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Gauss's Law01:07

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If a closed surface does not have any charge inside where an electric field line can terminate, then the electric field line entering the surface at one point must necessarily exit at some other point of the surface. Therefore, if a closed surface does not have any charges inside the enclosed volume, then the electric flux through the surface is zero. What happens to the electric flux if there are some charges inside the enclosed volume? Gauss's law gives a quantitative answer to this question.
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Gauss's Law: Planar Symmetry01:27

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A planar symmetry of charge density is obtained when charges are uniformly spread over a large flat surface. In planar symmetry, all points in a plane parallel to the plane of charge are identical with respect to the charges. Suppose the plane of the charge distribution is the xy-plane, and the electric field at a space point P with coordinates (x, y, z) is to be determined. Since the charge density is the same at all (x, y) - coordinates in the z = 0 plane, by symmetry, the electric field at P...
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Gauss's Law: Spherical Symmetry01:26

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A charge distribution has spherical symmetry if the density of charge depends only on the distance from a point in space and not on the direction. In other words, if the system is rotated, it doesn't look different. For instance, if a sphere of radius R is uniformly charged with charge density ρ0, then the distribution has spherical symmetry. On the other hand, if a sphere of radius R is charged so that the top half of the sphere has a uniform charge density ρ1 and the bottom half has a...
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Gauss's Law: Problem-Solving01:10

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Gauss's law helps determine electric fields even though the law is not directly about electric fields but electric flux. In situations with certain symmetries (spherical, cylindrical, or planar) in the charge distribution, the electric field can be deduced based on the knowledge of the electric flux. In these systems, we can find a Gaussian surface S over which the electric field has a constant magnitude. Furthermore, suppose the electric field is parallel (or antiparallel) to the area vector...
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In the context of a system of particles moving relative to an inertial frame of reference, the equation of motion is a crucial tool for understanding the dynamics of the system. This equation, which accounts for external forces acting on each particle, plays a fundamental role in describing the system's behavior.
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Equations of Motion: Rectangular Coordinates and Cylindrical Coordinates01:21

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Understanding the motion of particles is a fundamental aspect of classical mechanics, and the choice of the coordinate system plays a pivotal role in unraveling the complexities of their dynamics.
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Gaussian theory for spatially distributed self-propelled particles.

Hamid Seyed-Allaei1, Lutz Schimansky-Geier2, Mohammad Reza Ejtehadi1,3

  • 1Department of Physics, Sharif University of Technology, P. O. Box 11155-9161, Tehran, Iran.

Physical Review. E
|January 14, 2017
PubMed
Summary
This summary is machine-generated.

This study introduces a Gaussian approximation (GA) for modeling self-propelled particles, showing good agreement with simulations, especially at low noise intensities. The GA method offers a promising approach for understanding collective behaviors in these systems.

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Area of Science:

  • Physics
  • Statistical Mechanics
  • Complex Systems

Background:

  • Deriving continuum equations from microscopic models of interacting self-propelled particles necessitates approximations.
  • The conventional truncation method involves zeroing Fourier modes of the orientation distribution.

Purpose of the Study:

  • To propose and validate a novel Gaussian approximation (GA) method for deriving continuum equations for interacting self-propelled particles.
  • To compare the GA with simulations and assess its accuracy against existing approximation methods.

Main Methods:

  • Justifying the suitability of a wrapped Gaussian distribution for individual particle directions via microscopic simulations.
  • Numerically integrating the continuum equations derived using the GA.
  • Comparing GA results with direct particle simulations, focusing on global polarization and spatiotemporal structures.

Main Results:

  • The GA accurately models the distribution of particle directions as a wrapped Gaussian.
  • Global polarization in the GA exhibits hysteresis dependent on noise intensity, mirroring simulation results.
  • The GA shows excellent agreement with simulations for low noise intensities and qualitative agreement over a wider range.

Conclusions:

  • The Gaussian approximation (GA) provides a valid and accurate method for deriving continuum equations for self-propelled particles.
  • The GA is a strong candidate for describing spatially distributed self-propelled particles, outperforming other approximations at low noise levels.