Template-Free Preparation of Crystalline Ge Nanowire Film Electrodes via an Electrochemical Liquid–Liquid–Solid Process in Water at Ambient Pressure and Temperature for Energy Storage

Template-Free Preparation of Crystalline Ge Nanowire Film Electrodes via an Electrochemical Liquid–Liquid–Solid Process in Water at Ambient Pressure and Temperature for Energy Storage

The direct electrodeposition of crystalline germanium (Ge) nanowire film electrodes from an aqueous solution of dissolved GeO2 using discrete ‘flux’ nanoparticles capable of dissolving Ge(s) has been demonstrated. Electrodeposition of Ge at inert electrode substrates decorated with small (<100 nm...

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Bibliographic Details
Published in:Nano letters Vol. 12; no. 9; pp. 4617 - 4623
Main Authors: Gu, Junsi, Collins, Sean M, Carim, Azhar I, Hao, Xiaoguang, Bartlett, Bart M, Maldonado, Stephen
Format: Journal Article
Language:English
Published: Washington, DC American Chemical Society 12-09-2012
Subjects:
Chemical synthesis methods
Cross-disciplinary physics: materials science; rheology
Crystal structure
Crystallites
Dissolution
Electric Power Supplies
Electrodes
Electroplating - methods
Equipment Design
Equipment Failure Analysis
Exact sciences and technology
Germanium
Germanium - chemistry
Germanium oxides
Lithium - chemistry
Materials science
Membranes, Artificial
Methods of nanofabrication
Nanocrystalline materials
Nanoparticles
Nanoscale materials and structures: fabrication and characterization
Nanostructures - chemistry
Nanostructures - ultrastructure
Nanowires
Particle Size
Physics
Pressure
Quantum wires
Semiconductors
Water - chemistry
lithium-ion battery anodes
electrodeposition
ec-LLS
Germanium nanowires
Pressure effects
Germanium oxide
Semiconductor materials
Polycrystals
Template reaction
Indium
Thin films
Nanoparticles
Crystallites
Aqueous solutions
Energy conversion
Growth mechanism
Electrochemistry
Electrodeposition
Germanium
Nanowires
Nanostructured materials
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Description
Summary:The direct electrodeposition of crystalline germanium (Ge) nanowire film electrodes from an aqueous solution of dissolved GeO2 using discrete ‘flux’ nanoparticles capable of dissolving Ge(s) has been demonstrated. Electrodeposition of Ge at inert electrode substrates decorated with small (<100 nm), discrete indium (In) nanoparticles resulted in crystalline Ge nanowire films with definable nanowire diameters and densities without the need for a physical or chemical template. The Ge nanowires exhibited strong polycrystalline character as-deposited, with approximate crystallite dimensions of 20 nm and a mixed orientation of the crystallites along the length of the nanowire. Energy dispersive spectroscopic elemental mapping of individual Ge nanowires showed that the In nanoparticles remained at the base of each nanowire, indicating good electrical communication between the Ge nanowire and the underlying conductive support. As-deposited Ge nanowire films prepared on Cu supports were used without further processing as Li+ battery anodes. Cycling studies performed at 1 C (1624 mA g–1) indicated the native Ge nanowire films supported stable discharge capacities at the level of 973 mA h g–1, higher than analogous Ge nanowire film electrodes prepared through an energy-intensive vapor–liquid–solid nanowire growth process. The cumulative data show that ec-LLS is a viable method for directly preparing a functional, high-activity nanomaterials-based device component. The work presented here is a step toward the realization of simple processes that make fully functional energy conversion/storage technologies based on crystalline inorganic semiconductors entirely through benchtop, aqueous chemistry and electrochemistry without time- or energy-intensive process steps.
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ISSN:1530-6984
1530-6992
DOI:10.1021/nl301912f