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Potential Energy due to Gravitation01:27

Potential Energy due to Gravitation

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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...
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Energy In A Magnetic Field01:24

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If a magnetic field is sustained, there must be a current in a closed circuit or loop, implying some energy has been spent in creating the field. If this energy is not dissipated via the circuit's resistance, it is stored in the field.
Take an ideal inductor with zero resistance. Although it's practically impossible, assume that the coil's resistance is so small that it is practically negligible. The loss of the field's energy to dissipate thermal energy (or heat) is thus...
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Energy Associated With a Charge Distribution01:21

Energy Associated With a Charge Distribution

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The work done to bring a charge through a distance r is given by the potential difference between the initial and the final position. To assemble a collection of point charges, the total work done can be expressed in terms of the product of each pair of charges divided by their separation distance, defined with respect to a suitable origin. Solving this expression gives the energy stored in a point charge distribution.
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The Principle of Superposition and the Gravitational Field01:17

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The principle of superposition applies to gravitational forces of objects that are sufficiently far apart. It states that the net gravitational force on a point object is the vector sum of the gravitational forces on it due to various objects. The principle helps calculate the force by listing the individual forces and then vectorially summing them up. However, it should be noted that the principle of superposition is not always apparent. In the presence of a second force, the first force could...
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Gravitational Potential Energy for Extended Objects01:07

Gravitational Potential Energy for Extended Objects

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Consider a system comprising several point masses. The coordinates of the center of mass for this system can be expressed as the summation of the product of each mass and its position vector divided by the total mass:
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Gravitational Potential Energy01:14

Gravitational Potential Energy

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Potential energy is not just a property of each object, but also a property of the interactions between objects in a chosen system. For each type of interaction present in a system, there is a corresponding type of potential energy. The total potential energy of the system is the sum of the potential energies of all the objects. Potential energy can be classified into two major categories: gravitational potential energy and elastic potential energy. The potential energy associated with a...
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Related Experiment Video

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Scanning SQUID Study of Vortex Manipulation by Local Contact
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Vacuum Energy Sequestering and Graviton Loops.

Nemanja Kaloper1, Antonio Padilla2

  • 1Department of Physics, University of California, Davis, California 95616, USA.

Physical Review Letters
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PubMed
Summary
This summary is machine-generated.

A new mechanism removes vacuum energy contributions from matter and virtual gravitons. This approach addresses the cosmological constant problem by sequestering vacuum energy in quantum field theory and general relativity.

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Area of Science:

  • Theoretical physics
  • Quantum field theory
  • General relativity

Background:

  • The cosmological constant problem arises from large discrepancies between theoretical predictions and observed vacuum energy.
  • Vacuum energy, arising from quantum fluctuations, significantly contributes to the stress-energy tensor and spacetime curvature.
  • Existing mechanisms primarily address matter contributions to vacuum energy.

Purpose of the Study:

  • To adapt a local vacuum energy sequestering mechanism.
  • To cancel vacuum energy loops involving virtual gravitons.
  • To extend the cancellation to vacuum energy generated by matter fields.

Main Methods:

  • Formulation of a local vacuum energy sequestering mechanism.
  • Adaptation of the mechanism to include virtual graviton contributions.
  • Integration with existing methods for matter loop contributions.

Main Results:

  • The adapted mechanism successfully cancels vacuum energy loops involving virtual gravitons.
  • All vacuum energy contributions from both matter fields and virtual gravitons are removed from the stress-energy tensor.
  • The sequestering mechanism effectively addresses the source of spacetime curvature.

Conclusions:

  • The local vacuum energy sequestering mechanism provides a comprehensive solution for vacuum energy cancellation.
  • This approach offers a potential resolution to the cosmological constant problem.
  • The findings have significant implications for quantum gravity and cosmology.