Electronic properties and materials articles within Nature Communications

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  • Article |

    Understanding high temperature superconductivity in the cuprates is one of the hardest problems in physics to date. Wang et al.use state-of-the-art scanning tunnelling spectroscopy to visualize the atomic-scale electronic structure of the Mott insulator phase from which this elusive state emerges.

    • Cun Ye
    • , Peng Cai
    •  & Yayu Wang

  • Article
    | Open Access

    In metals, plasmon properties are fixed once the structure is built, but in graphene they can be altered by electric or magnetic fields. Using electrical time-of-flight measurements, Kumada et al. show wide plasmon velocity tunability in graphene with a varying magnetic field.

    • N. Kumada
    • , S. Tanabe
    •  & T. Fujisawa

  • Article |

    Organic electronic materials are promising candidates for applications in which flexible electronic devices are required. Yiet al. demonstrate a high-performance, flexible organic transistor based on solution-processed small molecules that can be fabricated with a simple, low-cost process.

    • Hee Taek Yi
    • , Marcia M. Payne
    •  & Vitaly Podzorov

  • Article |

    The charge-transfer characteristics of conjugated molecules are important in determining their electronic properties. Using resonant photoemission spectroscopy, Batraet al. quantify the through-space charge transfer in two model conjugated systems with femtosecond resolution.

    • Arunabh Batra
    • , Gregor Kladnik
    •  & Latha Venkataraman

  • Article |

    Topologically protected states of matter are receiving widespread attention owing to their unusual electronic properties. Using numerical simulations, this study predicts that tin telluride is a physical realization of a new class of materials termed topological crystalline insulators.

    • Timothy H. Hsieh
    • , Hsin Lin
    •  & Liang Fu

  • Article
    | Open Access

    The realization of wafer-scale graphene electronics is envisaged to open up the route to the use of graphene in mainstream electronics. Hertelet al.take a step in this direction by fabricating a transistor with a SiC channel and graphene electrodes, with excellent performance up to megahertz frequencies.

    • S. Hertel
    • , D. Waldmann
    •  & H.B. Weber

  • Article |

    Vortex–charge duality is a model that has been proposed for describing the superconducting to insulator transition in disordered thin films. Mehtaet al. report experimental evidence for this duality in the two-dimensional electron gas that arises in LaAlO3/SrTiO3heterostructures.

    • M.M. Mehta
    • , D.A. Dikin
    •  & V. Chandrasekhar

  • Article |

    The SrTiO3/LaAlO3 system is widely studied because it forms a two-dimensional electron gas at the interface. This study investigates the effects of diluting the LaAlO3 layer with SrTiO3, and finds that the threshold thickness required for the onset of conductivity scales inversely with the fraction of LaAlO3, suggesting an intrinsic origin for the electron gas.

    • M.L. Reinle-Schmitt
    • , C. Cancellieri
    •  & P.R. Willmott

  • Article |

    Stretchable electronics based on conducting polymers offer new opportunities for designing flexible technologies. Parket al. build three-dimensional nanostructures from elastomers soaked with liquid metal to produce stretchable conductors with greatly improved strain properties over solid films.

    • Junyong Park
    • , Shuodao Wang
    •  & Seokwoo Jeon

  • Article |

    Spin ice is a state of matter that occurs in certain rare earth magnets with a pyrochlore structure. Here it is shown theoretically that, in conjunction with the magnetic monopoles observed in previous experiments, spin ice can also host electric dipoles.

    • D.I. Khomskii

  • Article |

    Devices made up of nanowires offer promise for a range of electronic, photonic and energy applications. Liuet al. fabricate a miniature capacitor by employing a thin layer of Cu2O as a separator between layers of carbon and copper.

    • Zheng Liu
    • , Yongjie Zhan
    •  & Pulickel M. Ajayan

  • Article |

    Transistors based on ions, as opposed to electrons, offer the promise of bridging the gap between technological and biological systems. Tybrandtet al. present logic gates based on ion bipolar junction transistors that operate at concentrations compatible with biological systems.

    • Klas Tybrandt
    • , Robert Forchheimer
    •  & Magnus Berggren

  • Article |

    Strain engineering has been proposed as a promising strategy for manipulating the electronic properties of graphene. This scanning tunnelling microscopy study demonstrates the feasibility of controlling strain patterns in graphene down to the nanoscale.

    • Jiong Lu
    • , A.H. Castro Neto
    •  & Kian Ping Loh

  • Article
    | Open Access

    Electronic and optoelectronic devices based on gallium nitride suffer from self-heating arising as a result of their operation. This study presents and demonstrates a strategy for managing this problem that relies on graphene quilts which dissipate the heat away.

    • Zhong Yan
    • , Guanxiong Liu
    •  & Alexander A. Balandin

  • Article
    | Open Access

    Point defects in diamond in the form of nitrogen vacancy centres are believed to be promising candidates for qubits in quantum computers. Grotzet al. present a method for manipulating the charge state of nitrogen vacancies using an electrolytic gate electrode.

    • Bernhard Grotz
    • , Moritz V. Hauf
    •  & Jose A. Garrido

  • Article
    | Open Access

    Field-effect transistors fabricated from carbon nanotubes have been investigated extensively over the past two decades. This study demonstrates a nanotube-based integrated circuit design that substantially improves the speed and power consumption with respect to silicon-based integrated circuits.

    • Li Ding
    • , Zhiyong Zhang
    •  & Lian-Mao Peng

  • Article
    | Open Access

    Graphene's broad bandwidth makes it promising as a photodetector, but common electronics cannot analyse the currents at high frequencies. Here, using photocurrent measurements, laser-induced carrier generation effects in freely suspended graphene and at graphene–metal interfaces are clarified up to 1 THz.

    • Leonhard Prechtel
    • , Li Song
    •  & Alexander W. Holleitner

  • Article |

    The surface electronic structure of topological insulators is characterized by a so-called Dirac cone energy dispersion. This study shows that by tuning the compositions in the compound Bi2−xSbxTe3−ySeyone can control the precise features of its Dirac cone structure while keeping it a bulk insulator.

    • T. Arakane
    • , T. Sato
    •  & Yoichi Ando

  • Article
    | Open Access

    Fluctuations of the electrical current in nanoscale devices reveal important details of the physical processes occurring inside them. Using a quantum point contact placed in its vicinity, Ubbelohde et al. measure the electrical fluctuations in a single-electron transistor, and determine the dynamical features of the transport.

    • Niels Ubbelohde
    • , Christian Fricke
    •  & Rolf J. Haug

  • Article
    | Open Access

    Studying carrier multiplication in materials is important to understand their transport properties and interaction with light. Hiroriet al. show that intense terahertz pulses can generate electron-hole pairs in GaAs quantum wells that then emit infrared light, contrary to the effect with a DC field.

    • H. Hirori
    • , K. Shinokita
    •  & K. Tanaka

  • Article
    | Open Access

    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

  • Article
    | Open Access

    Transparent conducting oxides are wide bandgap conductors that have found a range of applications in optoelectronic devices. In this study, Hosono and colleagues fabricate the first transparent conducting oxide based on germanium.

    • Hiroshi Mizoguchi
    • , Toshio Kamiya
    •  & Hideo Hosono

  • Article
    | Open Access

    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

  • Article
    | Open Access

    Temperature-controlled regulation of thermal conductivity is difficult to achieve because thermal properties do not change significantly through solid-state phase transitions. Here temperature control of thermal conductivities is demonstrated using liquid–solid phase transitions in a nanoparticle suspension.

    • Ruiting Zheng
    • , Jinwei Gao
    •  & Gang Chen

  • Article |

    Interface effects in complex oxides could have interesting technological applications. Ariandoet al. demonstrate electronic phase separation and rich physics at a complex oxide interface between the two non-magnetic insulators LaAlO3 and SrTiO3.

    • Ariando
    • , X. Wang
    •  & T. Venkatesan

  • Article |

    The integration of oxide nanoelectronics with silicon platforms is a necessary step for the fabrication of ultrahigh-density devices. Here, the authors grow a LaAlO3/SrTiO3interface directly on silicon, and show the reversible creation of a two-dimensional electron gas confined within nanowires located on the surface.

    • J.W. Park
    • , D.F. Bogorin
    •  & C.B. Eom

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