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相关概念视频

Ferromagnetism01:31

Ferromagnetism

2.5K
Materials like iron, nickel, and cobalt consist of magnetic domains, within which the magnetic dipoles are arranged parallel to each other. The magnetic dipoles are rigidly aligned in the same direction within a domain by quantum mechanical coupling among the atoms. This coupling is so strong that even thermal agitation at room temperature cannot break it. The result is that each domain has a net dipole moment. However, some materials have weaker coupling, and are ferromagnetic at lower...
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Motional Emf01:22

Motional Emf

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Magnetic flux depends on three factors: the strength of the magnetic field, the area through which the field lines pass, and the field's orientation with respect to the surface area. If any of these quantities vary, a corresponding variation in magnetic flux occurs. If the area through which the magnetic field lines are passing changes, then the magnetic flux also changes. This change in the area can be of two types: the flux through the rectangular loop increases as it moves into the...
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Gauss's Law in Dielectrics01:17

Gauss's Law in Dielectrics

4.6K
Consider a polar dielectric placed in an external field. In such a dielectric, opposite charges on adjacent dipoles neutralize each other, such that the net charge within the dielectric is zero. When a polar dielectric is inserted in between the capacitor plates, an electric field is generated due to the presence of net charges near the edge of the dielectric and the metal plates interface. Since the external electrical field merely aligns the dipoles, the dielectric as a whole is neutral. An...
4.6K
Faraday's Law01:10

Faraday's Law

4.4K
Faraday's law state that the induced emf is the negative change in the magnetic flux per unit of time. Any change in the magnetic field or change in the orientation of the area of the coil with respect to the magnetic field induces a voltage (emf). The magnetic flux measures the number of magnetic field lines through a given surface area. Magnetic flux is estimated from the integral of the dot product of the magnetic field vector and the area vector. The negative sign describes the...
4.4K
Charging Conductors By Induction01:15

Charging Conductors By Induction

8.2K
The Earth is a good conductor of electricity, and it is so big that it can be considered an infinite source or sink of charges. It can easily exchange charges with any matter.
Generally, conductors like metals do not allow any excess charge to be present on them. Any excess charge added to metals easily flows away, for example, when a metal is placed on the Earth. This process is called earthing.
However, conductors can be charged by a process called induction. For example, consider charging a...
8.2K
Electric Field Inside a Conductor01:20

Electric Field Inside a Conductor

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When a conductor is placed in an external electric field, the free charges in the conductor redistribute and very quickly reach electrostatic equilibrium. The resulting charge distribution and its electric field have many interesting properties, which can be investigated with the help of Gauss's law.
Suppose a piece of metal is placed near a positive charge. The free electrons in the metal are attracted to the external positive charge and migrate freely toward that region. This region then...
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A Fabrication and Measurement Method for a Flexible Ferroelectric Element Based on Van Der Waals Heteroepitaxy
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铁电行业中的伯努利原理

Anna Razumnaya1, Yuri Tikhonov2,3, Dmitrii Naidenko4

  • 1Condensed Matter Physics Department, Jozef Stefan Institute, 1000 Ljubljana, Slovenia.

Nanomaterials (Basel, Switzerland)
|July 12, 2025
PubMed
概括
此摘要是机器生成的。

铁电极化流量像流体流一样保持,遵循纳米棒中的伯努利原理. 几何变化导致铁电材料的极化变化和新的拓结构.

关键词:
根茨堡兰多德文郡的理论铁电磁力学 铁电磁力学铁电器 铁电器 铁电器纳米电子学纳米电子学纳米棒是一种纳米棒.阶段场建模的阶段场建模.拓学的状态 拓状态

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Bulk and Thin Film Synthesis of Compositionally Variant Entropy-stabilized Oxides
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科学领域:

  • 凝聚物质物理学 凝聚物质物理学
  • 材料科学 材料科学 材料科学
  • 软物质物理学 软物质物理学

背景情况:

  • 铁电材料具有自发的电极化.
  • 了解狭窄几何体内的纳米极化对于基础物理学和技术至关重要.
  • 流体动力学原理为铁电行为提供了潜在的类比.

研究的目的:

  • 扩展经典的伯努利原理来描述铁电纳米棒中的极化流量保存.
  • 为了研究几何变化对极化分布的影响.
  • 探索拓极化结构的出现.

主要方法:

  • 伯努利原理的理论延伸到极化流量.
  • 分析具有不同横截面积的铁电纳米棒.
  • 研究相位分离和拓结构的形成.

主要成果:

  • 在铁电纳米棒中证明了极化流量的保存,类似于流体流动.
  • 在收缩中观察到增加的两极分化,在扩张中观察到减少的两极分化.
  • 识别了导致拓结构 (泡,卷曲,Hopfions) 的相分离,超出了临界扩张.

结论:

  • 伯努利原理有效地控制了铁电纳米结构中的极化流量保存.
  • 几何限制决定了极化行为,并可以诱导复杂的拓状态.
  • 这些发现适用于软铁电,包括铁电性阴性液晶,影响中等尺度状态.