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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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When an object is placed in a fluid, it either floats or sinks. All objects in a fluid experience a buoyant force. For example, a metal ball sinks, while a rubber ball floats. Similarly, a submarine can sink and float by adjusting its buoyancy.  The concept of buoyancy raises several interesting questions. For instance, where does this buoyant force come from? How much buoyant force is required to make an object sink or float? Do objects that sink get any support at all from the...
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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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A two-dimensional system in mechanical engineering involves the analysis of motion and forces in a plane. A two-dimensional force vector can be resolved into its components as:
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Solving problems related to two-dimensional force systems is an essential aspect of mechanics and engineering. By applying the principles of vector analysis and force equilibrium, one can determine the effect of multiple forces acting on an object in a two-dimensional space.
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Three-Dimensional Force System:Problem Solving01:30

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A three-dimensional force system refers to a scenario in which three forces act simultaneously in three different directions. This type of problem is commonly encountered in physics and engineering, where it is necessary to calculate the resultant force on the system, which can then be used to predict or analyze the behavior of the object or structure under consideration.
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洛伦兹力驱动自主游泳器

Gerardo Salinas1, Kostiantyn Tieriekhov1, Patrick Garrigue1

  • 1Bordeaux INP, ISM, UMR 5255, University of Bordeaux, CNRS, F-33607 Pessac, France.

Journal of the American Chemical Society
|August 3, 2021
PubMed
概括

研究人员利用离子流和磁场将自主游泳者的速度提高了100倍. 这种协同作用可以精确控制游泳者轨迹,为微观和宏观应用提供新的可能性.

科学领域:

  • 物理,材料科学,纳米技术,化学工程

背景情况:

  • 自主游泳器对于生物医学和环境修复的应用至关重要.
  • 现有的游泳者依靠自我推进或外部刺激来运动.
  • 控制游泳者的速度和轨迹仍然是一个关键挑战.

研究的目的:

  • 研究离子流和磁场对Mg/Pt Janus游泳器的协同作用.
  • 开发一种用于自主游泳的新型推进和控制机制.
  • 在不同尺寸的物体中探索这种效应的可扩展性.

主要方法:

  • 使用了自我电泳的Mg/Pt Janus游泳器.
  • 应用了与自发离子电流对角的外部磁场.
  • 分析了由此产生的磁动力学 (MHD) 效应和洛伦兹力.
  • 沿着游泳器边缘进行探测,以控制轨迹.
  • 在宏观和微观尺度上观察运动.

主要成果:

  • 对于游泳者来说,速度增加了两倍.
  • 通过磁场方向对游泳者轨迹 (顺时针/反顺时针运动) 进行精确控制.
  • 证实了推进和控制机制与游泳器尺寸的独立性.

结论:

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  • 离子流和磁场之间的协同作用为自主游泳器提供了高效的推进机制.
  • 这种方法提供了前所未有的游泳轨迹控制,
  • 开辟了用于各种应用的先进微型和纳米机器人的新途径.