Techniques and instrumentation articles within Nature Communications

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• Article | 06 August 2013

  Structured cone arrays for continuous and effective collection of micron-sized oil droplets from water

  Effective methods for the removal of micro-droplets of oil from water are sought-after to combat oil spills. Here, the authors report cactus-inspired oleophilic conical needle arrays capable of capturing micron-sized oil droplets with both high continuity and high throughput.

  • Kan Li
  • , Jie Ju
  •  & Lei Jiang

• Article | 02 August 2013

  Reversible patterning and actuation of hydrogels by electrically assisted ionoprinting

  Techniques for shape-controlling of hydrogels, that is, crosslinked networks of polymers, could make possible various biomimetic applications. Palleau et al.propose a strategy to pattern three-dimensional hydrogels using electric potential, which allows directed bending and fast controllable actuation.

  • Etienne Palleau
  • , Daniel Morales
  •  & Orlin D. Velev

• Article | 31 July 2013

  Stray-field imaging of magnetic vortices with a single diamond spin

  Obtaining quantitative information on nanoscale magnetic structures is a challenge. Here, the authors apply scanning probe magnetometry based on a single nitrogen-vacancy defect in diamond to quantitatively map the stray magnetic field emitted by a vortex state in a ferromagnetic dot.

  • L. Rondin
  • , J. -P. Tetienne
  •  & V. Jacques

• Article | 31 July 2013

  Transparency and damage tolerance of patternable omniphobic lubricated surfaces based on inverse colloidal monolayers

  It is challenging to design transparent, water-repellent and mechanical robust coatings for a broad range of technological applications. Vogel et al. develop a lubricant-infused surface coating, which satisfies all these requirements and is compatible with conventional patterning processes.

  • Nicolas Vogel
  • , Rebecca A. Belisle
  •  & Joanna Aizenberg

• Article | 31 July 2013

  Silicon-in-silica spheres via axial thermal gradient in-fibre capillary instabilities

  Silicon nanospheres could be of interest for applications in electronics and optoelectronics. Here, Gumenniket al. demonstrate a nanosphere fabrication process based on an optical fibre drawing technique that is able to produce p and n-type spheres paired into rectifying bispherical junctions.

  • Alexander Gumennik
  • , Lei Wei
  •  & Yoel Fink

• Article
  31 July 2013 | Open Access

  Nano-structured smart hydrogels with rapid response and high elasticity

  Smart hydrogels are 3D networks composed of cross-linked polymer chains that can alter their shape and properties in response to environmental stimuli. Xiaet al.demonstrate a smart hydrogel with rapid response and high elasticity, due to its nano-scale structure.

  • Lie-Wen Xia
  • , Rui Xie
  •  & Liang-Yin Chu

• Article | 30 July 2013

  A rational design of cosolvent exfoliation of layered materials by directly probing liquid–solid interaction

  Exfoliation of layered materials into mono- or few-layers is desirable for both fundamental studies and practical applications. Here, the authors show that Young's equation can be used to predict the optimal cosolvent concentration for the effective exfoliation of graphite and molybdenum disulphide.

  • Udayabagya Halim
  • , Chu Ran Zheng
  •  & Xiangfeng Duan

• Article
  29 July 2013 | Open Access

  Helicity-dependent single-walled carbon nanotube alignment on graphite for helical angle and handedness recognition

  The alignment of carbon nanotubes on a surface is of importance to deploy them in electronic devices. Here, Chen et al.achieve the orientation of carbon nanotubes according to their helical angle and handedness, thus separating nanotubes of different electronic properties.

  • Yabin Chen
  • , Ziyong Shen
  •  & Jin Zhang

• Article
  23 July 2013 | Open Access

  In-situ ultra-sensitive infrared absorption spectroscopy of biomolecule interactions in real time with plasmonic nanoantennas

  Infrared absorption spectroscopy provides important information about molecules, but is hampered by the absorption of water. Adato and Altug exploit the plasmonic enhancement from nanoantennas to overcome this, enabling chip-based monitoring of biological samples in aqueous environments.

  • Ronen Adato
  •  & Hatice Altug

• Article | 22 July 2013

  Rare-earth-doped biological composites as in vivo shortwave infrared reporters

  The short-wavelength infrared spectral region is of interest for bio-imaging applications as biological tissue is transparent to such light. Here Naczynski et al. fabricate rare-earth-based nanomaterials and demonstrate multispectral, real-time short-wavelength infrared in-vivoimaging.

  • D. J. Naczynski
  • , M. C. Tan
  •  & P. V. Moghe

• Article | 19 July 2013

  Desktop nanofabrication with massively multiplexed beam pen lithography

  The development of a desktop nanofabrication tool allowing high-resolution patterning and high-throughput synthesis is a long-standing goal in many nanoscience fields. Here, the authors report a system that can write arbitrary patterns composed of diffraction-unlimited features over square centimetre areas.

  • Xing Liao
  • , Keith A. Brown
  •  & Chad A. Mirkin

• Article
  17 July 2013 | Open Access

  Femtolitre chemistry assisted by microfluidic pen lithography

  Chemical reactions on femtolitre scales are necessary to study confined biological processes. Here, the authors use a microfluidic pen lithography technique to perform a series of discrete femtoscale acid-base and synthetic reactions, and crystallizations on a surface with high registration accuracy.

  • Carlos Carbonell
  • , Kyriakos C. Stylianou
  •  & Daniel Maspoch

• Article
  12 July 2013 | Open Access

  Conducting linear chains of sulphur inside carbon nanotubes

  Elemental sulphur is an insulator in the bulk phase, although it may become conducting under ultrahigh-pressure conditions. Here, the authors report a one-dimensional conducting form of sulphur formed by encapsulation inside single-walled and double-walled carbon nanotubes.

  • Toshihiko Fujimori
  • , Aarón Morelos-Gómez
  •  & Katsumi Kaneko

• Article | 27 June 2013

  Chemical vapour deposition growth of large single crystals of monolayer and bilayer graphene

  The growth of high-quality graphene over large areas is essential for the realization of graphene-based electronic devices. Zhou et al.report a new pathway to grow single crystalline graphene of up to 5 mm in size, with very good electronic performance and high uniformity.

  • Hailong Zhou
  • , Woo Jong Yu
  •  & Xiangfeng Duan

• Article
  19 June 2013 | Open Access

  Three-dimensional deep sub-diffraction optical beam lithography with 9 nm feature size

  The fabrication of three-dimensional nanoscale structures is important to nanophotonic applications where light is guided and controlled. The optical beam lithography scheme developed by Gan and colleagues enables the fabrication of three-dimensional structures with feature sizes down to 9 nm.

  • Zongsong Gan
  • , Yaoyu Cao
  •  & Min Gu

• Article | 18 June 2013

  Photolatently modulable hydrogels using unilamellar titania nanosheets as photocatalytic crosslinkers

  Postsynthetic modulation of the structural properties of hydrogels is desirable for a range of biomaterials applications. Here, the authors fabricate photolatently modulable polymer hydrogels crosslinked by titania nanosheets, which may be micropatterned with high spatial and temporal resolution.

  • Mingjie Liu
  • , Yasuhiro Ishida
  •  & Takuzo Aida

• Article | 28 May 2013

  Layer-by-layer assembly of vertically conducting graphene devices

  Vertically assembled graphene devices have received less attention than the typical two dimensional arrangements. Chen et al. show that an Au/graphene/Au assembly exhibits a large magnetoresistance ratio of up to 400%, while a Co/graphene/Co device displays a spin valve effect at room temperature.

  • Jing-Jing Chen
  • , Jie Meng
  •  & Da-Peng Yu

• Article
  30 April 2013 | Open Access

  Top–down fabrication of sub-nanometre semiconducting nanoribbons derived from molybdenum disulfide sheets

  Fabricating semiconductor devices with dimensions below 10 nm presents significant challenges. Here, Liu et al. use controlled electron irradiation to remove atoms in an MoS₂ sheet, creating Mo₅S₄nanoribbons with a uniform width of 0.35 nm and a theoretical band gap of 0.77 eV.

  • Xiaofei Liu
  • , Tao Xu
  •  & Wanlin Guo

• Article
  30 April 2013 | Open Access

  A synthetic route to ultralight hierarchically micro/mesoporous Al(III)-carboxylate metal-organic aerogels

  Hierarchically porous metal-organic monoliths are potential materials for mass transfer applications. Here, the authors synthesize metal-organic aerogels via the gelation of metal-organic frameworks, and are able to tune their porosity exploiting the properties of both crystalline and aerogel materials.

  • Lei Li
  • , Shenglin Xiang
  •  & Cheng-Yong Su

• Article
  23 April 2013 | Open Access

  Probing relaxation times in graphene quantum dots

  The experimental investigation of relaxation times in graphene quantum dots has long been hindered by the limited tunability of these devices. Here Volk et. al.employ a device design to study this problem and report charge relaxation times of around 60–100 ns.

  • Christian Volk
  • , Christoph Neumann
  •  & Christoph Stampfer

• Article | 16 April 2013

  Optical visualization of individual ultralong carbon nanotubes by chemical vapour deposition of titanium dioxide nanoparticles

  The characterization and manipulation of carbon nanotubes is of relevance for a range of nanotechnology applications, but usually requires electron microscopes. Here Zhang et al. evaporate nanoparticles on carbon nanotubes to make them visible even under an optical microscope.

  • Rufan Zhang
  • , Yingying Zhang
  •  & Fei Wei

• Article | 09 April 2013

  Shaping colloids for self-assembly

  Creating new materials requires novel approaches to design and synthesize small building particles. Sacanna et al. develop a versatile synthetic strategy to design and mass-produce colloidal building blocks starting from two different colloids that leads to selectively functionalized surface areas.

  • Stefano Sacanna
  • , Mark Korpics
  •  & Gi-Ra Yi

• Article
  09 April 2013 | Open Access

  Coherent diffraction imaging of nanoscale strain evolution in a single crystal under high pressure

  Extreme pressure can induce significant changes in a material’s mechanical response, but characterizing the evolution of these changes as they take place is challenging. Yang et al. demonstrate the use of coherent X-ray diffraction imaging to follow changes in the three-dimensional shape and strain fields within gold particles under pressure.

  • Wenge Yang
  • , Xiaojing Huang
  •  & Ho-kwang Mao

• Article | 09 April 2013

  Metallized DNA nanolithography for encoding and transferring spatial information for graphene patterning

  The structuring of graphene is important towards its use in electronic applications. Here Strano et al. develop a fast and efficient lithography process enabling the transfer of shape information from self-assembled DNA templates to custom graphene patterns at a resolution of about 10 nm.

  • Zhong Jin
  • , Wei Sun
  •  & Michael S. Strano

• Article
  09 April 2013 | Open Access

  Design principle for increasing charge mobility of π-conjugated polymers using regularly localized molecular orbitals

  Polymers are good potential processable materials for electronic components; however, their charge mobilities are quite low. Here, the authors show that wrapping polymers with macrocycles and localization of π-orbitals realizes an ideal orbital alignment for charge hopping with subsequently increased mobility.

  • Jun Terao
  • , Akihisa Wadahama
  •  & Yasushi Tsuji

• Article | 09 April 2013

  Stepwise self-assembly of C₆₀ mediated by atomic scale moiré magnifiers

  A promising route towards molecular devices is the self-assembly of atoms or molecules on a surface. Here, Gruznev et al. show that the synthesis of unique geometries of C₆₀molecules on gold–indium-covered crystalline silicon is governed by moiré interference.

  • D.V. Gruznev
  • , A.V. Matetskiy
  •  & Y.L. Wang

• Article
  03 April 2013 | Open Access

  Quantum engineering at the silicon surface using dangling bonds

  The ability to add and move individual atoms on a surface with a scanning tunnelling microscope enables precise control over the electronic quantum states of the surface. Schofield et al. show that removing hydrogen atoms from a passivated silicon surface can be used to generate and control such states.

  • S. R. Schofield
  • , P. Studer
  •  & D. R. Bowler

• Article | 19 March 2013

  Magnetic spin imaging under ambient conditions with sub-cellular resolution

  Detecting the magnetic spins of a small number of atoms is important for applications such as magnetic resonance imaging. Here, Steinert et al.demonstrate that nitrogen-vacancy defect centres in diamond allow spin detection at room temperature at length scales smaller than human cells.

  • S. Steinert
  • , F. Ziem
  •  & J. Wrachtrup

• Article
  19 March 2013 | Open Access

  Quantum dot imaging platform for single-cell molecular profiling

  Multiplexed labelling of individual cells allows the direct observation of intracellular molecular composition, but is difficult to achieve with existing techniques. Here, self-assembled fluorescent nanoparticle probes and multicolour multicycle staining are used for the simultaneous evaluation of multiple biomolecules at subcellular resolution.

  • Pavel Zrazhevskiy
  •  & Xiaohu Gao

• Article | 12 March 2013

  Epitaxial lift-off process for gallium arsenide substrate reuse and flexible electronics

  The fabrication of electronic devices depends on semiconductor substrates for device growth. The etching technique implemented here by Cheng et al. allows the reuse of these substrates and suggests a more economic fabrication of electronic devices.

  • Cheng-Wei Cheng
  • , Kuen-Ting Shiu
  •  & Devendra K. Sadana

• Article
  12 March 2013 | Open Access

  In vivo recordings of brain activity using organic transistors

  Flexible organic electronic devices have the potential to serve as biosensors in living animals. Khodagholy et al. show that organic transistors can be used to record brain activity in rats and demonstrate that they have a superior signal-to-noise ratio compared with electrodes due to local signal amplification.

  • Dion Khodagholy
  • , Thomas Doublet
  •  & George G. Malliaras

• Article | 26 February 2013

  A low-temperature method to produce highly reduced graphene oxide

  The chemical reduction of graphene oxide can provide large quantities of reduced graphene oxide for potential application in electronics and composite materials. Feng et al. report a highly efficient low-temperature one-pot reduction of graphene oxide that uses sodium-ammonia solution as the reducing agent.

  • Hongbin Feng
  • , Rui Cheng
  •  & Jinghong Li

• Article | 19 February 2013

  Surface-passivated GaAsP single-nanowire solar cells exceeding 10% efficiency grown on silicon

  The use of III-V semiconductor nanowires can overcome the need for lattice matching in multi-junction solar cells, which restricts the choice of materials and their bandgaps. This work demonstrates efficient solar cells with GaAsP single nanowires with tunable bandgap and grown on low-cost Si substrates.

  • Jeppe V. Holm
  • , Henrik I. Jørgensen
  •  & Martin Aagesen

• Article | 19 February 2013

  A synthetic nanomaterial for virus recognition produced by surface imprinting

  The recognition of viruses by synthetic materials is historically difficult. Here, a templating procedure using silica nanoparticles coated with organosilanes is used to form virus-imprinted particles, possessing both shape and chemical imprints, capable of virus recognition at picomolar concentrations.

  • Alessandro Cumbo
  • , Bernard Lorber
  •  & Patrick Shahgaldian

• Article | 12 February 2013

  Scalable fabrication of high-power graphene micro-supercapacitors for flexible and on-chip energy storage

  Microscale supercapacitors are promising alternative energy-storage devices; however, their use has been limited by the need for complicated fabrication techniques. This work reports the scalable fabrication of graphene supercapacitors with planar geometry that achieve power densities of up to 200 W cm⁻³.

  • Maher F. El-Kady
  •  & Richard B. Kaner

• Article | 05 February 2013

  Engineering the architectural diversity of heterogeneous metallic nanocrystals

  Engineering heterogeneous metallic nanocrystals could produce diverse materials with tunable properties. Here the authors develop a strategy for the rational and independent programming of each architecture-determining element, such as the shape, size and spatial relationship of the component nanocrystals.

  • Yue Yu
  • , Qingbo Zhang
  •  & Jim Yang Lee

• Article | 05 February 2013

  New diluted ferromagnetic semiconductor with Curie temperature up to 180 K and isostructural to the ‘122’ iron-based superconductors

  Diluted magnetic semiconductors are promising spintronic materials, however the simultaneous doping of charge and magnetic moment has prevented synthesis of bulk samples. This work reports the synthesis of a bulk magnetic semiconductor (Ba_1−xK_x)(Zn_1−yMn_y)₂As₂with Curie temperatures up to 180 K.

  • K. Zhao
  • , Z. Deng
  •  & C. Q. Jin

• Article | 05 February 2013

  Solution-phase epitaxial growth of noble metal nanostructures on dispersible single-layer molybdenum disulfide nanosheets

  The ‘wet’ chemical epitaxial growth of nanostructures on semiconducting surfaces is usually hindered by surface defects. Here, the authors show that large surface area single-layer molybdenum disulphide is an ideal substrate for epitaxial growth of a range of metallic nanoparticles.

  • Xiao Huang
  • , Zhiyuan Zeng
  •  & Hua Zhang

• Article
  05 February 2013 | Open Access

  Nanoscale imaging and spontaneous emission control with a single nano-positioned quantum dot

  The emission properties of quantum dots make them ideal for probing plasmonic nanostructures, but their small size makes them difficult to manipulate. Ropp et al.use a microfluidic system to accurately place single quantum dots around silver nanowires to probe the local density of optical states.

  • Chad Ropp
  • , Zachary Cummins
  •  & Edo Waks

• Article | 29 January 2013

  Quantitative experimental determination of site-specific magnetic structures by transmitted electrons

  Understanding magnetic materials at the nanoscale is important for the development of novel applications, but has been hampered by a lack of suitable experimental techniques. Here, the use of transmitted electrons permits the determination of atomic site-specific magnetic information.

  • Z.Q. Wang
  • , X.Y. Zhong
  •  & J. Zhu

• Article | 29 January 2013

  Composite-pulse magnetometry with a solid-state quantum sensor

  Quantum magnetometry in the solid state is usually affected by short coherence times and control errors that limit the sensitivity. This work demonstrates a continuous-driving scheme based on composite pulses that improves both these shortcomings and can be used in variable sensing environments.

  • Clarice D. Aiello
  • , Masashi Hirose
  •  & Paola Cappellaro

• Article | 29 January 2013

  The essential role of carefully optimized synthesis for elucidating intrinsic material properties of (Ga,Mn)As

  The electronic band structure of (Ga,Mn)As has been debated due to contrasting reports of experimental findings from samples differently synthesized. Nĕmec et al.show that a careful optimization of the synthesis protocol is necessary to evaluate the intrinsic semiconducting and magnetic properties of (Ga,Mn)As.

  • P. Nĕmec
  • , V. Novák
  •  & T. Jungwirth

• Article | 11 December 2012

  Holographic detection of the orbital angular momentum of light with plasmonic photodiodes

  Sub-wavelength structures can be used to convert between light and plasmon polaritons. Genevetet al. design holographic plasmonic interfaces that couple vortex light beams to surface plasmons, allowing them to detect the orbital angular momentum of the beam with a simple silicon photodiode.

  • Patrice Genevet
  • , Jiao Lin
  •  & Federico Capasso

• Review Article | 11 December 2012

  Moving from static to dynamic complexity in hydrogel design

  Hydrogels are water-containing polymer networks that have been applied in various biological settings. Burdick and Murphy review recent advances in the development of dynamic hydrogels whose properties and mechanics change in response to biological signals.

  • Jason A. Burdick
  •  & William L. Murphy

• Article
  13 November 2012 | Open Access

  Direct writing of electronic devices on graphene oxide by catalytic scanning probe lithography

  Controlled nanoscale reduction of graphene oxide could aid the development of graphene-based electronics. Here, a relatively mild technique is reported that uses a platinum-coated atomic force microscope tip to catalyse the reduction of graphene oxide to graphene.

  • Kun Zhang
  • , Qiang Fu
  •  & Jianguo Hou

• Article | 06 November 2012

  A general method for the large-scale synthesis of uniform ultrathin metal sulphide nanocrystals

  Ultrathin metal sulphides are attractive components for electronic and optical devices and are promising anode materials for lithium-ion batteries. Here, a universal, soft colloidal templating strategy is employed for the large-scale synthesis of uniform, ultrathin metal sulphide nanomaterials.

  • Yaping Du
  • , Zongyou Yin
  •  & Hua Zhang

• Article
  16 October 2012 | Open Access

  Correlative infrared–electron nanoscopy reveals the local structure–conductivity relationship in zinc oxide nanowires

  High-resolution characterisation techniques enable us to better understand the properties of nanoscale materials and devices. By combining electron microscopy and infrared nanoscopy, Stiegleret al.demonstrate a general approach to simultaneously probe the structural, chemical and electronic properties of a nanostructure.

  • J.M. Stiegler
  • , R. Tena-Zaera
  •  & R. Hillenbrand

• Article | 09 October 2012

  Measuring the size of individual particles from three-dimensional imaging experiments

  The degree of polydispersity of colloidal suspensions is known to have consequences for their physical properties. Kuritaet al. present a general method for determining the sizes of individual particles, and thus the polydispersity, using only the coordinates of the centre positions of spherical particles.

  • Rei Kurita
  • , David B. Ruffner
  •  & Eric R. Weeks

• Article | 11 September 2012

  Fabrication of flexible and freestanding zinc chalcogenide single layers

  Ultrathin inorganic materials hold promise for a variety of applications, including flexible electronics. This work presents a fabrication method that permits the synthesis of large and flexible freestanding layers of zinc selenide that display a high-photocurrent density.

  • Yongfu Sun
  • , Zhihu Sun
  •  & Yi Xie

• Article | 28 August 2012

  Direct dynamic imaging of non-adiabatic spin torque effects

  The torque contributions exerted by spin-polarized currents on magnetic structures are not fully understood due to the difficulty in discerning their relative weight. Pollardet al. propose a novel method to directly determine the value of the competing spin transfer torques by in-situLorentz microscopy.

  • S.D. Pollard
  • , L. Huang
  •  & Y. Zhu