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Buoyancy and Stability for Submerged and Floating Bodies01:11

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In fluid mechanics, buoyancy and stability are key concepts for understanding the behavior of submerged and floating bodies. When a stationary body is fully or partially submerged in a fluid, the fluid exerts a force on the body known as the buoyant force. This force acts vertically upward through a point called the center of buoyancy, which is the center of the displaced fluid volume. According to Archimedes' principle, the magnitude of the buoyant force is equal to the weight of the fluid...
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Fluid dynamics is the study of fluids in motion. Velocity vectors are often used to illustrate fluid motion in applications like meteorology. For example, wind—the fluid motion of air in the atmosphere—can be represented by vectors indicating the speed and direction of the wind at any given point on a map. Another method for representing fluid motion is a streamline. A streamline represents the path of a small volume of fluid as it flows. When the flow pattern changes with time, the...
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Plane potential flows simplify fluid motion by assuming the fluid to be irrotational and incompressible. These characteristics allow these flows to be described by a velocity potential function, ϕ, representing the flow speed in a given direction, and a stream function, ψ, that visualizes the flow path, both governed by Laplace's equation. These parameters help in estimating flow patterns, velocity distributions, and pressure fields around various hydraulic structures.
Uniform...
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Newtonian fluids exhibit a constant viscosity, meaning their shear stress and shear strain rate are directly proportional. This property ensures a predictable and stable response to applied forces, maintaining a linear relationship between force and flow. Examples include water, air, and light oils, consistently demonstrating this proportional behavior regardless of external conditions.
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Stokes' Law01:20

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Viscous forces, like friction, are intermolecular forces that resist the relative motion of molecules over each other. When a solid body moves through a liquid, viscous forces drag it in the opposite direction. The force's magnitude depends on the solid's shape and size, as well as its speed and the liquid's coefficient of viscosity, density and temperature.
The expression for the force on a solid spherical object in a fluid is called Stokes' law. Stokes' law is valid only...
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Gradually varying flow (GVF) in open channels describes situations where water depth changes slowly along the channel due to factors like non-uniform bed slope, channel shape variations, or obstructions. This flow type occurs when the depth adjusts gradually to balance gravitational forces, shear forces, and energy requirements, resulting in a low rate of depth change.Characteristics of Gradually Varying FlowGVF is commonly observed in natural streams, rivers, and canals, where flow depth...
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在周期阵列中,游泳者将从弹道转变为扩散转变.

Taylor J Whitney1, Kevin A Mitchell1

  • 1<a href="https://ror.org/00d9ah105">University of California Merced</a>, 5200 Lake Rd, Merced, California 95343, USA.

Physical review. E
|October 19, 2024
PubMed
概括

旋阵列中的较慢的游泳速度会导致更快的弹道运输,而更快的速度会导致更慢的,混乱的运输. 这一反直觉的发现揭示了微游泳者行为中的复杂动态.

科学领域:

  • 物理 物理学 物理
  • 流体动力学 流体动力学
  • 非线性动力学是一种非线性动力学.

背景情况:

  • 了解微游泳器运输对于有针对性的药物输送和微机器人技术的应用至关重要.
  • 螺旋阵列创建复杂的流动模式,显著影响粒子和游泳者动态.

研究的目的:

  • 为了研究在周期阵列中的刚性圆形游泳者的运输机制.
  • 阐明游泳速度和运输行为 (弹道与扩散) 之间的关系.

主要方法:

  • 游泳者轨迹的数值模拟.
  • 动态系统分析使用时间可逆的庞卡雷回归地图.
  • 组合模拟来分析运输统计和对噪声的强度.

主要成果:

  • 较慢的游泳速度导致快速弹道运输,其特点是稳定的周期轨道和不变的轨道.
  • 较快的游泳速度导致混乱和扩散的运输,由于周期翻倍的分叉.
  • 弹道运输因旋转扩散 (噪声) 的增加而退化.

结论:

  • 这项研究揭示了周期阵列中反直觉的速度运输关系.
  • 动态系统分析解释了从弹道运输到扩散运输的过渡.

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  • 弹道运输模式可以在实验环境中观察到.