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Momentum And Radiation Pressure01:20

Momentum And Radiation Pressure

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An object absorbing an electromagnetic wave would experience a force in the direction of propagation of the wave. This force occurs because electromagnetic waves contain and transport momentum. The force accounts for the wave's radiation pressure exerted on the object. Maxwell's prediction was confirmed in 1903 by Nichols and Hull by precisely measuring radiation pressures with a torsion balance. The measuring instrument had mirrors suspended from a fiber kept inside a glass container.
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Radiation Pressure: Problem Solving01:09

Radiation Pressure: Problem Solving

1.0K
The radiation pressure applied by an electromagnetic wave on a perfectly absorbing surface equals the energy density of the wave. The wave's momentum also gets transferred to the surface when an electromagnetic wave is entirely absorbed by it. The rate at which momentum is transmitted to an absorbing surface perpendicular to the propagation direction equals the force on the surface.
The average value of the rate of momentum transfer divided by the absorbing area represents the average force...
1.0K
Detection of Black Holes01:10

Detection of Black Holes

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Although black holes were theoretically postulated in the 1920s, they remained outside the domain of observational astronomy until the 1970s.
Their closest cousins are neutron stars, which are composed almost entirely of neutrons packed against each other, making them extremely dense. A neutron star has the same mass as the Sun but its diameter is only a few kilometers. Therefore, the escape velocity from their surface is close to the speed of light.
Not until the 1960s, when the first neutron...
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Radiation: Applications01:17

Radiation: Applications

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The average temperature of Earth is the subject of much current discussion. Earth is in radiative contact with both the Sun and dark space; it receives almost all its energy from the radiation of the Sun and reflects some of it into outer space. Dark space is very cold, about 3 K, so Earth radiates energy into it. For instance, heat transfer occurs from soil and grasses, the rate of which can be so rapid that frost can occur on clear summer evenings, even in warm latitudes.
The average...
1.8K
Schwarzschild Radius and Event Horizon01:21

Schwarzschild Radius and Event Horizon

2.2K
No object with a finite mass can travel faster than the speed of light in a vacuum. This fact has an interesting consequence in the domain of extremely high gravitational fields.
The minimum speed required to launch a projectile from the surface of an object to which it is gravitationally bound so that it eventually escapes the object’s gravitational field is called the escape velocity. The escape velocity is independent of the mass of the object. Merging the idea of escape...
2.2K
Interaction of EM Radiation with Matter: Spectroscopy01:12

Interaction of EM Radiation with Matter: Spectroscopy

4.0K
Electromagnetic (EM) radiation can be considered an oscillating electric and magnetic field propagating through a medium that can interact with matter in its path. The electric field in the radiation can interact with electrical charges in the atoms or molecules in the matter. On the other hand, the magnetic field can interact with the magnetic field in the atomic nucleus. The study of the interaction between electromagnetic radiation and matter is termed spectroscopy. Spectroscopy is the study...
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Related Experiment Video

Updated: Apr 21, 2026

Scattering And Absorption of Light in Planetary Regoliths
11:34

Scattering And Absorption of Light in Planetary Regoliths

Published on: July 1, 2019

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Dark radiation alleviates problems with dark matter halos.

Xiaoyong Chu1, Basudeb Dasgupta1

  • 1International Centre for Theoretical Physics, Strada Costiera 11, 34014 Trieste, Italy.

Physical Review Letters
|November 1, 2014
PubMed
Summary
This summary is machine-generated.

This study introduces a new dark matter (DM) and dark radiation (DR) model. The model explains dark matter properties and resolves galactic-scale issues, offering testable predictions for future observations.

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Area of Science:

  • Cosmology
  • Particle Physics
  • Astrophysics

Background:

  • The nature of dark matter and dark radiation remains a significant mystery in modern cosmology.
  • Existing dark matter models face challenges explaining small-scale structure formation (e.g., missing satellites, cusp-core problems).

Purpose of the Study:

  • To propose a unified model explaining dark matter (DM) and dark radiation (DR) existence and abundance.
  • To address small-scale structure formation problems using DM self-interactions and delayed kinetic decoupling.
  • To provide testable predictions for DM properties and DR signatures.

Main Methods:

  • Utilizing a theoretical framework involving a scalar and a fermion charged under a global U(1) symmetry.
  • Investigating the implications of delayed DM-DR kinetic decoupling on cosmic structure formation.
  • Analyzing scalar-mediated self-interactions of DM to resolve galactic structure discrepancies.

Main Results:

  • The proposed model successfully explains the observed abundance of DM and DR.
  • Delayed kinetic decoupling alleviates the missing satellites problem.
  • Scalar-mediated DM self-interactions resolve the cusp-core and too big to fail problems.
  • The model predicts DM to be pseudo-Dirac with a mass between 100 keV and 10 GeV.

Conclusions:

  • A scalar-fermion model with a U(1) symmetry provides a compelling explanation for DM and DR.
  • This scenario offers solutions to persistent small-scale structure formation challenges.
  • The predicted dark radiation may be detectable through primordial elemental abundances and cosmic microwave background observations.