Twin Paradox - Acceleration vs Velocity

In summary, the conversation discusses the twin paradox and whether one twin will be older than the other after they both undergo the same acceleration and deceleration, with one twin staying at a high velocity for longer. The conclusion is that it depends on which twin's journey through space-time has the shorter proper length, according to SR. The concept of proper length and proper time is also explained to be different for spacelike and timelike curves. The conversation also references equations that do and do not contain acceleration, and discusses the role of acceleration in determining the age difference between the twins.
  • #1
Bussani
47
0
Sorry, I know there are tons of threads about this, but I've been though them all and couldn't answer this satisfactorily myself.

You know how it goes. You have 2 twins, A and B, who are magically the same age exactly. They start at the same point in space, each in their own spaceship. They then accelerate at the same rate until reaching the same constant velocity, somewhere close to the speed of light. After some time, A decelerates and stops. B continues at the same near-light velocity for some time longer, then decelerates in exactly the same manner as A and stops.

Both twins have undergone the same acceleration and deceleration. The only difference was that B stayed at a high velocity for longer. Is one twin older than the other?
 
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  • #2
It depends on which twin's journey through space-time has the shorter proper length. And that's all it depends on according to SR.
 
  • #3
Both twins have undergone the same acceleration and deceleration. The only difference was that B stayed at a high velocity for longer. Is one twin older than the other?
Yes, the one who decelerated earlier.
The twin paradox is calculated in the following way:
1. Choose an arbitrary inertial frame - and stick to it.
2. For each flight segment of duration dt (in that frame), calculate the proper time [itex]d\tau=dt\sqrt{1-v^2/c^2}[/itex].
This works in every inertial system, giving always the same result. Acceleration is not in the equation, and there is no paradox.
Sometimes people mistakenly assume that there is some "principle of relativity" that allows them to pick a different inertial system for each flight segment in their calculation, so as to make two segments with different velocities equivalent to a larger one with constant velocity. There isn't.
To drive home the point that the segments are not equivalent, people sometimes argue that there is acceleration in one case, and no acceleration in the other. While this is true(at least if there is no gravitation), it doesn't mean that acceleration does somehow "cause" time dilatation. It just means that there is a difference. You could see the difference as easily in a spacetime diagram, without referring to acceleration.
 
  • #4
Bussani said:
Is one twin older than the other?
Yes. My standard answer is "Check out #3 and #142 (page 9) in this thread". Post #142 is just what Mentz and Ich are talking about. Post #3 contains a spacetime diagram that you should check out.

See also kev's argument and DrGreg's spacetime diagram here about why it doesn't make sense to say that it's the acceleration that causes the age difference.

Mentz114 said:
It depends on which twin's journey through space-time has the shorter proper [strike]length[/strike] time. And that's all it depends on according to SR.
FYP
 
  • #5
Thanks guys. "Acceleration is not in the equation," is pretty much what I wanted to hear.
 
  • #6
Fredrik said:
mentz114 said:
It depends on which twin's journey through space-time has the shorter proper (length) time. And that's all it depends on according to SR.
Nitpicking :smile: proper length = c* proper time, so strictly it doesn't make any difference which we compare.
 
  • #7
Actually "proper length" (integral of [tex]\sqrt{-dt^2+dx^2}[/tex] along the curve) is only defined for spacelike curves (curves such that the thing under the square root is always positive), and "proper time" (integral of [tex]\sqrt{dt^2-dx^2}[/tex] along the curve) is only defined for timelike curves (curves such that the thing under this square root is always positive). So it does matter. These concepts are properties of two different classes of curves, and the world line of a massive "particle" (in this case a rocket containing an astronaut) is always timelike.
 
  • #8
Bussani said:
Thanks guys. "Acceleration is not in the equation," is pretty much what I wanted to hear.
It's not that simple. Most equations do not contain acceleration, but some do. Check out
http://xxx.lanl.gov/abs/physics/0004024 [Found.Phys.Lett. 13 (2000) 595]
 
  • #9
Demystifier said:
It's not that simple. Most equations do not contain acceleration, but some do. Check out
http://xxx.lanl.gov/abs/physics/0004024 [Found.Phys.Lett. 13 (2000) 595]

Thanks. I figured it wasn't that simple in real life, but I just wanted to check what would happen if we discounted acceleration as a factor.
 

FAQ: Twin Paradox - Acceleration vs Velocity

What is the Twin Paradox?

The Twin Paradox is a thought experiment in special relativity that explores the concept of time dilation. It involves two twins, one who stays on Earth and one who travels at high speeds through space. When the traveling twin returns, they will have aged less than the twin who stayed on Earth.

How does acceleration affect the Twin Paradox?

Acceleration can affect the Twin Paradox by introducing a difference in the experience of time between the traveling twin and the stationary twin. According to the theory of relativity, acceleration causes time dilation, which means the traveling twin will experience time passing slower than the stationary twin.

What is the difference between velocity and acceleration in the Twin Paradox?

Velocity refers to the rate of change of an object's position, while acceleration refers to the rate of change of an object's velocity. In the Twin Paradox, velocity refers to the constant speed of the traveling twin, while acceleration refers to any changes in that speed, which can affect the experience of time for the traveling twin.

Can the Twin Paradox be resolved?

Yes, the Twin Paradox can be resolved by taking into account the concept of frame of reference. Each twin experiences time differently because they are in different frames of reference. When the traveling twin returns to the same frame of reference as the stationary twin, they will find that they have aged less due to their time in a different frame of reference with different speeds and accelerations.

What are the implications of the Twin Paradox?

The Twin Paradox has implications for our understanding of space and time. It challenges our intuitions about the nature of time and shows that time is not absolute, but is relative to the observer's frame of reference. It also has practical applications in fields such as space travel, where time dilation must be taken into account for accurate calculations.

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