Yuhang Zhang scite author profile

The understanding of the shrinkage dynamics of plasmonic bubbles formed around metallic nanoparticles immersed in liquid and irradiated by a resonant light source is crucial for the usage of these bubbles in numerous applications. In this paper, we experimentally show and theoretically explain that a plasmonic bubble during its shrinkage undergoes two different phases: first, a rapid partial bubble shrinkage governed by vapor condensation and, second, a slow diffusion-controlled bubble dissolution. The history of the bubble formation plays an important role in the shrinkage dynamics during the first phase as it determines the gas–vapor ratio in the bubble composition. Higher laser powers lead to more vaporous bubbles, while longer pulses and higher dissolved air concentrations lead to more gaseous bubbles. The dynamics of the second phase barely depends on the history of bubble formation, that is, laser power and pulse duration, but strongly on the dissolved air concentration, which defines the concentration gradient at the bubble interface. Finally, for the bubble dissolution in the second phase, with decreasing dissolved air concentration, we observe a gradual transition from a R(t) ∝ (t 0 – t)1/3 scaling law to a R(t) ∝ (t 0 – t)1/2 scaling law where t 0 is the lifetime of the bubble and theoretically explain this transition.

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Nanoindentation response of nanocrystalline copper via molecular dynamics: Grain-size effect

Zhang

et al. 2020

Materials Chemistry and Physics

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Characterization of the deformation behaviors under uniaxial stress for bicontinuous nanoporous amorphous alloys

Zhang

et al. 2022

Phys. Chem. Chem. Phys.

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Structure-property relation of nanoporous graphene membranes

Tian

Zhang

et al. 2020

Carbon

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Cold welding behavior of metallic glass nanowires: Insights from large-scale numerical simulations

Zhang

Zhou

et al. 2021

J Mater Sci

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Cold welding technique at room temperature is the preferred option in nanoassembly and nano-jointing. In this study, the cold welding behavior and mechanical strength of Cu 50 Zr 50 metallic glass nanowires (MGNWs) in head-tohead contact are investigated by molecular dynamics simulation based on the embedded atom method potential. Effects of welding velocity, operating temperature, and size of nanowires are discussed with the consideration of stress, shear strain, atomic deformation processes, and weld quality. Our simulation results demonstrate that a desirable weld quality can be obtained at room temperature. With an increase in welding velocity, the shear deformation zones of the welded MGNWs increase, leading to a decrease in mechanical strength. However, the effect of temperature on the weld quality is not pronounced. Besides, the elongation ability of the welded MGNWs increases with increasing diameters of nanowires. Smaller diameter results in better weld quality due to the size effect of metallic glass. For a pair of MGNWs with different diameters, the necking and fracture of the welded MGNWs occur in the regions of the nanowire with a relatively smaller diameter. This study carries major implications for the fabrication and structural assembly of metallic glass-based nanomaterials.

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Yuhang Zhang

Gas–Vapor Interplay in Plasmonic Bubble Shrinkage

Nanoindentation response of nanocrystalline copper via molecular dynamics: Grain-size effect

Characterization of the deformation behaviors under uniaxial stress for bicontinuous nanoporous amorphous alloys

Structure-property relation of nanoporous graphene membranes

Cold welding behavior of metallic glass nanowires: Insights from large-scale numerical simulations

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