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相关概念视频

Reynolds Transport Theorem01:24

Reynolds Transport Theorem

859
The Reynolds transport theorem provides a framework to relate the time rate of change of an extensive property within a system to that in a control volume, which is crucial for analyzing fluid dynamics. Extensive properties, such as mass, velocity, acceleration, temperature, and momentum, can be expressed in terms of the mass of a fluid portion. These properties are called extensive because they depend on the system's size, while intensive properties are their corresponding values per unit...
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Conservation of Mass in Finite Cotrol Volume01:16

Conservation of Mass in Finite Cotrol Volume

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The principle of conservation of mass is a fundamental law in fluid mechanics and is applied using the continuity equation. We apply the concept to a finite control volume to derive the continuity equation.
A system is defined as a collection of unchanging contents, and the conservation of mass states that a system's mass is constant.
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Bernoulli's Equation00:59

Bernoulli's Equation

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In the middle of the nineteenth century, it was observed that two trains passing each other at a high relative speed get pulled towards each other. The same occurs when two cars pass each other at a high relative speed. The reason is that the fluid pressure drops in the region where the fluid speeds up. As the air between the trains or the cars increases in speed, its pressure reduces. The pressure on the outer parts of the vehicles is still the atmospheric pressure, while the resultant...
10.1K
Energy Conservation and Bernoulli's Equation01:16

Energy Conservation and Bernoulli's Equation

8.6K
Applying the conservation of energy principle or the work-energy theorem to an incompressible, inviscid fluid in laminar, steady, irrotational flow leads to Bernoulli's equation. It states that the sum of the fluid pressure, potential, and kinetic energy per unit volume is constant along a streamline.
All the terms in the equation have the dimension of energy per unit volume. The kinetic energy per unit volume is called the kinetic energy density, and the potential energy per unit volume is...
8.6K
Continuity Equation01:28

Continuity Equation

1.3K
The continuity equation asserts that the mass flow rate must remain constant for a steady flow of an incompressible fluid within a confined system. This principle applies to systems where fluid passes through varying cross-sectional areas, such as nozzles, syringes, and pipes.
The mass flow rate is expressed as:
1.3K
Control Volume and System Representations01:16

Control Volume and System Representations

862
Two key frameworks are employed to analyze mass, energy, and momentum transfer: the control volume approach and the system approach. These frameworks offer different perspectives, depending on whether the focus is on a specific region in space (control volume approach) or a defined mass of fluid (system approach).
The control volume approach considers a stationary region in space through which fluid flows. This region is bounded by a control surface.  For instance, in the case of water...
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相关实验视频

Updated: Jun 6, 2025

Analyzing Mixing Inhomogeneity in a Microfluidic Device by Microscale Schlieren Technique
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Analyzing Mixing Inhomogeneity in a Microfluidic Device by Microscale Schlieren Technique

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不同质系统的压缩理论.

Doruk Efe Gökmen1,2,3,4, Sounak Biswas5, Sebastian D Huber6

  • 1Institute for Theoretical Physics, ETH Zurich, Zurich, Switzerland. gokmen@uchicago.edu.

Nature communications
|November 25, 2024
PubMed
概括
此摘要是机器生成的。

压缩理论从不规则结构上的复杂系统中提取关键数据. 这使得对缺乏转化不变的系统能够进行有效的理论,揭示了异国情调的关键点.

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The Diffusion of Passive Tracers in Laminar Shear Flow
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相关实验视频

Last Updated: Jun 6, 2025

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Analyzing Mixing Inhomogeneity in a Microfluidic Device by Microscale Schlieren Technique

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The Diffusion of Passive Tracers in Laminar Shear Flow
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科学领域:

  • 复杂系统物理 复杂系统物理
  • 数据驱动的计算方法 数据驱动的计算方法
  • 凝聚物质理论 凝聚物质理论

背景情况:

  • 复杂的系统往往涉及在不均的图表上相互作用的自由度.
  • 缺乏转化不变性挑战了传统的理论工具,如重新规范化组.
  • 数据可用性和计算方法的进步为分析提供了新的途径.

研究的目的:

  • 开发一种方法来提取任意几何体内的相关自由度.
  • 创建高效的数值工具,从数据中构建有效的理论.
  • 将这种方法应用于缺乏转化不变性的复杂物理系统.

主要方法:

  • 使用压缩理论来获取自由度.
  • 开发高效的数值工具,用于数据驱动的理论构建.
  • 将该方法应用于准晶体上的强相关系统和随机图上的反铁磁系统.

主要成果:

  • 在任意几何体中成功提取相关的自由度.
  • 在一个准晶体系统中发现了一个异国情调的临界点,其符合对称性被打破了.
  • 将该方法应用于非双边随机图,显示其在周期性缺失的情况下的适用性.

结论:

  • 压缩理论为分析缺乏转化不变的复杂系统提供了一个强大的框架.
  • 开发的数值工具使得直接从数据中构建有效的理论成为可能.
  • 这种方法为了解多样化,复杂系统中的通用物理行为开辟了新的可能性.