Nanoscale materials | Nature Communications

Article | 24 May 2011

Stabilizing lithium–sulphur cathodes using polysulphide reservoirs

Lithium–sulphur batteries may achieve higher energy densities than conventional lithium-ion cells, but the dissolution of sulphur intermediates is a continuing challenge. Here this problem is overcome using a cathode with a mesoporous structure that is able to accommodate intermediate polysulphide anions.

Xiulei Ji
, Scott Evers
& Linda F. Nazar

Article
10 May 2011 | Open Access

Large-scale single-chirality separation of single-wall carbon nanotubes by simple gel chromatography

Large-scale separation of single-wall carbon nanotubes into populations of single chirality is a significant challenge in the practical application of nanotubes. Now, using multicolumn gel chromatography, the large-scale separation of 13 different carbon nanotube species is achieved.

Huaping Liu
, Daisuke Nishide
& Hiromichi Kataura

Article | 26 April 2011

Synthesis of hexagonal close-packed gold nanostructures

Solid gold is most stable as a face-centred cubic structure, and stable colloidal gold with hexagonal close packing has not been produced. Huanget al.prepare square gold sheets with hexagonal close packing that are stable under ambient conditions.

Xiao Huang
, Shaozhou Li
& Hua Zhang

Article
19 April 2011 | Open Access

Reversible temperature regulation of electrical and thermal conductivity using liquid–solid phase transitions

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 | 19 April 2011

Size and mechanics effects in surface-induced melting of nanoparticles

Melting-related phenomena are of fundamental and applied interest, but the melting theory is poorly understood. Levitas and Samani develop an advanced phase-field theory of melting coupled to mechanics that resolves existing contradictions and reveals the features of melting phenomena.

Valery I Levitas
& Kamran Samani

Article | 19 April 2011

A monolithically integrated plasmonic infrared quantum dot camera

Infrared cameras are used for night vision and in medical diagnostics, but currently only present monochrome images. Krishnaet al. demonstrate a monolithically intergrated plasmonic infrared quantum dot camera as a step towards coloured infrared imaging.

Sang Jun Lee
, Zahyun Ku
& Sam Kyu Noh

Article
19 April 2011 | Open Access

Nano-engineered electron–hole exchange interaction controls exciton dynamics in core–shell semiconductor nanocrystals

Electron–hole exchange interaction is an intrinsic property of semiconductors, which affects their fine structure. Brovelliet al. demonstrate a nanoengineering-based approach that provides control over the exchange interaction energy at nearly constant emission energy, which cannot be carried out using core-only nanocrystals.

S. Brovelli
, R.D. Schaller
& V.I. Klimov

Article
05 April 2011 | Open Access

3D optical Yagi–Uda nanoantenna array

Nanoantennas may be important for future photonic circuits; they combine an emitter or detector with free-space propagation of light. Dregelyet al. fabricate an array of 3D optical Yagi–Uda nanoantennas and show that radiofrequency antenna array concepts applied to the optical regime can provide improved directional properties.

Daniel Dregely
, Richard Taubert
& Harald Giessen

Article
29 March 2011 | Open Access

Development of a universal stress sensor for graphene and carbon fibres

Embedding carbon fibres in polymer matrices provides significant gains in strength and stiffness. Here, the Raman G peak of carbon fibre is studied in relation to applied strain and referenced to graphene; the work could facilitate stress measurements of carbon fibre polymer composites.

Otakar Frank
, Georgia Tsoukleri
& Costas Galiotis

Article
29 March 2011 | Open Access

Whispering gallery microresonators for second harmonic light generation from a low number of small molecules

Small molecules can be detected by second harmonic light generation, but sensitive detection usually requires a large number of molecules and a high-power laser source. Here, relatively low numbers of molecules are detected using Q spherical microresonators and low average power.

J.L. Dominguez-Juarez
, G. Kozyreff
& Jordi Martorell

Article | 15 March 2011

Coherent electron–phonon coupling in tailored quantum systems

Graphene and InAs nanowires are both promising materials for coherent spin manipulation, but coupling between a quantum system and its environment leads to decoherence. Here, the contribution of electron–phonon coupling to decoherence in graphene and InAs nanowire is studied.

P. Roulleau
, S. Baer
& T. Ihn

Article
15 March 2011 | Open Access

A new method to position and functionalize metal-organic framework crystals

Metal-organic frameworks (MOFs) have potential catalysis, filtration and sensing applications, but device fabrication will require controlled MOF growth. Here, α-hopeite microparticles are used to achieve spatial control of MOF nucleation, and accelerate MOF growth.

Paolo Falcaro
, Anita J. Hill
& Dario Buso

Article
08 March 2011 | Open Access

Phonon-tunnelling dissipation in mechanical resonators

The performance of micromechanical and nanomechanical resonators is often hampered by mechanical damping. In this study, the authors demonstrate a numerical solver for the prediction of support-induced losses in these structures and verify experimentally the fidelity of this method.

Garrett D. Cole
, Ignacio Wilson-Rae
& Markus Aspelmeyer

Article | 01 March 2011

Identification of active atomic defects in a monolayered tungsten disulphide nanoribbon

The physical and chemical properties of low-dimensional materials, such as nanoribbons, are affected by edge structures and atomic defects. Here, single-atom defects in a monolayered tungsten disulphide nanoribbon are discriminated and the motions of atomic defects are visualized.

Zheng Liu
, Kazu Suenaga
& Sumio Iijima

Article
01 March 2011 | Open Access

Observation and electric current control of a local spin in a single-molecule magnet

In molecular spintronics, the spin state of a molecule may be switched by changing the molecular structure. Here, the spin of a single-molecule magnet is switched by applying an electric current using a scanning tunnelling microscope, which may aid in information coding at the single-molecule level.

Tadahiro Komeda
, Hironari Isshiki
& Masahiro Yamashita

Article
22 February 2011 | Open Access

Transport spectroscopy of non-equilibrium many-particle spin states in self-assembled quantum dots

All-electrical quantum state manipulation is highly desirable for quantum information technologies. In this study, the authors demonstrate the preparation and detection of excited many-particle spin states in self-assembled quantum dots at 4 K, using only electrical means.

B. Marquardt
, M. Geller
& A. Lorke

Article | 01 February 2011

Tablet-level origin of toughening in abalone shells and translation to synthetic composite materials

The mechanism responsible for the toughness of nacre, the hierarchical iridescent material in seashells, is still unknown. Espinosa and colleagues show that the waviness of its tablets leads to interfacial hardening, and ultimately to energy dissipation, when the material is stressed.

Horacio D. Espinosa
, Allison L. Juster
& Pablo D. Zavattieri

Article | 21 December 2010

Atomically flat single-crystalline gold nanostructures for plasmonic nanocircuitry

Polycrystalline substrates are a hindrance to the realization of high-definition plasmonic nanostructures. In this paper the authors chemically grow large and thin gold single crystals, and show that they can be coupled with top-down fabrication methods to produce high-quality nanostructures with good optical properties.

Jer-Shing Huang
, Victor Callegari
& Bert Hecht

Article
21 December 2010 | Open Access

Discrete plasticity in sub-10-nm-sized gold crystals

Deformations in nanocrystals smaller than 10 nm are not well understood. The authors perform compression high-resolution transmission electron microscopy studies of gold nanoparticles, and determine that the nanoparticles deform through the emission of partial dislocations from free surfaces.

He Zheng
, Ajing Cao
& Scott X. Mao

Article | 23 November 2010

Three-dimensional imaging of magnetic domains

The imaging of magnetic domains in three-dimensional solids has been hampered by a lack of suitable methods. The authors show that Talbot-Lau neutron tomography is capable of visualizing the domain structure of an iron silicide bulk crystal.

I. Manke
, N. Kardjilov
& J. Banhart

Article | 19 October 2010

Piezoelectric-nanowire-enabled power source for driving wireless microelectronics

Energy harvesting through mechanical actions of nanosized components could be useful for powering mobile electronics. Here, the authors grow lead zirconate nanowire arrays at comparatively low temperature and use them to power a macroscopic laser diode.

Sheng Xu
, Benjamin J. Hansen
& Zhong Lin Wang

Article
19 October 2010 | Open Access

Structural bases for the interaction of frataxin with the central components of iron–sulphur cluster assembly

Frataxin is an essential protein that has been linked to iron–sulphur cluster assembly, and reduced levels are associated with Friedrich's ataxia. In this study, a combination of techniques is used to probe the interactions of the bacterial frataxin orthologue CyaY with the iron–sulphur cluster assembly machinery.

Filippo Prischi
, Petr V. Konarev
& Annalisa Pastore

Article | 19 October 2010

One-by-one trap activation in silicon nanowire transistors

Flicker noise in nanoscale field effect transistors deviates from the simple frequency-dependent behaviour of macroscale objects. Here the authors show that Coulomb repulsion between nearby trap sites leads to an order of magnitude reduction in noise in these devices.

N. Clément
, K. Nishiguchi
& D. Vuillaume

Article | 05 October 2010

A systems approach towards the stoichiometry-controlled hetero-assembly of nanoparticles

The assembly of nanoparticles into stoichiometry-controlled structures could lead to materials with novel properties and functions. Here, reaction systems are developed, which allow the rational assembly of differently functionalized gold nanoparticles (A and B) to give AB, AB₂, AB₃ and AB₄nanoclusters.

Yong Wang
, Gang Chen
& Hongyu Chen

Article | 21 September 2010

Reduced graphene oxide by chemical graphitization

The mass production of high-quality reduced graphene oxide could aid the scale-up of graphene-based technologies. Here, a one-pot reduction of graphene oxide using hydriodic acid and acetic acid provides large quantities of highly conductive reduced graphene oxide.

In Kyu Moon
, Junghyun Lee
& Hyoyoung Lee

Article | 21 September 2010

Self-assembled aggregates formed by single-molecule magnets on a gold surface

The spontaneous ordering of molecules into two-dimensional arrays is usually a result of directional intermolecular interactions. Here, it is shown that electrospray-deposited Mn₁₂(acetate)₁₆forms filamentary aggregates driven by anisotropic interactions, which are a consequence of the complex shape of the molecule.

Alex Saywell
, Graziano Magnano
& Peter H. Beton

Article | 13 July 2010

Nanoelectromechanical coupling in fullerene peapods probed by resonant electrical transport experiments

Fullerene peapods are carbon nanotubes encapsulating buckyball molecules. Here the authors show by low-temperature electron transport experiments, that the electronic states of nanotubes couple to the vibrational states of fullerenes, making the peapods a new class of nanoelectromechanical devices.

Pawel Utko
, Raffaello Ferone
& Jesper Nygård

Article | 29 June 2010

Gate-controlled electron transport in coronenes as a bottom-up approach towards graphene transistors

Graphene sheets used to build electronic devices have defects that limit performance. As a possible bottom-up route towards better devices, Diez-Perez and co-workers build large polyaromatic molecules with precisely defined structures which show good performance as field-effect transistors.

Ismael Diez-Perez
, Zhihai Li
& Nongjian Tao

Article | 15 June 2010

Enhanced stochasticity of domain wall motion in magnetic racetracks due to dynamic pinning

Understanding the details of domain wall motion in nanowires is important for magnetic racetrack memories. Jiang and co-workers show that this motion can become more random by varying the magnetic field, pinning the domains at several local imperfections of the nanowire.

Xin Jiang
, Luc Thomas
& Stuart S.P. Parkin

Article
01 June 2010 | Open Access

Electron-beam-assisted superplastic shaping of nanoscale amorphous silica

At room temperature, glasses are known to be brittle and fracture upon deformation. Zhenget al. show that, by exposing amorphous silica nanostructures to a low-intensity electron beam, it is possible to achieve dramatic shape changes, including a superplastic elongation of 200% for nanowires.

Kun Zheng
, Chengcai Wang
& Evan Ma

Article | 12 April 2010

Engineering hybrid nanotube wires for high-power biofuel cells

Miniaturizing fuel cells for biological applications is challenging due to poor performance at these small scales. Now Gao and coworkers show that electrodes made with porous microfibers composed of oriented carbon nanotubes are capable of delivering fast mass transport of the reagents and greatly enhanced currents.

Feng Gao
, Lucie Viry
& Nicolas Mano