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RESEARCH PRODUCT
3D superconducting hollow nanowires with tailored diameters grown by focused He+ beam direct writing
Dominique MaillyIsabel GuillamónJosé María De TeresaHermann SuderowAlfonso IbarraRosa Córdobasubject
NanostructureMaterials scienceIon beamelectron tomographyNanowireGeneral Physics and Astronomy02 engineering and technologyfocused ion beam induced deposition (FIBID)lcsh:Chemical technologylcsh:Technology01 natural sciencesFull Research Paperchemistry.chemical_compoundTungsten carbide0103 physical sciencesNanotechnologylcsh:TP1-1185tungsten carbide (WC)General Materials Sciencehelium ion microscopeElectrical and Electronic Engineeringlcsh:Science010302 applied physicslcsh:Tbusiness.industrynano-superconductorsmagneto-transport measurements021001 nanoscience & nanotechnologyMicrostructureAspect ratio (image)lcsh:QC1-999NanosciencechemistryElectron tomographyTransmission electron microscopy[PHYS.COND.CM-MS]Physics [physics]/Condensed Matter [cond-mat]/Materials Science [cond-mat.mtrl-sci]Optoelectronicslcsh:Q0210 nano-technologybusinesslcsh:Physicsdescription
Currently, the patterning of innovative three-dimensional (3D) nano-objects is required for the development of future advanced electronic components. Helium ion microscopy in combination with a precursor gas can be used for direct writing of three-dimensional nanostructures with a precise control of their geometry, and a significantly higher aspect ratio than other additive manufacturing technologies. We report here on the deposition of 3D hollow tungsten carbide nanowires with tailored diameters by tuning two key growth parameters, namely current and dose of the ion beam. Our results show the control of geometry in 3D hollow nanowires, with outer and inner diameters ranging from 36 to 142 nm and from 5 to 28 nm, respectively; and lengths from 0.5 to 8.9 µm. Transmission electron microscopy experiments indicate that the nanowires have a microstructure of large grains with a crystalline structure compatible with the face-centered cubic WC1−x phase. In addition, 3D electron tomographic reconstructions show that the hollow center of the nanowires is present along the whole nanowire length. Moreover, these nanowires become superconducting at 6.8 K and show high values of critical magnetic field and critical current density. Consequently, these 3D nano-objects could be implemented as components in the next generation of electronics, such as nano-antennas and sensors, based on 3D superconducting architectures.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-08-11 |