Re: OT: The 10th Demention
 

In other words, work is being done on the rope, even though the work formula wont agree. The kinetic energy being applied by the two guys pulling the rope are ripping apart the bonds holding it together. Right?

But that was my point; if you're fighting gravity, or magnetism, then isn't energy "disappearing", since gravity and magnetism doesn't weaken( i.e. they have infinite power )?

And also, why wouldn't 'exerting forces' be exactly the same as applying kinetic energy? It's no less 'applying k. energy' just because it's not moving; that just means another force is applying a bigger amount of kinetic energy than you are, and in a different direction. Or in the case of an atmosphere, where you're not just pushing the object, but the air particles covering the direction you're pushing it in as well.

Re: OT: The 10th Demention
 

No, I'm quite pro-science. What I'm against is the cynical exploitation of public ignorance of science to further personal and political agendas.

I haven't read the book I linked to, but I did read about half of the reviews linked from that site. The author's argument is more with the attitudes of the scientific community than it is with the theory itself.

Re: OT: The 10th Demention
 

Kinetic energy is loosely defined as "extra energy an object has due to motion." You cannot apply kinetic energy to anything. You just can't. What you can do is apply force to an object, and if the force you apply to the object makes it move, then it gains kinetic energy, but you didn't give the object the kinetic energy. You gave the object force, which resulted in motion, and by virtue of said motion, it gained kinetic energy.

As for objects not moving, keep in mind that the law of conservation of energy states that you cannot create or destroy energy, only convert it between forms. So, you go and push on a big rock. You're using chemical energy derived from food to apply force to the rock. But say it's a big rock, and it won't move. The chemical energy you use to create the force is thus converted into heat in your body. Have you ever noticed you get hot & sweaty faster when you try to move something that's too heavy to move, compared to something that's just heavy enough that you can move it? I'll probably get whacked by the sciency folks for that comparisson, but my grade 11 physics teacher used it to illustrate the point, so I'm using it too. http://forum.shrapnelgames.com/image...ies/tongue.gif

I hope that made sense.

Re: OT: The 10th Demention
 

And the force you are applying to the aforementioned large rock isn't disappearing either; it's being "eaten up" by friction between the rock and the Earth, etc. You could apply a lot of force to the rock, but if you can't overcome the coefficient of friction, all you're doing is ultimately applying all the energy you exerted on the rock into the Earth, which is holding the rock still.

Re: OT: The 10th Demention
 

Yeah, but then 'what is force'? Isn't exerting force actually just transference of kinetic energy? If an object floats, completely still, in space, and another object bumps into it, isn't it true that the previously still object will start to move and the previously moving object will stop( assuming a perfect collision between like masses )?

Renegade, friction wont matter if you're lifting it straight upwards, though.

Anyway, I'll try not to drag this around in circles forever. I was just thinking that surely gravity would be both a creator and a destructor of energy.

Given a rope, a tree, a bucket of water, a gravity switch and Earth: The tree is on earth, the rope is hanging from the tree, the bucket of water is hanging from the rope and is so heavy that it'll snap the rope within one minute. The gravity switch is off.

You turn on the switch. What happens? Gravity starts pulling, exerting force as you would say, on everything. With the help of the bucket of water, gravity is actually pulling with enough energy to break the bonds in the rope.

The big question: Where's gravity getting its energy from? And even if gravity itself doesn't actually need any energy to work( i.e. spacetime ), gravity *is* exerting force on the bucket making it move. When it's moving it has kinetic energy. Since gravity made it move, that means gravity *created* energy, no?. To our knowledge, gravity doesn't weaken over time( unless given external events ). Gravity could be doing this with billions and billions of buckets all over the world, forever really. So what am I missing? How is this not an infinite energy scenario and something that breaks the law of conservation of energy?

Sorry if I'm being difficult. I understand what you guys are saying; it's along the lines of what I did learn when I actually went to school. I just can't get it all to add up.

And how is it that a photon can slow down when passing through other mass, then speed up again on its own accord? Doesn't that too go against a number of laws?

Re: OT: The 10th Demention
 

You don't have to expend energy to apply a force. The spring in your ballpoint pen (the clicky kind) is always exerting force on the clicker, but that dosen't in itself mean that the pen is mightier than the sword.

Change in energy = Work = Force (dot) Distance
(Dot product of the vectors) this is the same as simple multiplication if the force and movement are in the same direction. (Negative if they're in opposite directions, and zero if they are perpendicular)

No movement means no transfer of kinetic energy regardless of the force applied.

Re: OT: The 10th Demention
 

Something's amiss with the Work formula. If I lift a brick straight up it takes some effort. If I lower that brick straight down, it doesn't feel like I've exerted as much effert. If I push it sideways on a slippery surface, it takes almost no effort at all.

If I carry a rock to the top of a mountain, did I store energy in some sort of battery? Potential Energy? I notice that pendulums and bouncy balls and roller coasters have enough energy in their battery to bounce all the way back up to very nearly where they were. Odd that we say it was Momentum carried it back up to where it was. If I put enough energy in a brick to lift it six feet from the sand, we have no problem saying that was just enough energy to go back down. But it looks like twice as much on the way down, doesn't it?

What if I tossed a steel marble up in a vacuum sealed metal box here on earth? Would it continue to bounce up to some specific height? And doesn't that look a lot like orbiting, viewed from an angle?

Re: OT: The 10th Demention
 

I only got a C in highschool physics, so I'm no expert, but the way I remember it working is this: When you lift the brick, you're working against gravity, so you personally do most of the work, so it seems hard. When you lower the brick, gravity is doing most of the work, so to you it seems easy. But either way, the same amount of work is being exerted on the brick. I think the work formula by itself is based on moving things through the air, and you have to make additional calculations for friction when you're moving an object across a surface. Or something. I was sick when we covered friction so I'm kinda fuzzy on it.

Things stop bouncing because every time they hit the object they're bouncing against, they transfer some of their energy into what ever they're bouncing against, so your marble would probably bounce just the same in a vacuum as it does in the atmosphere, since air friction plays a very small part in slowing the marble. Otherwise, air being thin as it is, things would bounce for a very long time!

Re: OT: The 10th Demention
 

But the work formula doesn't cut it. It doesn't even take into account that the force being applied could have ripped apart atomic bindings and the likes( which means that *some work* has definitely been done, regardless of what the formula says ) even if the object wasn't actually moved.

Gravity does generate movement, and accelerates/decelerates other objects, without tiring.

But what's the difference between saying what you're saying, and saying that kinetic energy is always being transfered, it's just going elsewhere? If you're far away in space and you push something, then accoding to the work formula, work is *always* being done, because away from gravity even the smallest amount of force exerted on an object will get it to move. Agreed?

Let's not forget that kinetic energy is really *all energy*. Even the heat and sweat of your body when doing work is at base kinetic energy. For that matter, heat *is* kinetic energy; the hotter it is, the faster the particles move, the more kinetic energy they have. The work formula only takes into account work done on a visible level, it doesn't take into account work done on an atomic, or even smaller, level.

Re: OT: The 10th Demention
 

It does not take any energy to apply a force.
It does take energy to accelerate an object.

You gain energy if you fall in a gravitational field (since you are moving with the force.
You lose energy if you move against the force (upwards).

If you do the integral, you will find that the escape velocity of Earth is 11.186 km/s (The kinetic energy is scaled by mass and the force of gravity is scaled by mass too, so mass cancels out)
If you are moving outwards, you lose kinetic energy and speed, but gain potential energy for being higher up and having farther to fall.
Kinetic energy is NOT all energy.

A compressed spring isn't hotter or moving any faster than a relaxed one. And that the stretched slingshot dosen't move either... and how about all that chemical potential energy in your car's fuel tank?