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Gravitational Force01:16

Gravitational Force

In the years before Newton, a general belief prevailed that different laws governed objects in the sky than objects on Earth. When Kepler wrote down the three laws of planetary motion, explaining in detail the geometrical properties of the planetary orbits around the Sun, there was no immediate idea to discern their connection with more fundamental laws. It was Isaac Newton who, in 1665–66, figured out the connection between planetary motion, the motion of the moon around the Earth, and the...
Momentum And Radiation Pressure01:20

Momentum And Radiation Pressure

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. Nichols...
Centrifugal Force01:06

Centrifugal Force

Pseudo forces, or fictitious forces, appear to act on an object in motion in a rotating frame of reference with respect to an inertial reference frame. These forces are not real forces but rather mathematical constructs and are introduced to simplify calculations in a non-inertial frame while using Newton's laws of motion. Common examples of pseudo forces include centrifugal, Coriolis, and Euler forces. These forces are essential in fields such as mechanics, astrophysics, and fluid dynamics,...
Comparison Between Electrical And Gravitational Forces01:24

Comparison Between Electrical And Gravitational Forces

There are four fundamental forces in nature: the gravitational force, the electromagnetic force, the strong nuclear force, and the weak nuclear force. To compare the numerical strengths of the first two, take two particles of the same kind. Since electrons are fundamental particles, they are a good example.
Since both are inverse square law forces, the distance gets canceled when the ratio of the two forces is considered. Instead, the ratio of the electrical and gravitational forces depends on...
Hydrostatic Pressure Force on a Curved Surface01:04

Hydrostatic Pressure Force on a Curved Surface

Hydrostatic pressure on curved surfaces is a fundamental concept in fluid mechanics with broad applications in the civil engineering field. When fluid is in contact with a curved surface, as in a reservoir, dam, or storage tank, it exerts pressure that varies in magnitude and direction along the curved surface. To assess the total hydrostatic force exerted by the fluid on a curved structure, engineers typically isolate the fluid volume adjacent to the surface and analyze the forces acting on...
Potential Energy due to Gravitation01:27

Potential Energy due to Gravitation

Since gravitational force is a conservative force, the amount of work done to move an object between two points in the gravitational field in which it resides is independent of the path taken. Thus, similar to the gravitational field, a gravitational potential energy function can be defined, which depends only on spatial coordinates.
Consider a mass gravitationally bound to another object. For example, the Earth is gravitationally bound to the Sun’s gravitational field. The potential energy of...

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Related Experiment Video

Updated: Jun 12, 2026

Magnetically Induced Rotating Rayleigh-Taylor Instability
06:42

Magnetically Induced Rotating Rayleigh-Taylor Instability

Published on: March 3, 2017

Gravity-induced vacuum dominance.

William C C Lima1, Daniel A T Vanzella

  • 1Instituto de Física de São Carlos, Universidade de São Paulo, Caixa Postal 369, CEP 15980-900, São Carlos, SP, Brazil. william@ursa.ifsc.usp.br

Physical Review Letters
|May 21, 2010
PubMed
Summary
This summary is machine-generated.

Gravity

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Last Updated: Jun 12, 2026

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Area of Science:

  • Quantum field theory
  • General relativity
  • Cosmology

Background:

  • Quantum fields in curved spacetimes typically exhibit small gravitational influences.
  • Renormalization techniques in curved spacetimes have historically supported this view.
  • Previous research suggested gravity's effect on quantum fields is subdominant.

Purpose of the Study:

  • To challenge the prevailing belief about gravity's subdominant role in quantum fields.
  • To demonstrate scenarios where vacuum energy density becomes dominant.
  • To explore the implications of vacuum energy dominance in astrophysics and cosmology.

Main Methods:

  • Analyzing well-behaved spacetime evolutions.
  • Investigating the behavior of free quantum fields in curved spacetimes.
  • Estimating the timescale for vacuum energy dominance.

Main Results:

  • Vacuum energy density of free quantum fields can become dominant over classical energy densities.
  • This dominance is enforced by the spacetime's own evolution.
  • A timescale for vacuum energy dominance and subsequent backreaction was estimated.

Conclusions:

  • The belief in gravity's consistently subdominant influence on quantum fields is incorrect.
  • Vacuum energy dominance has potentially significant astrophysical and cosmological implications.
  • Further research into infrared vacuum dominance is warranted.