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Poiseuille's Law and Reynolds Number01:10

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Any fluid in a horizontal tube can flow due to pressure differences—fluid flows from high to low pressure. The flow rate (Q) is the ratio of pressure difference and resistance through a horizontal tube. The greater the pressure difference, the higher the flow rate. The flow resistance is expressed as:
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Viscosity of Fluid01:19

Viscosity of Fluid

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Viscosity measures the resistance a fluid offers to flow and deformation. It results from internal friction between layers of fluid moving relative to one another. Dynamic viscosity, denoted by the Greek letter mu (μ), quantifies the force needed to move one fluid layer over another. For Newtonian fluids like water and air, the relationship between the shearing stress and the rate of shearing strain is linear, meaning their viscosity remains constant regardless of the applied stress.
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Irrotational Flow01:28

Irrotational Flow

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Irrotational flow is characterized by fluid motion where particles do not rotate around their axes, resulting in zero vorticity. For a flow to be irrotational, the curl of the velocity field must be zero. This imposes specific conditions on velocity gradients. For instance, to maintain zero rotation about the z-axis, the gradient condition:
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When water is poured into a glass, it falls freely and quickly, whereas if honey or maple syrup is poured over a pancake, it flows slowly and sticks to the surface of the container. This difference in the flow of different kinds of liquids arises due to the fluid friction between the liquid layers and the liquid and the surrounding material. This property of fluids is called fluid viscosity. In this example, water has a lower viscosity than honey and maple syrup.
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Hagen-Poiseuille flow describes a viscous fluid's steady, incompressible flow through a cylindrical tube with a constant radius R. This flow profile is often applied to understand fluid transport in narrow channels, such as capillaries. It serves as a foundational example of laminar flow. In this model, cylindrical coordinates (r,θ,z) are used to describe the radial (r), angular (θ), and axial (z) dimensions within the tube. For Hagen-Poiseuille flow, the velocity profile is...
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Euler's Equations of Motion01:28

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In fluid mechanics, shear stresses arise from viscosity, which represents a fluid's internal resistance to deformation. For low-viscosity fluids, like water, these stresses are minimal, simplifying flow analysis by allowing the fluid to be treated as inviscid, or frictionless. In an inviscid fluid, shear stresses are absent, leaving only normal stresses, which act perpendicularly to fluid elements. Notably, pressure — defined as the negative of the normal stress — remains...
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Uncoupling Coriolis Force and Rotating Buoyancy Effects on Full-Field Heat Transfer Properties of a Rotating Channel
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洛伦茨反向定理在具有奇异粘度的流体中

Yuto Hosaka1, Ramin Golestanian1,2,3, Andrej Vilfan1,4

  • 1Max Planck Institute for Dynamics and Self-Organization (MPI-DS), Am Fassberg 17, 37077 Göttingen, Germany.

Physical review letters
|November 13, 2023
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概括

洛伦茨反向定理在性活性流体中被违反,但可以通过使用辅助问题来概括. 这一概括定理适用于微游泳器,揭示了奇异粘度如何影响它们的运动,特别是那些具有活性力的运动.

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科学领域:

  • 水力动力学是指水力动力学.
  • 活动物质物理学 活动物质物理学
  • 非平衡的统计力学 统计力学

背景情况:

  • 洛伦茨反向定理是研究水力动力学运输现象的基础.
  • 具有奇异粘度的状活性流体破坏了时间逆转和平价对称性,违反了标准定理.
  • 了解这些违规行为对于模拟复杂的流体行为至关重要.

研究的目的:

  • 为了将洛伦茨反向定理推广到具有奇数粘度的性活性流体.
  • 为了研究奇异粘度对微游泳者动态的影响.
  • 为分析活性流体系统提供理论框架.

主要方法:

  • 通过引入一个具有相反奇数粘度的辅助问题来制定一个概括的洛伦茨反向定理.
  • 分析了两类微游泳器:具有规定的表面速度和具有规定的活性力的微游泳器.
  • 将概括定理应用于特定的微游泳模型,包括具有扭矩双极的模型.

主要成果:

  • 洛伦茨反向定理可以成功地概括,包括奇数粘度.
  • 具有规定的表面速度的微游泳器不受奇异粘度的影响.
  • 带有规定的活性力的微游泳器受到奇异粘度的影响,扭矩二极管诱导定向运动.

结论:

  • 一般化的洛伦茨反向定理为活跃流体研究提供了一个强大的工具.
  • 奇异的粘度在某些活性物质系统的运动中起着重要作用.
  • 这项工作有助于我们更好地理解在性活性流体中非互惠现象.