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関連する概念動画

Phase Transitions: Vaporization and Condensation02:39

Phase Transitions: Vaporization and Condensation

22.3K
The physical form of a substance changes on changing its temperature. For example, raising the temperature of a liquid causes the liquid to vaporize (convert into vapor). The process is called vaporization—a surface phenomenon. Vaporization occurs when the thermal motion of the molecules overcome the intermolecular forces, and the molecules (at the surface) escape into the gaseous state. When a liquid vaporizes in a closed container, gas molecules cannot escape. As these gas phase...
22.3K
Viscosity of Fluid01:19

Viscosity of Fluid

2.3K
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.
2.3K
Pressure Variation in a Fluid at Rest01:11

Pressure Variation in a Fluid at Rest

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In a fluid at rest, the pressure at any point beneath the fluid surface depends solely on the depth, not on the container's shape or size. This principle, known as hydrostatic pressure, arises because, in stationary fluids, there is no acceleration, meaning the forces within the fluid balance out. Only vertical forces, caused by the weight of the fluid above, contribute to pressure changes with depth.
When measuring pressure at two different levels within the fluid, the difference in...
1.1K
Irrotational Flow01:28

Irrotational Flow

1.3K
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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Couette Flow01:22

Couette Flow

1.4K
Couette flow represents the flow of fluid between two parallel plates, with one plate fixed and the other moving with a constant velocity. This configuration allows for a simplified analysis using the Navier-Stokes equations, which govern fluid motion under conditions of viscosity and incompressibility. For Couette flow, the assumptions include a steady, laminar, incompressible flow with a zero-pressure gradient in the flow direction. This flow type is beneficial for understanding shear-driven...
1.4K
Dimensionless Groups in Fluid Mechanics01:15

Dimensionless Groups in Fluid Mechanics

960
Dimensionless groups in fluid mechanics provide simplified ratios that help analyze fluid behavior without relying on specific units. The Reynolds number (Re), which represents the ratio of inertial to viscous forces, distinguishes between laminar and turbulent flows, making it essential in the design of pipelines and aerodynamic surfaces. The Froude number (Fr), the ratio of inertial to gravitational forces, is particularly useful in predicting wave formation and hydraulic jumps in...
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関連する実験動画

Updated: Apr 15, 2026

Scanning SQUID Study of Vortex Manipulation by Local Contact
06:53

Scanning SQUID Study of Vortex Manipulation by Local Contact

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超流動ヘリウム:量子化された渦の可視化.

Gregory P Bewley1, Daniel P Lathrop, Katepalli R Sreenivasan

  • 1Department of Physics, Institute for Research in Electronics and Applied Physics, Institute for Physical Sciences and Technology, University of Maryland, College Park, Maryland 20742, USA.

Nature
|June 2, 2006
PubMed
まとめ

研究者は,固体水素粒子を用いて,液体ヘリウム中の量子化された渦の核をイメージした. この新しい技術により,渦の幾何学と3次元での相互作用を直接観察することができます.

科学分野:

  • 低温物理学 低温物理学とは
  • 量子流体力学とは

背景:

  • 量子化された渦は,液体ヘリウムの超流動性にとって根本的なものです.
  • 直径わずか数アングストロームの核構造は,直接視覚化するのが困難でした.

研究 の 目的:

  • 量子化された渦の核の3次元構造をイメージするための新しい方法を開発する.
  • 渦の中核の幾何学と相互作用の直接観測を可能にします.

主な方法:

  • 小さな固体水素粒子の生成.
  • これらの粒子を液体ヘリウム内のトレーサーとして利用する.
  • 量子化された渦の3次元環境をイメージする.

主要な成果:

  • 液体ヘリウム中の量子化された渦の核を視覚化することに成功しました.
  • 渦の幾何学を直接観察する能力を示した.
  • 渦の相互作用を研究するための方法を提供した.

結論:

  • 固体水素粒子は,超流体現象を調査するための強力な新しいツールを提供します.
  • 量子化された渦の中核を直接画像化することで,量子乱流の理解が進んでいます.

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Experimental Investigation of the Flow Structure over a Delta Wing Via Flow Visualization Methods

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関連する実験動画

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