Open AccessReal-Time Observation of Nanosecond Liquid-Phase Assembly of Nickel Nanoparticles via Pulsed-Laser Heating
Author(s) -
Joseph T. McKeown,
Nicholas A. Roberts,
Jason D. Fowlkes,
Yueying Wu,
Thomas LaGrange,
Bryan W. Reed,
Geoffrey H. Campbell,
Philip D. Rack
Publication year - 2012
Publication title -
langmuir
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.042
H-Index - 333
eISSN - 1520-5827
pISSN - 0743-7463
DOI - 10.1021/la303657e
Subject(s) - dewetting , spinodal , nanosecond , materials science , laser , nanoparticle , nanomaterials , nanometre , phase (matter) , spinodal decomposition , nanotechnology , instability , optoelectronics , thin film , chemical physics , analytical chemistry (journal) , optics , chemistry , composite material , physics , organic chemistry , mechanics , chromatography
Using pump-probe electron microscopy techniques, the dewetting of thin nickel films exposed to a pulsed nanosecond laser was monitored at tens of nanometers spatial and nanosecond time scales to provide insight into the liquid-phase assembly dynamics. Thickness-dependent and correlated time and length scales indicate that a spinodal instability drives the assembly process. Measured lifetimes of the liquid metal are consistent with finite-difference simulations of the laser-irradiated film and are consistent with estimated and observed spinodal time scales. These results can be used to design improved synthesis and assembly routes toward achieving advanced functional nanomaterials and devices.
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