queiroz
-
Article
| Open AccessX-ray radiation damage cycle of solvated inorganic ions
A radiation damage cycle in X-ray-ionized solvated Mg ions is reported by the authors leading to production of water radicals and low-energy electrons. The Mg ion ends in its initial state quickly and can restart the cycle, multiplying the local damage.
- Dana Bloß
- , Florian Trinter
- & Andreas Hans
-
Article
| Open AccessThe observation of π-shifts in the Little-Parks effect in 4Hb-TaS2
The authors report the measurement of the Little-Parks effect in the unconventional superconductor candidate 4Hb-TaS2. They find a π-shift in the transition-temperature oscillations and an ehancement of Tc as a function of the out-of-plane field when a constant in-plane field is applied, consistent with a multi-component order parameter.
- Avior Almoalem
- , Irena Feldman
- & Amit Kanigel
-
Article
| Open AccessPhotoinduced dynamics during electronic transfer from narrow to wide bandgap layers in one-dimensional heterostructured materials
One-dimensional van der Waals heterostructures can realize atomically thin transistor junctions. Here, the authors study electron transfer in such layered structures using ultrafast diffraction and spectroscopy as well as theoretical simulations.
- Yuri Saida
- , Thomas Gauthier
- & Masaki Hada
-
Article
| Open AccessReliable wafer-scale integration of two-dimensional materials and metal electrodes with van der Waals contacts
2D semiconductors may offer a platform for future electronics, but the wafer-scale fabrication of high-performance 2D transistors remains challenging. Here, the authors report a universal all-stacking method to fabricate wafer-scale 2D electronic devices with van der Waals contacts, based on epitaxial metallic electrodes grown on fluorophlogopite mica.
- Xiaodong Zhang
- , Chenxi Huang
- & Hualing Zeng
-
Article
| Open AccessObservation of the photonic Hall effect and photonic magnetoresistance in random lasers
This work reveals the presence of the photonic Hall effect and photonic magnetoresistance in a field-dependent random laser. This observation visualizes the influence of magnetic field on random lasers scattering at the microscopic level.
- Wenyu Du
- , Lei Hu
- & Zhijia Hu
-
Article
| Open AccessMomentum-dependent scaling exponents of nodal self-energies measured in strange metal cuprates and modelled using semi-holography
Strange metal behaviour of high-Tc superconductors, characterised by unconventional electrical and thermodynamic properties, still poses challenges for theory. Smit et al. report experimental features in the self-energy of a strange metal that are consistent with predictions by holographic theoretical methods.
- S. Smit
- , E. Mauri
- & M. S. Golden
-
Article
| Open AccessActive ballistic orbital transport in Ni/Pt heterostructure
The authors observe THz emission from Ni/Pt heterostructure due to long-range ballistic orbital transport. The velocity of orbital current can be optically tuned by laser fluence, opening the avenue for future optorbitronic devices.
- Sobhan Subhra Mishra
- , James Lourembam
- & Ranjan Singh
-
Article
| Open AccessObservation of phonon Stark effect
The authors report experimental evidence of phonon Stark effect in 2H-MoS2 bilayers. A Stark phonon appears as the interlayer excitons are tuned to resonate with the LA phonon emission line, and shows a linear energy shift upon application of an out-of-plane electric field.
- Zhiheng Huang
- , Yunfei Bai
- & Guangyu Zhang
-
Article
| Open AccessRemote sensing of emperor penguin abundance and breeding success
Emperor penguins colony occupancy is variable and chiefly estimated with remote sensing images at end of the breeding season. Here, the authors provide a phenological model that can extrapolate occupancy from sparse data and can predict phenological events, breeding pairs and fledging chicks.
- Alexander Winterl
- , Sebastian Richter
- & Daniel P. Zitterbart
-
Article
| Open AccessReversible flexoelectric domain engineering at the nanoscale in van der Waals ferroelectrics
Flexoelectric effect may offer a voltage-free method to control the polarization in 2D ferroelectrics, but its widespread application remains challenging. Here, the authors report an approach to arbitrarily switch the ferroelectricity in 2D CuInP2S6.
- Heng Liu
- , Qinglin Lai
- & Hualing Zeng
-
Article
| Open AccessSemi-classical origin of the extreme magnetoresistance in PtSn4
Extreme magnetoresistance (XMR) is the name assigned to the large and non-saturating magnetoresistance that occurs in some metals and semi-metals. In this work, the authors demonstrate the first material, PtSn4, in which XMR can be switched off by changing the direction of the magnetic field.
- J. Diaz
- , K. Wang
- & P. J. W. Moll
-
Article
| Open AccessARPES detection of superconducting gap sign in unconventional superconductors
According to conventional wisdom, angle-resolved photoemission spectroscopy (ARPES) can only measure the magnitude of the superconducting gap but not its phase. Here, the authors propose a new method to directly detect the superconducting gap phase using ARPES and validate this technique on a cuprate superconductor.
- Qiang Gao
- , Jin Mo Bok
- & X. J. Zhou
-
Article
| Open AccessQuantum barriers engineering toward radiative and stable perovskite photovoltaic devices
Efficient radiation is essential to reach thermodynamic limit of photovoltaic efficiency. Here, authors design thick quantum barriers to suppress interfacial quenching and boost photon recycling in perovskite cells, achieving high radiation and photovoltaic efficiencies and long device stability.
- Kyung Mun Yeom
- , Changsoon Cho
- & Jun Hong Noh
-
Article
| Open AccessDomain wall magnetic tunnel junction-based artificial synapses and neurons for all-spin neuromorphic hardware
The authors demonstrate all-spin synapses and neurons using domain wall-magnetic tunnel junctions, utilizing synergistic spin-orbit torque and Dzyaloshinskii-Moriya interaction. The intrinsic linearity is required for compact and energy-efficient bio-inspired hardware for neuromorphic computing.
- Long Liu
- , Di Wang
- & Ming Liu
-
Article
| Open AccessProgrammable quantum emitter formation in silicon
Quantum emitters in Si show promise for applications in quantum information processing and communication due to their potential as spin-photon interfaces. Jhuria et al. report the formation of selected telecom emitters in Si using local writing and erasing by fs laser pulses and annealing in a hydrogen atmosphere.
- K. Jhuria
- , V. Ivanov
- & T. Schenkel
-
Article
| Open AccessIntermittency in the not-so-smooth elastic turbulence
Intermittency is the behavior of extreme fluctuations observed in the flow of a fluid that is often associated with high Reynolds numbers. Here, the authors report intermittency in elastic turbulence at the low Reynolds number and high Deborah number limit.
- Rahul K. Singh
- , Prasad Perlekar
- & Marco E. Rosti
-
Article
| Open AccessZero-field J-spectroscopy of quadrupolar nuclei
Zero to ultralow-field NMR provides chemical information in the absence of a high magnetic field but it is difficult to measure molecules with quadrupolar nuclei due to their fast relaxation. This study examines zero-field J-spectra from isotopologues of ammonium cations, with quadrupolar nuclei, revealing the presence of a primary isotope effect of −58 mHz.
- Román Picazo-Frutos
- , Kirill F. Sheberstov
- & Danila A. Barskiy
-
Article
| Open AccessInhomogeneous high temperature melting and decoupling of charge density waves in spin-triplet superconductor UTe2
Understanding the physics of charge density waves in emerging superconductors may reveal insights into unconventional superconductivity mechanisms. Here, the authors study the temperature and magnetic-field dependence of charge-density-wave suppression in the unconventional superconductor UTe2.
- Alexander LaFleur
- , Hong Li
- & Ilija Zeljkovic
-
Article
| Open AccessDuality between predictability and reconstructability in complex systems
Reconstructing the structure of a complex networked system and predicting its time evolution to understand its functions are usually two subjects that are treated separately. The authors propose a theoretical framework based on information theory, that uncovers the relation between reconstructability and predictability in networked systems.
- Charles Murphy
- , Vincent Thibeault
- & Patrick Desrosiers
-
Article
| Open AccessAbove-room-temperature chiral skyrmion lattice and Dzyaloshinskii–Moriya interaction in a van der Waals ferromagnet Fe3−xGaTe2
There are now several van der Waals magnets that have been shown to host skyrmions, however, these are typically hampered by a low Curie temperature, restricting the temperature at which the skyrmions can exist. Here, Zhang, Jiang, Jiang and coauthors find a skyrmion lattice in the van der Waals magnet Fe3 − xGaTe2 above room temperature and demonstrate the critical role of symmetry breaking in crystal lattice in the origin of these skyrmions.
- Chenhui Zhang
- , Ze Jiang
- & Hyunsoo Yang
-
Article
| Open AccessEnhancement of phase transition temperature through hydrogen bond modification in molecular ferroelectrics
The authors propose a hydrogen bond modification method to achieve introduction of polarization and enhancement of phase transition temperature in molecular ferroelectrics, exploring the piezoelectric prototype devices of the molecular ferroelectric.
- Yu-An Xiong
- , Sheng-Shun Duan
- & Yu-Meng You
-
Article
| Open AccessAnomalous behavior of critical current in a superconducting film triggered by DC plus terahertz current
The authors study the [Nb/V/Ta] superconducting artificial superlattice, known to support a superconducting diode effect, by pulsed THz spectroscopy and simultaneous transport. They found a non-monotonic switching between the superconducting and normal state, which can be explained if the THz-driven vortex depinning determines the critical current.
- Fumiya Sekiguchi
- , Hideki Narita
- & Yoshihiko Kanemitsu
-
Article
| Open AccessHigh-power electrically pumped terahertz topological laser based on a surface metallic Dirac-vortex cavity
The researchers showcase an exciting surface metallic Dirac-vortex cavity design with enhanced power capabilities for electrically pumped Topological Lasers in the THz spectral range.
- Junhong Liu
- , Yunfei Xu
- & Shenqiang Zhai
-
Article
| Open AccessHybrid architectures for terahertz molecular polaritonics
Metasurface-based architectures enhance light-matter interactions between a terahertz photonic mode and glucose vibrational resonance. This platform allows new physical and chemical properties of hybrid light-matter states to be exploited.
- Ahmed Jaber
- , Michael Reitz
- & Jean-Michel Ménard
-
Article
| Open AccessUltrafast all-optical toggle writing of magnetic bits without relying on heat
Toggle switching refers to the switching of magnetization induced by a train of ultrashort laser pulses. The high speed make such switching in extremely promising for devices, however, the underlying toggle switching mechanism in metals is due to heating, and thus has a downside of dissipation. Here, Zalewski et al demonstrate ultrafast ‘cold’ toggle switching, with a mechanism that does not rely on heating in dielectric Cobalt doped Yittrium Iron Garnet.
- T. Zalewski
- , A. Maziewski
- & A. Stupakiewicz
-
Article
| Open AccessMolecular orbital breaking in photo-mediated organosilicon Schiff base ferroelectric crystals
Switchable structural and physical bistability in ferroelectric materials can be achieved as result of molecular orbital breaking. Here, the authors describe the photo-mediated bistability in organosilicon Schiff base ferroelectric crystals for the modulation of dielectric, second-harmonic generation, and ferroelectric polarization and showing good in vitro biocompatibility.
- Zhu-Xiao Gu
- , Nan Zhang
- & Han-Yue Zhang
-
Article
| Open AccessTunnel junctions based on interfacial two dimensional ferroelectrics
The authors study tunneling junctions in rhombohedral MoS2 bilayers and correlate their performance with the local domain layout. They show that the switching behavior in sliding ferroelectrics is strongly dependent on the pre-existing domain structure.
- Yunze Gao
- , Astrid Weston
- & Roman Gorbachev
-
Article
| Open AccessSelf acceleration from spectral geometry in dissipative quantum-walk dynamics
The strong connection between the dynamics of a physical system and its Hamiltonian’s spectrum has scarcely been applied in the non-Hermitian case. Here, the authors use a photonic quantum walk to confirm and expand previous theoretical analyses connecting self-acceleration dynamics with non-trivial point-gap topology.
- Peng Xue
- , Quan Lin
- & Wei Yi
-
Article
| Open AccessRashba-splitting-induced topological flat band detected by anomalous resistance oscillations beyond the quantum limit in ZrTe5
Topological flat bands offer a solid-state platform for studying the interplay between topology and electron correlations. Here, the authors demonstrate that a prototypical 3D Dirac material can host topological flat bands under magnetic fields due to polar-distortion-assisted Rashba splitting.
- Dong Xing
- , Bingbing Tong
- & Cheng-Long Zhang
-
Article
| Open AccessLink between supercurrent diode and anomalous Josephson effect revealed by gate-controlled interferometry
The authors study the intrinsic superconducting diode effect (SDE) in a single Josephson junction consisting of a InGaAs/InAs/InGaAs quantum well as the weak link, and an Al film as the superconductor. They find a correspondence between SDE and an offset in the relationship between critical current and the difference in phase of the superconducting order parameter across the junction.
- S. Reinhardt
- , T. Ascherl
- & N. Paradiso
-
Article
| Open AccessHighly tunable ground and excited state excitonic dipoles in multilayer 2H-MoSe2
Here, the authors discover the ground and excited state interlayer excitons in bi- and tri-layer 2H-MoSe2 crystals which exhibit electric-field-driven hybridisation with the intralayer A excitons, showing distinct spin, layer and valley characteristics.
- Shun Feng
- , Aidan J. Campbell
- & Brian D. Gerardot
-
Article
| Open AccessReal-time observation of two distinctive non-thermalized hot electron dynamics at MXene/molecule interfaces
Photoexcited MXenes could transfer charge carriers to or heat molecules at their interfaces. Here, the authors show using time-resolved spectroscopy that the non-thermalized carriers can directly transfer to molecules or heat them within 125 fs.
- Qi Zhang
- , Wei Li
- & Xueming Yang
-
Article
| Open AccessOrigin of the light-induced spin currents in heavy metal/magnetic insulator bilayers
The authors study the light-induced spin current observed in W/Y3Fe5O12 heterojunctions, elucidating the photo-generated spin current, rather than light-thermally induced spin current, by photon-magnon interaction.
- Hongru Wang
- , Jing Meng
- & Lin Sun
-
Article
| Open AccessIntermolecular interactions probed by rotational dynamics in gas-phase clusters
The authors demonstrate, using coincident Coulomb explosion imaging, that the rotational dynamics of single nitrogen molecules can be used as a probe to sense the interactions with surrounding Ar atoms in gas-phase clusters.
- Chenxu Lu
- , Long Xu
- & Jian Wu
-
Article
| Open AccessRevealing the mechanism and function underlying pairwise temporal coupling in collective motion
It is known that spatially localized interactions can give rise to self-organized collective motion. Here, by studying pairwise interactions in juvenile zebrafish, authors reveal the role of reciprocal temporal coupling and find that temporal coordination considerably improves spatial responsiveness, such as reacting to changes in the direction of motion of a partner.
- Guy Amichay
- , Liang Li
- & Iain D. Couzin
-
Article
| Open AccessEmergent disorder and mechanical memory in periodic metamaterials
Frustrated magnetic systems typically have multiple ground state configurations. While such multistability is common in amorphous materials, periodic mechanical systems have long range elastic interactions that tend to lead to a long-range ordered ground state. Herein, Sirote-Katz, Shohat et al. introduce periodic mechanical systems that have many disordered metastable states.
- Chaviva Sirote-Katz
- , Dor Shohat
- & Yair Shokef
-
Article
| Open AccessUncovering the spin ordering in magic-angle graphene via edge state equilibration
The hierarchy of symmetry breaking in magic-angle twisted bilayer graphene remains a topic of intense fundamental study. Here, the authors determine the spin polarization of symmetry-broken quantum Hall states and Chern insulators in MATBG using a twist-decoupled graphene probe.
- Jesse C. Hoke
- , Yifan Li
- & Benjamin E. Feldman
-
Article
| Open AccessMassive, long-lived electrostatic potentials in a rotating mirror plasma
In open-field-line magnetic plasma traps, the attainable cross-field voltage drops are limited by the tolerances of the solid materials of the vacuum vessel. Here, the authors demonstrate the possibility of equilibria that isolate large voltage drops to the interior of the plasma, circumventing this limit.
- E. J. Kolmes
- , I. E. Ochs
- & N. J. Fisch
-
Article
| Open AccessActive transcription and epigenetic reactions synergistically regulate meso-scale genomic organization
Chromatin within interphase nuclei forms compacted nanoscale DNA domains of uniform size. By integrating theory and imaging, here the authors show how the interplay between transcription and epigenetic mechanisms determine this size, independent of cell type.
- Aayush Kant
- , Zixian Guo
- & Vivek B. Shenoy
-
Article
| Open AccessFiring feature-driven neural circuits with scalable memristive neurons for robotic obstacle avoidance
The authors proposed a strategy for sensorimotor control using memristive H-H neurons, integrating bio-inspired neural circuits and computational capabilities of neurons’ firing features with a robot for avoidance control.
- Yue Yang
- , Fangduo Zhu
- & Ming Liu
-
Article
| Open AccessDigital non-Foster-inspired electronics for broadband impedance matching
Resonance-based systems such as electroacoustic transducers are often limited by narrow bandwidth. Here, authors report a digital non-Foster inspired circuit demonstrating significant bandwidth and power level enhancement with greater reconfigurability than conventional analog non-Foster approaches.
- Xin Yang
- , Zhihe Zhang
- & Andrea Alù
-
Article
| Open AccessTowards silent and efficient flight by combining bioinspired owl feather serrations with cicada wing geometry
This study unveils a synergistic bioinspired design, seamlessly merging owl feather and cicada wing geometries into propeller configurations. Authors achieve reduction in noise by up to 5.5 dB while boosting aerodynamic efficiency by over 20% compared to current industry standards.
- Zixiao Wei
- , Stanley Wang
- & Grace X. Gu
-
Article
| Open AccessExplainable chemical artificial intelligence from accurate machine learning of real-space chemical descriptors
Chemical AI often behaves as a black box, providing accurate, but opaque, predictions. Here, the authors show that the synergy of cutting-edge ANNs with the rigor of Quantum Chemical Topology can result in Explainable Chemical AI (XCAI).
- Miguel Gallegos
- , Valentin Vassilev-Galindo
- & Alexandre Tkatchenko
-
Article
| Open AccessAntiferromagnetic magnonic charge current generation via ultrafast optical excitation
Néel spin-orbit torques arise due to charge currents in some antiferromagnets, and have sparked interest as a possible pathway for achieving electrical control of antiferromagnetic order. While the driving of antiferromagnetic order by Néel spin-orbit torques is now experimentally well established, the inverse process, where magnetic excitations in an antiferromagnetic drive a charge current is not reported. Here Huang, Liao, Qiu, and coauthors observe this inverse process in an Mn2Au thin film.
- Lin Huang
- , Liyang Liao
- & Cheng Song
-
Article
| Open AccessNon-coplanar helimagnetism in the layered van-der-Waals metal DyTe3
Helimagnetic materials host a twisted magnetic texture, realizing screws, cycloids, and cones. While helimagnets are common in three dimensional materials, layered van der Waals helimagnets are exceedingly rare. Here, Akatsuka et al. demonstrate conical ordering in the easily cleavable magnet DyTe3.
- Shun Akatsuka
- , Sebastian Esser
- & Max Hirschberger
Browse broader subjects
Browse narrower subjects
- Applied physics
- Astronomy and astrophysics
- Atomic and molecular physics
- Biological physics
- Chemical physics
- Condensed-matter physics
- Electronics, photonics and device physics
- Fluid dynamics
- Information theory and computation
- Nuclear physics
- Optical physics
- Particle physics
- Plasma physics
- Quantum physics
- Space physics
- Statistical physics, thermodynamics and nonlinear dynamics
- Techniques and instrumentation