The physical laws of our universe are internal to our universe, and they'll hold (at least to within current experimental accuracy) for any observer.khotsofalang said:how does one define time? iv we viewed time from outta our universe...would einsteins theories of relativity still hold...i mean would any of the laws of physics in our universe hold if we assumed the multiverse model of the universe(s)?
No. Time and energy are quite distinct. Time is absolutely not a conserved quantity. It doesn't even make sense as a conserved quantity, any more than position could be considered a conserved quantity.khotsofalang said:can't we define time as another form of energy? well i mean it obeys the laws of conservation quite well. in fact if time was created during the big bang then it must have been made from some form of energy... the problem is whether we can convert energy into time... or vice versa, if its not possible then what are the constraints?
Huh? Newton's third law is about opposing forces: when one object applies a force on another, there is necessarily an equal force (pointing in the opposite direction) of the other object back on the first. So if I push on a wall, the wall pushes back on me with equal force.narrator said:If the progress of time is just one of four vectors, does it follow Newton's third law of motion?
Chalnoth said:Huh? Newton's third law is about opposing forces: when one object applies a force on another, there is necessarily an equal force (pointing in the opposite direction) of the other object back on the first. So if I push on a wall, the wall pushes back on me with equal force.
I don't see how this concept makes any sense whatsoever in relation to time.
Chalnoth said:Also, a small nitpick: time isn't "one of four vectors". Rather, it is a component of a four-dimensional vector. The four numbers (three space, one time) together make up a single vector.
I think you're confusing terms here. Newton's third law applies to forces and only to forces. It only applies to the sorts of things you would place on the left hand side of the equation F=ma. The use of another word for the same thing (action) doesn't change this at all. It's still a statement about the relationship between forces.narrator said:Yes, or per the cliche quote, for every action there's an equal and opposite reaction.
I guess the question is, was/is time an action? Did/does it propel forward, and thus something else propels backwards? When time was first set in motion, did something go (crudely put) in the opposite direction? And when something distorts spacetime, does it also cause an equal and opposite spacetime reaction?
Chalnoth said:I think you're confusing terms here. Newton's third law applies to forces and only to forces. It only applies to the sorts of things you would place on the left hand side of the equation F=ma. The use of another word for the same thing (action) doesn't change this at all. It's still a statement about the relationship between forces.
A perhaps related question that expresses yours (hopefully) more accurately would be to ask whether or not there exists some higher-order law that would result in similar behavior with respect to time (e.g. when you create a universe that has a future forward in time, you also create a reflection with its future going backwards in time). Well, as far as I know, that is just not known at this time, and there isn't any good reason to believe it might be the case either.
Well, sort of, I guess? Acceleration is the rate of change of velocity over time. So time is involved, but there is no way to simply equate them.narrator said:Thanks Chalnoth.. your second para is just what I was getting at..
And re the first para, I guess in terms of F=ma I considered time to be notionally connected to the 'acceleration' part.
Well, there really is no doubt that General Relativity breaks down at some point. It has to, because it makes some nonsensical predictions (singularities).Ashwin_Kumar said:i'm not too sure about einstein's theories holding, because i don't believe in the curvature of spacetime being solely the cause of gravitation, but time definitely exists. A multiverse must exist, and time has to run in that. Our universe expands into this time and space in this multiverse.
I guess in terms of F=ma I considered time to be notionally connected to the 'acceleration' part.
khotsofalang said:how does one define time? iv we viewed time from outta our universe...would einsteins theories of relativity still hold...i mean would any of the laws of physics in our universe hold if we assumed the multiverse model of the universe(s)?
The theory of relativity is a scientific theory developed by Albert Einstein in the early 20th century that explains the relationship between space and time. It states that the laws of physics are the same for all observers in uniform motion and that the speed of light is constant in all reference frames.
The multiverse theory is the idea that there are multiple universes parallel to our own. In this theory, each universe may have its own unique time frame, making the concept of time relative to each universe. This means that time in one universe may not be the same as time in another universe.
The Outta Universe theory is a concept that suggests there may be an existence outside of our known universe. This theory is based on the idea that our universe is just one of many and that there may be a higher dimension or realm beyond our own.
These time theories challenge our traditional understanding of time as a linear concept and instead propose that time may be relative and exist differently in other universes or dimensions. They also suggest that time may not be absolute and may be influenced by factors such as gravity and the speed of light.
While these theories are still being explored and studied, there is some scientific evidence that supports them. For example, the theory of relativity has been tested and confirmed through various experiments. However, as these theories involve concepts that are difficult to observe or measure, further research and evidence are needed to fully understand them.