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Three-dimensional high-resolution quantitative microscopy of extended crystals
X-ray ptychography has been used to extend the field of view in high-resolution quantitative imaging. Godardet al. develop Bragg-mode ptychography to reconstruct, in three dimensions, a crystalline specimen that is too large to be studied as a single object with a coherence-limited X-ray beam.
- P. Godard
- , G. Carbone
- & V. Chamard
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Article
| Open AccessSuppression of the intrinsic stochastic pinning of domain walls in magnetic nanostripes
The propagation of magnetic domain walls in nanowires offers promise as the basis of future memory storage technologies. Muñoz and Prieto show that the random pinning of domain walls to structural defects in the nanowires can be suppressed at low fields, thus improving the reliability of the transmission of the domain walls substantially.
- Manuel Muñoz
- & José L. Prieto
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Towards hybrid superlattices in graphene
The controllable modification of graphene by chemical functionalization can modulate its optical and electronic properties. Sunet al. devise a functionalisation-based method to pattern graphane/graphene superlattices within a single sheet of graphene.
- Zhengzong Sun
- , Cary L. Pint
- & James M. Tour
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Concurrent transition of ferroelectric and magnetic ordering near room temperature
Magnetoelectric materials combine ferroelectric and magnetic properties through a coupling of the spin and lattice degrees of freedom. Here, magnetoelectric bismuth ferrite is found to simultaneously undergo both a magnetic and a ferroelectric transition at the same temperature.
- Kyung-Tae Ko
- , Min Hwa Jung
- & Chan-Ho Yang
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Article
| Open AccessExperimental loss-tolerant quantum coin flipping
When two spatially separated parties flip a coin, it is impossible to choose between two alternatives in an unbiased manner. This study presents a quantum coin-flipping protocol that overcomes this problem and ensures a dishonest party cannot bias the outcome completely.
- Guido Berlín
- , Gilles Brassard
- & Wolfgang Tittel
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| Open AccessA new regime for mechanical annealing and strong sample-size strengthening in body centred cubic molybdenum
Mechanical annealing is a process through which the dislocation density in submicrometre metal crystals can be removed purely by applying a mechanical stress. This study shows that mechanical annealing occurs in body centred cubic molybdenum, and not only in face centred crystals as previously thought.
- Ling Huang
- , Qing-Jie Li
- & Evan Ma
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Experimental generation of an eight-photon Greenberger–Horne–Zeilinger state
Generation of multipartite entanglement between quantum states is crucial for developing quantum computation systems, although it has proven harder to achieve for photons than ions. Here, an eight-photon entangled state based on four independent photon pairs is observed, beating the previous record of six.
- Yun-Feng Huang
- , Bi-Heng Liu
- & Guang-Can Guo
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| Open AccessCoupling artificial molecular spin states by photon-assisted tunnelling
Tunnelling transitions triggered by microwave irradiation between coupled quantum dots have generally been assumed to be spin-conserving. This study shows that this condition is violated in the presence of spin–orbit coupling, thus opening new possibilities for manipulating a two–spin qubit system by microwave irradiation.
- L.R. Schreiber
- , F.R. Braakman
- & L.M.K. Vandersypen
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| Open AccessHigh-density magnetoresistive random access memory operating at ultralow voltage at room temperature
Magnetoresistive random access memory offers significant promise as a next-generation memory technology. Nan and colleagues present a design concept for a device that simultaneously possesses ultrahigh storage capacity, ultralow power dissipation, and high-speed operation at room temperature.
- Jia-Mian Hu
- , Zheng Li
- & Ce-Wen Nan
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| Open AccessElectric field-induced chemical locomotion of conducting objects
External electric fields have been used to control the motion of small objects through electrostatic repulsion. Here, electric fields are used to polarize conducting objects, triggering their movement by spatially separated electrochemical reactions leading to directionally controlled bubble evolution.
- Gabriel Loget
- & Alexander Kuhn
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| Open AccessWide-band quantum interface for visible-to-telecommunication wavelength conversion
Most quantum communication experiments are performed at visible wavelengths, yet practical, long-range schemes need photons in the telecommunications range. Here, down-conversion of a visible photon to the near-infrared is demonstrated, while retaining its entanglement to another visible photon.
- Rikizo Ikuta
- , Yoshiaki Kusaka
- & Nobuyuki Imoto
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Super-resolution surface mapping using the trajectories of molecular probes
Surface characterization of soft materialsin situis challenging due to the importance of non-covalent interactions. Now, a new chemical imaging method is reported that generates images of surface interactions by combining many molecular probe trajectories.
- Robert Walder
- , Nathaniel Nelson
- & Daniel K. Schwartz
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Broadband polarization-independent resonant light absorption using ultrathin plasmonic super absorbers
Plasmonic nanostructures and metamaterials can augment the performance of photovoltaic and thermophotovoltaic cells by enhancing their absorption properties. Aydinet al. demonstrate a broadband, ultrathin plasmonic super absorber using crossed trapezoids as part of a metal–insulator–metal stack.
- Koray Aydin
- , Vivian E. Ferry
- & Harry A. Atwater
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| Open AccessQuantum interferometric visibility as a witness of general relativistic proper time
In the theory of general relativity time flows at different rates depending on the space–time geometry. Here, a drop in the visibility of a quantum 'clock' interference in a gravitational potential is predicted, which cannot be explained without the general relativistic notion of time.
- Magdalena Zych
- , Fabio Costa
- & Časlav Brukner
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Field-effect reconfigurable nanofluidic ionic diodes
Nanofluidic diodes are utilized for the rectification of ionic transport, but their rectifying properties cannot be altered after the devices are made. Here, a field-effect reconfigurable nanofluidic diode is reported in which the forward direction and the degree of rectification can be modulated by a gate voltage.
- Weihua Guan
- , Rong Fan
- & Mark A. Reed
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Control of electronic conduction at an oxide heterointerface using surface polar adsorbates
The interfaces between complex oxides can play host to a range of interesting electronic phenomena. Xieet al. demonstrate that the electronic properties at the LaAlO3/SrTiO3interface can be tuned upon application of common polar solvents such as acetone, ethanol and water.
- Yanwu Xie
- , Yasuyuki Hikita
- & Harold Y. Hwang
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| Open AccessDesigning attractive models via automated identification of chaotic and oscillatory dynamical regimes
Modelling of chaos and oscillations is usually done indirectly and quantitatively by fitting models to a finite number of data-points. Here, a qualitative framework is developed where the characteristics of the underlying dynamical system are directly specified, revealing new properties of such systems.
- Daniel Silk
- , Paul D.W. Kirk
- & Michael P.H. Stumpf
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| Open AccessRole of mid-gap states in charge transport and photoconductivity in semiconductor nanocrystal films
Nanocrystals are used in light-emitting diodes and solar cells, but their charge transport in films is unclear. Here, the study of PbS nanocrystal films reveals the role of mid-gap states in their charge transport, suggesting different design needs for devices operated in dark (transistors) versus light (solar cells) conditions.
- Prashant Nagpal
- & Victor I. Klimov
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| Open AccessDetecting inertial effects with airborne matter-wave interferometry
Inertial sensors using atom interferometry have applications in geophysics, navigation- and space-based tests of fundamental physics. Here, the first operation of an atom accelerometer during parabolic flights is reported, demonstrating high-resolution measurements at both 1g and 0g.
- R. Geiger
- , V. Ménoret
- & P. Bouyer
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| Open AccessInformation processing using a single dynamical node as complex system
The paradigm of reservoir computing shows that, like the human brain, complex networks can perform efficient information processing. Here, a simple delay dynamical system is demonstrated that can efficiently perform computations capable of replacing a complex network in reservoir computing.
- L. Appeltant
- , M.C. Soriano
- & I. Fischer
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Microfluidic quadrupole and floating concentration gradient
Quadrupoles have many engineering applications, but experimental observations of fluidic multipoles have not been reported. This study presents an experimental two-dimensional microfluidic quadrupole, a theoretical analysis consistent with observations, and a first application as a channel-free floating gradient generator.
- Mohammad A. Qasaimeh
- , Thomas Gervais
- & David Juncker
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Surfactant-enabled epitaxy through control of growth mode with chemical boundary conditions
Property coupling by heteroepitaxy is severely limited in material combinations with highly dissimilar bonding. This report presents a chemical boundary condition methodology to actively engineer two-dimensional film growth in such systems that otherwise collapse into island formation and rough morphologies.
- Elizabeth A. Paisley
- , Mark. D. Losego
- & Jon-Paul Maria
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| Open AccessMeasurement of the inelastic proton–proton cross-section at √s=7 TeV with the ATLAS detector
The measurement of the total cross-section of proton–proton collisions is of fundamental importance for particle physics. Here, the first measurement of the inelastic cross-section is presented for proton–proton collisions at an energy of 7 teraelectronvolts using the ATLAS detector at the Large Hadron Collider.
- G. Aad
- , B. Abbott
- & L. Zwalinski
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Strong plasmonic enhancement of photovoltage in graphene
Photodetection is believed to be among the most promising potential applications for graphene. Here, by combining graphene with plasmonic nanostructures, the efficiency of graphene-based photodetectors is increased by up to two orders of magnitude.
- T.J. Echtermeyer
- , L. Britnell
- & K.S. Novoselov
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| Open AccessBethe-hole polarization analyser for the magnetic vector of light
Determining the direction of the magnetic field of light is important for optical applications. Here, scattering of light from a subwavelength aperture in a metal plane is shown to be governed by its magnetic vector, providing the magnetic field orientation independently of the electric field.
- H.W. Kihm
- , S.M. Koo
- & D.-S. Kim
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| Open AccessEvidence of superdense aluminium synthesized by ultrafast microexplosion
At extreme temperature and pressure, materials can form new dense phases with unusual physical properties. Here, laser-induced microexplosions are used to produce a superdense, stable, body-centred-cubic form of aluminium, which was previously predicted to exist at pressures above 380GPa.
- Arturas Vailionis
- , Eugene G. Gamaly
- & Saulius Juodkazis
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Direct imaging of Joule heating dynamics and temperature profiling inside a carbon nanotube interconnect
The use of carbon nanotubes in nanoelectronics requires an understanding of their resistive, or Joule, heating at interconnects. Here, Joule heating dynamics are imaged in real time by following the evolution of resistive hot spots with a transmission electron microscope.
- Pedro M.F.J. Costa
- , Ujjal K. Gautam
- & Dmitri Golberg
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| Open AccessFast cavity-enhanced atom detection with low noise and high fidelity
Single atoms can be detected using optical resonators that extend the lifetime of the photon. Here, the authors demonstrate fast, high-fidelity detection of very low atom densities using a microfabricated optical cavity to couple the detection light with the atoms.
- J. Goldwin
- , M. Trupke
- & E.A. Hinds
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| Open AccessNo extension of quantum theory can have improved predictive power
Quantum-mechanical predictions are generally probabilistic. Here, assuming freely chosen measurements, it is shown that enhanced predictions are not possible and, thus, randomness is inherent in quantum theory: a result that has applications in fields such as quantum cryptography.
- Roger Colbeck
- & Renato Renner
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| Open AccessAdding control to arbitrary unknown quantum operations
Quantum computing has advantages over conventional computing, but the complexity of quantum algorithms creates technological challenges. Here, an architecture-independent technique, that simplifies adding control qubits to arbitrary quantum operations, is developed and demonstrated.
- Xiao-Qi Zhou
- , Timothy C. Ralph
- & Jeremy L. O'Brien
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Stimulated optomechanical excitation of surface acoustic waves in a microdevice
Brillouin interactions between sound and light can excite mechanical resonances in photonic microsystems, with potential for sensing and frequency reference applications. The authors demonstrate experimental excitation of mechanical resonances ranging from 49 to 1,400 MHz using forward Brillouin scattering.
- Gaurav Bahl
- , John Zehnpfennig
- & Tal Carmon
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Ranking stability and super-stable nodes in complex networks
Pagerank is widely used to rank web content; however, it is unknown how network topology affects its performance. The authors demonstrate that, in random networks, pagerank is sensitive to perturbations in topology, whereas scale-free networks contain a few super-stable nodes whose ranking is exceptionally stable.
- Gourab Ghoshal
- & Albert-László Barabási
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| Open AccessProximity of iron pnictide superconductors to a quantum tricritical point
In some iron-based materials, unconventional superconductivity can emerge near a quantum phase transition where long-range magnetic order vanishes. Giovannettiet al.show that the magnetic quantum phase transition in an iron pnictide superconductor is very close to the quantum tricritical point.
- Gianluca Giovannetti
- , Carmine Ortix
- & José Lorenzana
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| Open AccessFractional quantum Hall effect in the absence of Landau levels
The fractional quantum Hall effect occurs when electrons move in Landau levels. In this study, using a theoretical flat-band lattice model, the fractional quantum Hall effect is observed in the presence of repulsive interactions when the band is one third full and in the absence of Landau levels.
- D.N. Sheng
- , Zheng-Cheng Gu
- & L. Sheng
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Onset of a quantum phase transition with a trapped ion quantum simulator
A quantum simulator can follow the evolution of a prescribed model, whose behaviour may be difficult to determine. Here, the emergence of magnetism is simulated by implementing a quantum Ising model, providing a benchmark for simulations in larger systems.
- R. Islam
- , E.E. Edwards
- & C. Monroe
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| Open AccessOptical switching of nuclear spin–spin couplings in semiconductors
Two-qubit operation is an essential part of quantum computation, but implementation has been difficult. Gotoet al.introduce optically controllable internuclear coupling in semiconductors providing a simple way of switching inter-qubit couplings in semiconductor-based quantum computers.
- Atsushi Goto
- , Shinobu Ohki
- & Tadashi Shimizu
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Using disorder to detect locally ordered electron nematics via hysteresis
Interactions between charge, orbital and lattice degrees of freedom in correlated electron systems have resulted in predictions of new electronic phases of matter. Carlson and Dahmen propose two protocols for detecting disordered electron nematics in condensed matter systems using non-equilibrium methods.
- E.W. Carlson
- & K.A. Dahmen
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Imaging local electronic corrugations and doped regions in graphene
The unoccupied electronic levels of graphene are modified by corrugation, doping and presence of impurities. Here, the authors map discrete electronic domains within a single graphene sheet using scanning transmission X-ray microscopy and provide insight into the modification of unoccupied levels.
- Brian J. Schultz
- , Christopher J. Patridge
- & Sarbajit Banerjee
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Statistically induced phase transitions and anyons in 1D optical lattices
Anyons are particles with fractional statistics that interpolate between bosons and fermions, and are thought to exist in low-dimensional systems. Keilmannet al. propose an experimental system to create anyons in one-dimensional optical lattices using assisted Raman tunnelling.
- Tassilo Keilmann
- , Simon Lanzmich
- & Marco Roncaglia
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| Open AccessSize limits the formation of liquid jets during bubble bursting
A bubble at an air–liquid interface can form a liquid jet upon bursting, spraying aerosol droplets into the air. Leeet al. show that jetting is analogous to pinching-off in liquid coalescence, which may be useful in applications that prevent jet formation and in the improved incorporation of aerosols in climate models.
- Ji San Lee
- , Byung Mook Weon
- & Wah-Keat Lee
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| Open AccessThe vectorial control of magnetization by light
Light–matter interactions can be used to manipulate magnetization in solids, but light-controlled magnetization vector motion has not been demonstrated. Here, two-dimensional magnetic oscillations in NiO are manipulated with optical pulses leading to vectorial control of magnetization by light.
- Natsuki Kanda
- , Takuya Higuchi
- & Makoto Kuwata-Gonokami
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Biologically inspired achromatic waveplates for visible light
Waveplates are used in optoelectronics to alter the polarization of light, but they do not typically perform achromatically, which is important for applications such as three-dimensional displays. Here, biologically inspired periodically multilayered structures are produced, which function as achromatic visible-light waveplates.
- Yi-Jun Jen
- , Akhlesh Lakhtakia
- & Jyun-Rong Lai
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Observing chaos for quantum-dot microlasers with external feedback
Optoelectronic devices such as conventional semiconductor lasers are used to study the chaotic behaviour of nonlinear systems. Here chaos is observed for quantum-dot microlasers operating close to the quantum limit with potential for new directions in the study of chaos in quantum systems.
- Ferdinand Albert
- , Caspar Hopfmann
- & Ido Kanter
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Full-field implementation of a perfect eavesdropper on a quantum cryptography system
A quantum key distribution system allows two remote parties to communicate in secret by a shared key code. This work demonstrates a complete and undetected eavesdropping attack on a quantum key distribution connection, highlighting the need for further security updates on secure communication systems.
- Ilja Gerhardt
- , Qin Liu
- & Vadim Makarov
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| Open AccessColossal negative thermal expansion in BiNiO3 induced by intermetallic charge transfer
Negative thermal expansion—contraction upon heating—is an unusual process that may be exploited to produce materials with zero or other controlled thermal expansion values. Azumaet al. observe negative thermal expansion in BiNiO3which is a result of Bi/Ni charge-transfer transitions.
- Masaki Azuma
- , Wei-tin Chen
- & J. Paul Attfield
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Article
| Open AccessRevealing the high-energy electronic excitations underlying the onset of high-temperature superconductivity in cuprates
Understanding how the high-energy physics of Mott-like excitations affects condensate formation is a key challenge in high-temperature superconductivity. Giannettiet al. clarify the relationship of many-body CuO2excitations and the onset of superconductivity using a new optical pump supercontinuum-probe technique.
- Claudio Giannetti
- , Federico Cilento
- & Fulvio Parmigiani
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| Open AccessTransition to a Bose–Einstein condensate and relaxation explosion of excitons at sub-Kelvin temperatures
Bose–Einstein condensation of excitons in thermal equilibrium is a predicted quantum statistical phenomenon that has been difficult to observe. Yoshiokaet al. cool trapped excitons to sub-Kelvin temperatures and show that condensation manifests itself as a relaxation explosion as has been observed for atomic hydrogen.
- Kosuke Yoshioka
- , Eunmi Chae
- & Makoto Kuwata-Gonokami
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| Open AccessActive microrheology and simultaneous visualization of sheared phospholipid monolayers
Two-dimensional fluid interfaces are ubiquitous, but studying their surface dynamic properties is difficult because of coupling between the film and bulk fluid. Choiet al.combine active microrheology with fluorescence microscopy to image fluid interfaces under applied stress.
- S.Q. Choi
- , S. Steltenkamp
- & T.M. Squires
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Article
| Open AccessRevealing the molecular structure of single-molecule junctions in different conductance states by fishing-mode tip-enhanced Raman spectroscopy
The conductance of single-molecule junctions is affected by the structure of the molecule and how it is bound to the electrodes, which may be examined using Raman spectroscopy. Liuet al. have developed 'fishing-mode' tip-enhanced Raman spectroscopy, which allows the simultaneous determination of conductance and Raman spectra.
- Zheng Liu
- , Song-Yuan Ding
- & Zhong-Qun Tian
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