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Collisions in Multiple Dimensions: Introduction01:05

Collisions in Multiple Dimensions: Introduction

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It is far more common for collisions to occur in two dimensions; that is, the initial velocity vectors are neither parallel nor antiparallel to each other. Let's see what complications arise from this. The first idea is that momentum is a vector. Like all vectors, it can be expressed as a sum of perpendicular components (usually, though not always, an x-component and a y-component, and a z-component if necessary). Thus, when the statement of conservation of momentum is written for a...
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Collisions in Multiple Dimensions: Problem Solving01:06

Collisions in Multiple Dimensions: Problem Solving

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In multiple dimensions, the conservation of momentum applies in each direction independently. Hence, to solve collisions in multiple dimensions, we should write down the momentum conservation in each direction separately. To help understand collisions in multiple dimensions, consider an example.
A small car of mass 1,200 kg traveling east at 60 km/h collides at an intersection with a truck of mass 3,000 kg traveling due north at 40 km/h. The two vehicles are locked together. What is the...
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Equations of Motion: Rectangular Coordinates and Cylindrical Coordinates01:21

Equations of Motion: Rectangular Coordinates and Cylindrical Coordinates

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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.
When a particle moves relative to an inertial frame, the equations of motion can be expressed using rectangular components. If the motion is confined to the x-y plane, the equations having the x and y coordinates only can be used to simplify the mathematical representation.
However, when particles...
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Elastic Collisions: Case Study01:15

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Elastic collision of a system demands conservation of both momentum and kinetic energy. To solve problems involving one-dimensional elastic collisions between two objects, the equations for conservation of momentum and conservation of internal kinetic energy can be used. For the two objects, the sum of momentum before the collision equals the total momentum after the collision. An elastic collision conserves internal kinetic energy, and so the sum of kinetic energies before the collision equals...
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First Law: Particles in Two-dimensional Equilibrium01:18

First Law: Particles in Two-dimensional Equilibrium

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Recall that a particle in equilibrium is one for which the external forces are balanced. Static equilibrium involves objects at rest, and dynamic equilibrium involves objects in motion without acceleration; but it is important to remember that these conditions are relative. For instance, an object may be at rest when viewed from one frame of reference, but that same object would appear to be in motion when viewed by someone moving at a constant velocity.
Newton's first law tells us about...
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Angular Momentum: Single Particle01:10

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Angular momentum is directed perpendicular to the plane of the rotation, and its magnitude depends on the choice of the origin. The perpendicular vector joining the linear momentum vector of an object to the origin is called the “lever arm.” If the lever arm and linear momentum are collinear, then the magnitude of the angular momentum is zero. Therefore, in this case, the object rotates about the origin such that it lies on the rim of the circumference defined by the lever arm...
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Related Experiment Video

Updated: Jun 15, 2025

Laboratory Drop Towers for the Experimental Simulation of Dust-aggregate Collisions in the Early Solar System
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Laboratory Drop Towers for the Experimental Simulation of Dust-aggregate Collisions in the Early Solar System

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Entangled nematic disclinations using multi-particle collision dynamics.

Louise C Head1,2, Yair A G Fosado1, Davide Marenduzzo1

  • 1School of Physics and Astronomy, The University of Edinburgh, Peter Guthrie Tait Road, Edinburgh, EH9 3FD, UK. t.shendruk@ed.ac.uk.

Soft Matter
|August 28, 2024
PubMed
Summary
This summary is machine-generated.

We developed a new simulation method to study how colloids entangle in liquid crystals. This approach reveals complex defect behaviors and enables the design of novel topological materials.

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Area of Science:

  • Soft Matter Physics
  • Materials Science
  • Computational Physics

Background:

  • Colloids in nematic liquid crystals form topological composites with defect-mediated interactions.
  • Existing numerical methods struggle with dynamic and complex scenarios involving these materials.
  • Understanding colloidal entanglement kinetics is crucial for realizing the potential of these composites.

Purpose of the Study:

  • To develop and employ a mesoscale simulation approach for modeling mobile colloids in liquid crystals.
  • To investigate the kinetics of colloidal entanglement and the behavior of associated topological defects.
  • To explore far-from-equilibrium configurations and topological transitions of disclination loops.

Main Methods:

  • Simulated colloids as mobile surfaces within a fluctuating nematohydrodynamic medium.
  • Utilized a mesoscale approach to capture both far-field interactions and defect dynamics.
  • Resolved topological properties of disclination loops during relaxation processes.

Main Results:

  • Successfully reproduced far-field interactions between colloids.
  • Identified metastable states and topological transitions of disclination loops.
  • Revealed novel far-from-equilibrium disclination states, including those with localized positive winding profiles, driven by hydrodynamic fluctuations.

Conclusions:

  • The developed mesoscale simulation approach accurately models colloidal entanglement in liquid crystals.
  • This method provides insights into the dynamics of topological defects, including previously unexplored states.
  • The approach is adaptable for studying designed and out-of-equilibrium systems involving colloids and defects.