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Seth Lichter

教授 Mechanical Engineering · Northwestern University  high

Professor of Mechanical Engineering

🏠 教授主页

研究方向

  • 液固界面动力学
    • 库埃特流动分析
      • 滑移现象
        • 分子级机制
        • 扭结传播
液固界面库埃特流动滑移分子级机制扭结传播液体原子固体基底切向速度分子动力学界面动力学流动分析边界条件相对速度液体滑移界面现象原子运动界面滑移粘附流体力学表面科学剪切应力润滑分子模拟原子速度界面摩擦吸附表面粗糙度分子输运热力学动力学理论边界层粘弹性润湿性表面化学

该校申请信息 · Northwestern University

ME deadlineDec 15 (2025 Fall (legacy · deadline 需按新申请季重验))
申请费$95

近三年论文 · 2 篇 (点击展开摘要,时间倒序)

Slip due to kink propagation at the liquid–solid interface
Journal of Fluid Mechanics · 2024 · cited 0 · doi.org/10.1017/jfm.2024.1013
In Couette flow, the liquid atoms adjacent to a solid substrate may have a finite average tangential velocity relative to the substrate. This so-called slip has been observed frequently. However, the particular molecular-level mechanisms that give rise to liquid slip are poorly understood. It is often assumed that liquid slip occurs by surface diffusion whereby atoms independently move from one substrate equilibrium site to another. We show that under certain conditions, liquid slip is due not to singular independent molecular motion, but to localized nonlinear waves that propagate at speeds that are orders of magnitude greater than the slip velocity at the liquid–solid interface. Using non-equilibrium molecular dynamics simulations, we find the properties of these waves and the conditions under which they are to be expected as the main progenitors of slip. We also provide a theoretical guide to the properties of these nonlinear waves by using an augmented Frenkel–Kontorova model. The new understanding provided by our results may lead to enhanced capabilities of the liquid–solid interface, for heat transfer, mixing, and surface-mediated catalysis.
Slip Due to Kink Propagation at the Liquid-Solid Interface
arXiv (Cornell University) · 2024 · cited 0 · doi.org/10.48550/arxiv.2409.04445
In Couette flow, the liquid atoms adjacent to a solid substrate may have a finite average tangential velocity relative to the substrate. This so-called slip has been frequently observed. However, the particular molecular-level mechanisms that give rise to liquid slip are poorly understood. It is often assumed that liquid slip occurs by surface diffusion whereby atoms independently move from one substrate equilibrium site to another. We show that under certain conditions, liquid slip is due not to singular independent molecular motion, but to localized nonlinear waves that propagate at speeds that are orders of magnitude greater than the slip velocity at the liquid-solid interface. Using non-equilibrium molecular dynamics simulations, we find the properties of these waves and the conditions under which they are to be expected as the main progenitors of slip. We also provide a theoretical guide to the properties of these nonlinear waves by using an augmented Frenkel-Kontorova model. The new understanding provided by our results may lead to enhanced capabilities of the liquid-solid interface, for heat transfer, mixing, and surface-mediated catalysis.