Originally posted by yogi
A little more to add to the above - Janus - your analysis is parallel to that given by Born in his book on SR - but if you go through Born's math you see he made a critical flaw in arriving at the time dilation for the turn around - he use a time period for the acceleration that corresponded with the total outward time interval- but this period did not involve an acceleration - that took place only during the turn around - you cannot make up for the acumulated loss of time that occurs with years of near c velocity travel with a short period of turn around acceleration (even if acceleration per se altered clock rates) - the formulas derived for the acceleration time dilation are typically based upon some metaphore like having a clock in the nose of an accelerating spaceship and one in the tail - and both are subjected to the same acceleration field (they are both in the same vehicle) so there is a difference in the rate at which signals arrive from front to end and vice versa - this gives the correct formula for time dilation in a G field (somewhat surprizingly) but as I previously said - clocks subject to acceleration by some means other that a G field do not exhibit time dilation.
Again, no one is saying that acceleration effects clocks per se (or that velocity effects clocks per se either) We are saying that relative velocity effects how clocks measure each other, and acceleration felt by one clock effects how it measures others along the line of the acceleration it feels.
With the astronaut during turnaround, it is not only the strength of the acceleration he feels, but the distance and direction from him of the other clock he is measuring, that effects how he measures that other clock's rate.
Thus for an astronaut that has drifted at near c for years will be very far away from Earth, and the combined effect of this increased distance and the acceleration he feels during turnaround that will account for the speed up in time rate he sees for Earth. The longer he drifts, the further Away from Earth he is at turn around, and the greater the rate increase he sees in Earth's clock. So yes, a short turnaround
can make up the difference.
So what happens is that from Earth the following is measured:
Twin 2 accelerates up to near c, coast for a while to some distance as measured form Earth, turns around and comes back. During this perod of The Earth observer will see twin 2's clock run slow for at varying rates due to the relative velocity of Twin 2 alone. (no additional time dilation is seen due to Twin 2's acceleration)
Twin 2 measures the following:
As he feels the acceleration and the distance between him and the Earth increase, he will measure the Earth's clock run slow due to the Increased relative velocity and the aceleration he feels at a changing rate. (since he is close to the Earth during this period, the acclerations effect on his measurements will be fairly small)
The force felt to acceleration is cut off, and now he measures only time dilation due to relative motion. The distance beween him and the Earth will increase unitl he reachs turnaround point. But because of length contraction, the distance between him and Earth will be less by his measurements than by the Earth's measurements. (If he coasted at .866c it will be just about 1/2 the distance as measured from Earth.)
Thus both he and the Earth will agree as what his clock reads at turnaround. (The Earth will say that he traveled a distance of x at .866c, and took T time to do so, but because twin 2 clock underwent time dilation it will only read 1/2 T. Twin 2 will say that the distance between the Earth and him increased to a distance of 1/2 x at .866c and it took, by his clock 1/2 T to do so. )
Up until now, twin 2 wil measure less time as passing on Earth than for him.
But now, as he feels the force due to turnaround, The Earth is in the opposite direction with respect to this force than it was earlier, and much further away. He will measure the Earth time rate as moving very fast during this period.
Once again, the force will stop and he will only measure the time dilation due to relative motion (earth clock running slow.)
The force of acceleration is felt again as he brakes, and he measures the combined effect of acceleration and relative velocity, both decreasing as the distance to Earth decreases and the relative velocity lowers. This continues until twin 2 and Earth are at rest wrt each other again.
Due to the various measurments each made of each other clocks for the duration, each will agree who experienced less time and by how much. However, they won't agree as to
how that time difference was reached.
And neither is more correct than the other.