Can a magnet have more push force than it weighs?

AI Thread Summary
A magnet can exert a push force greater than its own weight, as demonstrated by a 2kg magnet potentially exerting a push force equivalent to 3kg. When levitating magnets, additional support like rails is necessary to prevent sliding or flipping. The force between magnets is equal in magnitude, but it's important to distinguish between mass (in kg) and force (in Newtons). Using gravity, the force exerted by a magnet can be calculated, showing that a magnet can indeed push against another with a force exceeding its weight. Overall, the interaction of magnets can lead to scenarios where the forces involved surpass the weight of the magnets themselves.
JustSomeone
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Simple question. Can a magnet have more push force than the magnet itself weighs.
Example: A magnet weighing 2kg having a push force equal to 3kg.
 
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Hello Som1, :welcome:

Simple answer: yes !
 
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JustSomeone said:
Simple question. Can a magnet have more push force than the magnet itself weighs.
Example: A magnet weighing 2kg having a push force equal to 3kg.
https://s-media-cache-ak0.pinimg.com/564x/e2/3a/70/e23a7074e0e19066c1ae700be2593b74.jpg
e23a7074e0e19066c1ae700be2593b74.jpg
 
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If you try to levitate a magnet on top of another magnet without some sort of rails, active feedback, or superconductors, then the top magnet will simply slide away or flip around and fall. If you do have rails, then it's easy to levitate a magnet on top of another.
 
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Noob Question 2.png

https://www.physicsforums.com/attachments/146121
 
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I don't understand the diagram. The magnets should be pushing on each other, but you have arrows pointing to the right. What is it pushing on?
 
Sorry about that, the glow is meant to represent the push force. I updated the arrow direction.
 
What does Newton's third law say?
 
Khashishi said:
I don't understand the diagram. The magnets should be pushing on each other, but you have arrows pointing to the right. What is it pushing on?

why are you limiting it to push force ... the pull is just the same
 
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JustSomeone said:
View attachment 146200
https://www.physicsforums.com/attachments/146121

The force from each magnet on the other will be equal in magnitude. Also note that a kilogram is not a unit of force, but a unit of mass (unlike the pound which is a unit of force). If your mass is in kg then your force should be in Newtons (which itself is in units of kg*m/s2).
If you take your magnets and place one on top of the other along with a rail to keep the top from sliding off of the bottom one, the magnitude of the force on each magnet will be equal to the mass of the top magnet times the gravitational acceleration. So in your example:

2kg * 9.81 m/s2 = 19.62 kg*m/s2, or 19.62 Newtons.

This will be exactly enough to balance out the force of gravity on the top magnet and it will remain stationary. If you then add a small amount of mass or press down lightly on the top magnet the two will move closer to each other and until the forces once again balance out. At this point the force on each magnet is more than the top magnet's weight.
 
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