Gravity Law: Force & Mass Relationships

In summary, the conversation discusses the relationship between mass, force, and power in the context of gravity. It explains that while the equation for gravitational force (F=G(m1*m2)/r^2) may seem to include power, it actually represents force. The conversation also delves into the concept of "why" in science, with one person arguing that it is important to understand the "why" behind natural phenomena in addition to the "how," while others explain that science mainly seeks to answer questions of "how" and "what" rather than "why."
  • #1
Hepic
118
0
As gravity law says: F=G( (m1*m2)/r^2).
That means that power between two objects with more mass is biggest.
Why? It is because they have more atoms?
Thank you.
 
Physics news on Phys.org
  • #2
Power is wok per unit time. Power is not in your equation.

You probably mean something else, but in science you have to be very clear about what you mean. Otherwise we have to guess.
 
  • #3
What you mean?? F does not mean power? Is not the power that a object attract an other??
 
  • #4
No, F does not mean power. F means force. In physics these words have very specific meanings. Force is a different quantity from power. You cannot use them interchangeably.
 
  • #5
Ok then,I am sorry.
So you can answer me?? Why object with more mass have more force than other objects with less mass?
 
  • #6
Also, there is no good answer to your original "why" question other than, "Because that's what we observe to be true." That's how gravity works in nature. Objects with more mass have more gravity.
 
  • #7
I think that the answer is,because objects with more mass make bigger curvature in the space time(about general relativity),so biggest curvature means bigger force
 
  • #8
Hepic said:
I think that the answer is,because objects with more mass make bigger curvature in the space time(about general relativity),so biggest curvature means bigger force

Then I could play your game. I can ask you "Why do objects with more mass make bigger curvature of space time?"

Now what?

Zz.
 
  • #9
That is what I try to find now. If anyone knows let me know.
(Also I am not playinh any game,I just want to udnestand the universe.)
 
  • #10
Hepic said:
That is what I try to find now. If anyone knows let me know.
(Also I am not playinh any game,I just want to udnestand the universe.)

Well then, you shouldn't be using the curvature of spacetime to "explain" the Newton's gravitational law. It isn't the explanation the way you had written.

In physics, there isn't really a "why". It is mainly a "how". We can explain things by using something more fundamental, but if you look at it closely, at the origin of it, is more of a description, rather than an "explanation" of the why. You were told by cephid of this.

Zz.
 
  • #12
Ι will disagree my dear. I think that in science we do not need only the "how",but the "why" too.
That is because with "how" we learn the way that something happens.
But with the "why" we learn why this way there is. So the "why" is stronger,because if you know the "why" you know and the "how",but not the opposite.
 
  • #13
Just to add to what ZapperZ said: we weren't originally talking about gravity as described by General Relativity (GR). We were talking about classical (Newtonian) gravity. GR is a newer theory that supersedes Newtonian gravity, in the sense that is has been shown to be more "correct" (it applies over a wider range of circumstances and explains observed phenomena better). But as far as Newton, all he said was that the gravitational force between two masses is proportional to the product of their masses and inversely proportional to the square of the distance between them. He readily *acknowledged* that he had no idea HOW two masses could exert a force on each other over a great distance, without contact. In other words, his theory only explained how gravity *worked*, not what it WAS (in terms of a causal mechanism). GR is slightly better in the sense that it explains gravitation in terms of the curvature of spacetime, but as Zz pointed out, one could then very well ask why mass curves spacetime. Science seeks to describe nature and explain its behaviour in terms of physical laws, but when you keep asking "why" questions, you eventually reach the point where your theory has no answer other than "because that's the way nature is." Asking WHY nature is the way it is, is arguably more of a philosophical question. Science just answers the how and the what. What is nature like? How does it work? NOT why does it work the way it does?
 
  • #14
Hepic said:
Ι will disagree my dear. I think that in science we do not need only the "how",but the "why" too.
That is because with "how" we learn the way that something happens.
But with the "why" we learn why this way there is. So the "why" is stronger,because if you know the "why" you know and the "how",but not the opposite.

There are at least two different kinds of "why" questions. The first (which science can answer) are actually "how" questions in disguise. When you ask, "Why does this phenomenon work the way it does?" you are actually asking what the causal mechanism for it is, in terms of more fundamental things. E.g. explaining a macroscopic observed phenomenon in terms of the behaviour of fundamental subatomic particles. But the second kind of "why" questions asks for a purpose or intent, rather than just an explanation. There is none. Once you reach your fundamental objects (like subatomic particles) you get to questions like, "why are there x number of fundamental particles, and not x+1, or x-3?" Why do these particles have the masses they do, instead of some other mass? As of yet, there is no answer for these questions, and there may never be, unless if we come up with a more fundamental theory that explains subatomic particles in terms of some other underlying phenomonon (like a bunch of tiny vibrating strings). But then you would ask WHY the strings have the properties that they do, and again there would be no answer, other than, "because that's what we observe. That's how nature seems to work."
 
  • Like
Likes 1 person
  • #15
Hepic said:
Ι will disagree my dear. I think that in science we do not need only the "how",but the "why" too.
That is because with "how" we learn the way that something happens.
But with the "why" we learn why this way there is. So the "why" is stronger,because if you know the "why" you know and the "how",but not the opposite.
This is simply wrong. Many priests will tell you exactly "why" with no clue "how". There is no order or hierarchy of answers here, they are simply different types of answers and getting one may offer little or no insight to the other.
 
  • #16
cepheid said:
There are at least two different kinds of "why" questions. The first (which science can answer) are actually "how" questions in disguise. When you ask, "Why does this phenomenon work the way it does?" you are actually asking what the causal mechanism for it is, in terms of more fundamental things. ... But the second kind of "why" questions asks for a purpose or intent, rather than just an explanation.
Wow! Excellent answer.
 
  • #17
Guys I am just a child that want to learn. Why the **** you are so bad??
First scientist were philoshopher. I like ask "why" and I will continue do that. Also If someone can not answer the "why",that means that an other power works(God),and I believe to god for this reason too.
 
  • #18
Hepic said:
Guys I am just a child that want to learn. Why the **** you are so bad??

Because of your attitude. You came here, asking a question, and then you turned around and start to try and "educate" the rest of us. Think about it. Many of us here are practicing physicists. We are not amateurs. And yet, you are lecturing us as if you are an expert in physics, and how physics is done! Go back and look at what you've written. It's as if you think we are ignorant of General Relativity and the history of physics.

If you really are a "child", then don't act as if you know what you've said.

First scientist were philoshopher. I like ask "why" and I will continue do that. Also If someone can not answer the "why",that means that an other power works(God),and I believe to god for this reason too.

Then you already have made up your mind based on what you believe in. You are not here to learn, contrary to what you have said. You are here only to strengthened your beliefs.

Zz.
 
  • #19
That is not true.Anyway that is your opinion and I respect that.
 
  • #20
Hepic said:
Guys I am just a child that want to learn.
Great! Then I hope you have learned from the excellent answers provided (especially cephids answer)
 
  • #21
Hepic said:
Guys I am just a child that want to learn. Why the **** you are so bad??
First scientist were philoshopher. I like ask "why" and I will continue do that. Also If someone can not answer the "why",that means that an other power works(God),and I believe to god for this reason too.
It is true that the first scientists were philosophers, but they aren't anymore. So I think the most important thing you should learn here is what science is. Because you can't get useful answers by asking the wrong people the wrong questions.
 

1. What is the Law of Gravity?

The Law of Gravity, also known as Newton's Law of Universal Gravitation, is a physical law that describes the force of attraction between two objects with mass. It states that the force of gravity is directly proportional to the product of the masses of the objects and inversely proportional to the square of the distance between them.

2. How does mass affect gravity?

The greater the mass of an object, the greater its gravitational force. This means that objects with larger masses will have a stronger pull on each other compared to objects with smaller masses.

3. Does distance affect gravity?

Yes, the distance between two objects does affect the force of gravity between them. According to the Law of Gravity, the force of gravity decreases as the distance between two objects increases. This means that the farther apart two objects are, the weaker their gravitational pull on each other will be.

4. What is the formula for calculating gravitational force?

The formula for calculating gravitational force is F = G * (m1 * m2)/r^2, where F is the force of gravity, G is the gravitational constant, m1 and m2 are the masses of the two objects, and r is the distance between them.

5. How is the Law of Gravity related to the motion of celestial bodies?

The Law of Gravity plays a crucial role in explaining the motion of celestial bodies, such as planets, moons, and stars. It is responsible for keeping these objects in their orbits around larger bodies, such as the sun. The gravitational force between celestial bodies also determines their speed, direction, and trajectory of motion.

Similar threads

B A question about why gravity is only attractive
    • Other Physics Topics
Replies
7
Views
2K
I De Broglie Wavelength at rest: λ = h/p = h/0 when v=0?
    • Other Physics Topics
Replies
5
Views
831
B Exploring the equivalences between mass, time and length
    • Other Physics Topics
Replies
8
Views
494
I Center of Mass of a jetpack-Earth System
    • Other Physics Topics
Replies
7
Views
2K
Find the acceleration of the system (2 blocks sliding on a table)
    • Introductory Physics Homework Help
Replies
23
Views
1K
B Gravitational force between two masses
    • Classical Physics
Replies
11
Views
1K
B 'A Brief History of Time' question on gravity
    • Other Physics Topics
Replies
4
Views
1K
I Seeking intuition on movement of COM
    • Other Physics Topics
Replies
2
Views
1K
A Damped Harmonic Oscillator - Gravity not constant.
    • Other Physics Topics
Replies
9
Views
2K
I Is there an integral version of Newton's law of gravity?
    • Classical Physics
Replies
10
Views
1K

Hot Threads

Recent Insights

Back
Top