Gravity - relationship with Electromagnetism?

In summary: But we're making progress...]In summary, gravity and electromagnetism are related in that they both involve the binding of mass and energy together. We don't know what space is or how it curves, and we don't know what particles are or how they interact. However, we do know that gravity and particles are related in that they both involve the binding of mass and energy together.
  • #1
azawah
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Gravity -- relationship with Electromagnetism?

Hi all my interest in Physics is purely a hobby and I have to say I have gaps in my knowledge but even then I have a question is it possible that the wave and particle nature of electromagnetic waves and small particles are related to gravity meaning if we don't have gravity we won't have the wave nature of these particle. Gravity curves space maybe it does more then just that maybe it puts a speed limit on the universe that nothing can go faster the the speed of light and causes electromagnetic waves and small particles have both wave and particle properties. Please educate me.
thanks
 
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  • #2


azawah said:
...I have a question is it possible that the wave and particle nature of electromagnetic waves and small particles are related to gravity meaning if we don't have gravity we won't have the wave nature of these particle. Gravity curves space maybe it does more then just that maybe it puts a speed limit on the universe that nothing can go faster the the speed of light and causes electromagnetic waves and small particles have both wave and particle properties. Please educate me.
thanks

Welcome to PhysicsForums, azawah!

The short answer is NO. We have a theory of electromagnetism which posits one thing, and a theory of gravity which posits something else. In their respective domains of applicability, they are excellent at predicting the results of specific situations.

The more complicated answer is that it is *possible* that both are part of an even more comprehensive theory. But even in that case, you would not be able to state that gravity causes wave/particle behavior any more than wave/particle behavior causes gravity.
 
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  • #3


Hi azawah,
[sorry, This post got way too long...but with luck I'll have explained, oops! wrong word...discussed some things of interest..]

Two general points:

The single most importanent thing gravity does is to draw mass and energy together...to form stars, planets and eventually,...us. If it did not we would not be here; sure they are many other essentials, but those are key.

Second, no one knows what space is, let alone curved spacetime [gravity], any more than they know what time is or mass, energy, gravity,etc,etc. For most part, we can describe the observational effects of all these but not the fundamental origin nor "what is...made of?" what we usually discuss is 'How does THAT behave...' One thing we do think we know : 'space' or, 'spacetime' if you prefer, is NOT 'empty'...

Here are brief quotes from another discussion on particles [think, 'mass' if you like] to illustrate some of the subtlies underlying gravity and particles:

One comment was made:
As a general rule the world is not made of particles, it is more correct and less confusing to say that it is made of fields. Unless I'm mistaken all or most of us at the Forum realize this?

[This post refers to 'fields' which have never been directly observed; they are aspects of mathematical models and are pervasive in phsics..because they work. Are fields real or just imaginary descriptions, like lines of lat and long we place on a map??

Referring to the above quote:

Marcus:
I don't count myself in this group. As Naty1's quote said "Particles are the objects revealed by detectors, tracks in bubble chambers, or discharges of a photomultiplier." This means that particles (not some mysterious fields) are the objects studied by real experimental physics. If "curved spacetime" does not agree with the particle concept, so bad for the "curved spacetime".

[So here we were discussing the ambiguity of gravitational spacetime curvature [gravity] with respect to particles. My quote above is actually from a Carlo Rovelli research paper we were likely discussing.]

What this gets at is that local particle states correspond to the 'real' objects observed by finite size detectors. On the other hand, global particle states can be defined only under certain limited conditions. With gravity, global distances and times [in curved spacetimes] are indeterminate as well...they are not typically subject to precise definition. And, this is really crazy, we cannot ascribe precise energies to a local gravitational field. So one smart poster here says:

Matter is that which has localized mass-energy, while spacetime does not.

Take 'matter' here as 'particle' if you like.

Want to know three ways to 'create real particles' from 'nothing'?? that is, be able to measure something locally via an appropriate detector that was 'not there' before: accelerate, accelerate spacetime [via expanding horizons as in our universe], accelerate a cosmological horizon.

[If this seems interesting try reading 'Unruh effect' in Wikipedia...you will be amazed! I know I still am.

What to make of all this?? It goes back to the 'complicated' answer of Dr Chinese above. We have a lot more to learn before we have a 'comprehensive theory'! How do all the pieces fit together??
 
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  • #4


Gravity Relationship with electromagnetism:

It should be noted one relationship which we know about and was confirmed after Einstein's general relativity: Light [which is an electromagnetic wave, or photons as quanta if you like], IS curved by gravity. This was not known nor understood for sure before an eclipse confirmed gravitational lensing [curving] of light as it passes the sun, a prediction of Einstein.

Another relationship between the two is that we know about is that light gains energy when moving to a higher [less negative] gravitational potential and loses energy the other way.
It gives up potential energy to gain kinetic energy. This is referred to a 'redshift' and blue shift respectively...but the speed of light, locally, remains 'c'...it is it's color [frequency] that changes.

We also know that during cosmological expansion, as is experienced in our universe, electromagnetic waves [the cosmic microwave background] gets redshifted...is weakened, that is cooled...so this relic radiation from 13.7B years ago has cooled from roughly 3,000 degrees K to about 2.7 degrees as it heads toward absolute zero.
 

1. What is the relationship between gravity and electromagnetism?

Gravity and electromagnetism are two of the four fundamental forces in the universe. While gravity is responsible for the attraction between objects with mass, electromagnetism is responsible for the interaction between electrically charged particles. They are both fundamental forces, but they have different mechanisms and are not directly related to each other.

2. Can gravity be explained through electromagnetism?

No, gravity cannot be explained through electromagnetism. While both forces are fundamental, they operate on different principles and have different effects. Gravity is a result of the curvature of space-time caused by mass, while electromagnetism is caused by the interaction between electrically charged particles.

3. How do gravity and electromagnetism affect each other?

Gravity and electromagnetism do not affect each other directly. However, they both play a role in the behavior of matter and energy in the universe. For example, the electromagnetic force holds atoms together, which in turn creates the gravitational force between objects with mass.

4. Is gravity stronger than electromagnetism?

Gravity is weaker than electromagnetism. In fact, it is the weakest of the four fundamental forces. The strength of the gravitational force is directly proportional to the mass of objects, while the strength of the electromagnetic force is determined by the strength of the electric charges involved.

5. How do scientists study the relationship between gravity and electromagnetism?

Scientists study the relationship between gravity and electromagnetism through various experiments and observations. These include studying the behavior of particles in particle accelerators, observing the effects of gravity on astronomical objects, and testing theories such as Einstein's theory of general relativity. Through these methods, scientists continue to deepen our understanding of the relationship between these two fundamental forces.

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