High School Why is gravity a weak force at the atomic scale?

Click For Summary
SUMMARY

The discussion centers on the comparative weakness of gravity at the atomic scale, particularly in relation to the electrostatic force. Participants highlight that while classical mechanics suggests a strong gravitational force at quantum distances (as per the formula g=-GM/R^2), the actual gravitational coupling is weak due to quantum effects. The conversation references the inadequacy of Newton's law of gravity in quantum contexts and emphasizes the need for a comprehensive quantum theory of gravity, noting that gravitational effects, although minor, persist at the subatomic level.

PREREQUISITES
  • Understanding of classical mechanics, specifically Newton's law of gravity (g=-GM/R^2).
  • Familiarity with quantum mechanics concepts, including position uncertainty and probabilistic wave functions.
  • Knowledge of fundamental forces, particularly the comparison between gravitational and electrostatic forces.
  • Awareness of quantum field theory and its implications for gravity, including massless spin-2 fields.
NEXT STEPS
  • Research quantum gravity theories and their implications for fundamental forces.
  • Explore the role of quantum field theory in understanding gravitational interactions.
  • Investigate the mathematical modeling of gravitational forces at Planck distances.
  • Examine experimental challenges in detecting gravitational effects from subatomic particles like neutrinos.
USEFUL FOR

Physicists, researchers in quantum mechanics, and anyone interested in the interplay between gravity and other fundamental forces at the atomic scale.

Arend
Messages
21
Reaction score
2
TL;DR
Following the classical mech. g=-GM/R^2, for quantum distances the gravity force would be strong. What are the quantum mechanisms that cause the effects of gravity to vanish?
Hi. Following the classical mech. g=-GM/R^2, for quantum distances the gravity force would be strong. What are the quantum mechanisms that cause the effects of gravity to vanish? The position uncertainty or the probabilistic wave function can be a justification for suppressing strong gravitational coupling?
Thank you,
Arend
 
Physics news on Phys.org
Arend said:
TL;DR Summary: Following the classical mech. g=-GM/R^2, for quantum distances the gravity force would be strong. What are the quantum mechanisms that cause the effects of gravity to vanish?

Hi. Following the classical mech. g=-GM/R^2, for quantum distances the gravity force would be strong. What are the quantum mechanisms that cause the effects of gravity to vanish? The position uncertainty or the probabilistic wave function can be a justification for suppressing strong gravitational coupling?
Thank you,
Arend
Do the mathematics. The gravitational force between two electrons, say, is very weak compared to the electrostatic force.
 
PeroK said:
Do the mathematics. The gravitational force between two electrons, say, is very weak compared to the electrostatic force.
Sorry, incomplete question. For example, applying the classical gravitational force between two electrons at Planck distance results in a strong force (~1.35 x 10^20 N). I know, that the "size" of the electron is bigger, but could be the case for other scenario. The point is, the classical expression allows infinite gravitational field for a "point". tks
 
Arend said:
Sorry, incomplete question. For example, applying the classical gravitational force between two electrons at Planck distance results in a strong force (~1.35 x 10^20 N). I know, that the "size" of the electron is bigger, but could be the case for other scenario. The point is, the classical expression allows infinite gravitational field for a "point". tks
It allows an unbounded gravitational force, but also an unbounded electrostatic force, which is always much greater.

The electrostatic force between two electrons is much greater than the gravitational force. Do the maths!
 
PeroK said:
It allows an unbounded gravitational force, but also an unbounded electrostatic force, which is always much greater.

The electrostatic force between two electrons is much greater than the gravitational force. Do the maths!
For example, a not charged particle, such as a neutrino, even a very small mass would generate a huge gravitational field closer to such "point" mass. Changing the question, would the gravitational field have a limitation due to the quantum environment?
 
Arend said:
For example, a not charged particle, such as a neutrino, even a very small mass would generate a huge gravitational field closer to such "point" mass. Changing the question, would the gravitational field have a limitation due to the quantum environment?
Newton's law of gravity isn't a fundamental law. No one knows what is the fundamental law of quantum gravity.

Nevertheless, one problem is that the gravitational force is so much weaker than the electrostatic force for elementary particles.

Someone got a Nobel Prize simply for detecting a neutrino. Doing a gravitational experiment with neutrinos would be great - but the practical difficulties are immense.
 
Understood. tks!
 
Arend said:
What are the quantum mechanisms that cause the effects of gravity to vanish?
We don't know that they do. All we know is, as @PeroK said, the effects of gravity are many, many orders of magnitude smaller than the effects of any other interaction.

Arend said:
strong gravitational coupling?
The gravitational coupling, as far as quantum field theory is concerned, is not strong. It's weak--much weaker than any of the other fundamental interactions.

Note that this is a quantum question you're asking, so the Newtonian gravitational force formula is irrelevant. We don't have a good comprehensive quantum theory of gravity, but in the 1960s and early 1970s, the quantum field theory of a massless spin-2 field was investigated, and it was found that its classical limit is General Relativity, so that QFT is at least a plausible effective theory of gravity's quantum properties. The coupling in that theory is weak, much weaker than any of the other couplings in the Standard Model.
 
Reply
  • Like
Likes Arend and PeroK
As others are telling you, the gravitational effect does not "vanish" at subatomic scale. What makes you think it does?

It certainly is overwhelmed by larger forces, but gravity is still there. In principle, the gravity of every subatomic particle affects every other particle in the universe, across vast distances.
 

Similar threads

Graduate Gravity Measured with Milligram masses
  • · Replies 3 ·
Replies
3
Views
1K
Undergrad How Do Quantum Field Theory and Quantum Loop Gravity Explain the Quantum World?
  • · Replies 1 ·
Replies
1
Views
2K
High School How does exchange of elementary particles result in a force?
  • · Replies 13 ·
Replies
13
Views
2K
Undergrad A proposed experiment to test quantum gravity
  • · Replies 12 ·
Replies
12
Views
4K
Undergrad Why does quantum mechanics believe that gravity is a field?
  • · Replies 10 ·
Replies
10
Views
2K
Undergrad Two recent tests of loop quantum gravity theory
  • · Replies 15 ·
Replies
15
Views
6K
Graduate Why is matter-free gravity not ultraviolet finite?
  • · Replies 13 ·
Replies
13
Views
4K
Undergrad How is the weak force related to a change in velocity?
  • · Replies 4 ·
Replies
4
Views
2K
What is the Weak Nuclear Force?
  • · Replies 5 ·
Replies
5
Views
3K
Undergrad Black Hole Singularity: Discussing Quantum Theories
  • · Replies 11 ·
Replies
11
Views
3K