Thermally induced breakup of metallic nanowires: Experiment and theory

Martin Schnedlitz; Maximilian Lasserus; Daniel Knez; Andreas W. Hauser; Ferdinand Hofer; Wolfgang E. Ernst

doi:10.1039/c7cp00463j

Thermally induced breakup of metallic nanowires: Experiment and theory

Martin Schnedlitz, Maximilian Lasserus, Daniel Knez, Andreas W. Hauser^*, Ferdinand Hofer, Wolfgang E. Ernst

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

We present time-resolved transmission electron microscopy studies of the degradation of Au, Ag, Cu and Ni nanowires deposited on a heated support. The wires are grown under fully inert conditions in superfluid helium droplets and deposited onto amorphous carbon. The inherent stability of these pristine metal nanowires with diameters below 10 nm is investigated in the absence of any stabilizers, templates or solvents. The phenomenon of Rayleigh-breakup, a consequence of diffusion processes along the wire surfaces, is analysed in situ via scans over time and support temperature. Our experimental efforts are combined with simulations based on a novel model featuring a cellular automaton to emulate surface diffusion. Based on this model, correlations between the material parameters and actual breakup behaviour are studied.

Original language	English
Pages (from-to)	9402-9408
Number of pages	7
Journal	Physical Chemistry, Chemical Physics
Volume	19
Issue number	14
DOIs	https://doi.org/10.1039/c7cp00463j
Publication status	Published - 2017

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Physics and Astronomy(all)
Physical and Theoretical Chemistry

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Advanced Materials Science

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title = "Thermally induced breakup of metallic nanowires: Experiment and theory",

abstract = "We present time-resolved transmission electron microscopy studies of the degradation of Au, Ag, Cu and Ni nanowires deposited on a heated support. The wires are grown under fully inert conditions in superfluid helium droplets and deposited onto amorphous carbon. The inherent stability of these pristine metal nanowires with diameters below 10 nm is investigated in the absence of any stabilizers, templates or solvents. The phenomenon of Rayleigh-breakup, a consequence of diffusion processes along the wire surfaces, is analysed in situ via scans over time and support temperature. Our experimental efforts are combined with simulations based on a novel model featuring a cellular automaton to emulate surface diffusion. Based on this model, correlations between the material parameters and actual breakup behaviour are studied.",

author = "Martin Schnedlitz and Maximilian Lasserus and Daniel Knez and Hauser, {Andreas W.} and Ferdinand Hofer and Ernst, {Wolfgang E.}",

year = "2017",

doi = "10.1039/c7cp00463j",

language = "English",

volume = "19",

pages = "9402--9408",

journal = "Physical Chemistry, Chemical Physics",

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T2 - Experiment and theory

AU - Schnedlitz, Martin

AU - Lasserus, Maximilian

AU - Knez, Daniel

AU - Hauser, Andreas W.

AU - Hofer, Ferdinand

AU - Ernst, Wolfgang E.

PY - 2017

Y1 - 2017

N2 - We present time-resolved transmission electron microscopy studies of the degradation of Au, Ag, Cu and Ni nanowires deposited on a heated support. The wires are grown under fully inert conditions in superfluid helium droplets and deposited onto amorphous carbon. The inherent stability of these pristine metal nanowires with diameters below 10 nm is investigated in the absence of any stabilizers, templates or solvents. The phenomenon of Rayleigh-breakup, a consequence of diffusion processes along the wire surfaces, is analysed in situ via scans over time and support temperature. Our experimental efforts are combined with simulations based on a novel model featuring a cellular automaton to emulate surface diffusion. Based on this model, correlations between the material parameters and actual breakup behaviour are studied.

AB - We present time-resolved transmission electron microscopy studies of the degradation of Au, Ag, Cu and Ni nanowires deposited on a heated support. The wires are grown under fully inert conditions in superfluid helium droplets and deposited onto amorphous carbon. The inherent stability of these pristine metal nanowires with diameters below 10 nm is investigated in the absence of any stabilizers, templates or solvents. The phenomenon of Rayleigh-breakup, a consequence of diffusion processes along the wire surfaces, is analysed in situ via scans over time and support temperature. Our experimental efforts are combined with simulations based on a novel model featuring a cellular automaton to emulate surface diffusion. Based on this model, correlations between the material parameters and actual breakup behaviour are studied.

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DO - 10.1039/c7cp00463j

M3 - Article

AN - SCOPUS:85019586820

SN - 1463-9076

VL - 19

SP - 9402

EP - 9408

JO - Physical Chemistry, Chemical Physics

JF - Physical Chemistry, Chemical Physics

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ER -

Thermally induced breakup of metallic nanowires: Experiment and theory

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