Time Dilation
- When objects travel close to the speed of light, to an observer moving relative to that object, it looks as if the object has slowed down
- This is best demonstrated by clocks
- Observer H is in a rocket moving close to the speed of light
- They will see their clock ticking at a regular pace, say, it is reading 15:00
- Observer G at rest on Earth, with remarkable eyesight, will measure the clock as ticking slower
- They will observe that time has slowed down in the spaceship from their reference frame i.e. they may see the time as 14:45 instead of 15:00
- However, the same occurs the other way around
- For observer H on the rocket, it is observer G that is moving relative to them
- Therefore, observer H will measure observer G's clock as ticking slower i.e. they see time slow down on Earth from their reference frame
A stationary observer in their own reference frame views clocks as running slower in the moving reference frame. We're back to disagreeing
Time Dilation Equation
- Consider a light clock. This consists of two mirrors facing each other with a beam of light travelling up and down between them
- An observer is at rest relative to the clock on a train platform and watches the light reflect between the mirrors
- The distance between the mirrors is L and the light travels at a speed c
- Therefore, the time interval for the light to travel from the top mirror back down to the bottom is:
- Another light clock is on a moving train, relative to the initial observer on the platform, travelling at constant velocity v
- The stationary observer on the platform sees the light clock on the train and watches the reflection of the rays between the mirrors
- It appears that the light rays travel to the right at an angle to the direction of motion
- The observer on the train platform sees the mirror at:
- Position 1, when the light leaves the bottom mirror
- Position 2, when the light returns to it
- The length of the light path as seen by the stationary observer is not L, they see the longer path, D
- The distance travelled by the light ray is now 2D, and the time observed between the reflections is now
- The apparent distance horizontally travelled by the mirror is where v is the speed of the train
- Notice that this is part of a right-angled triangle, so using Pythagoras' theorem we can see that:
- Where:
- We want to find , the time taken for the light ray to travel up and down in the reference frame of the stationary observer on the train platform, who is moving relative to the light clock on the train
- Remember, although it is the train that is moving, in the reference frame of an observer on the train it is the observer on the platform that is moving
- Remember the gamma factor is from the Lorentz transformation equations
- Therefore:
- Where:
- = the time interval measured from an observer moving relative to the time interval being measured (s)
- = the proper time interval (s)
- As > 1, this means that the
- In other words, a clock observed from a reference frame moving relative to it will be measured to tick slower than a clock that is at rest in its frame of reference
- The observer on the platform will view the train clock as moving slower
- The observer on the train will view the platform as moving slower
- You may be wondering why it's the time that slows down for the light beam, and not the light beam just speeding up to hit each mirror at the same frequency
- This is due to Einstein's second postulate
- Both Observers G and H must measure the speed of light to be c, so it doesn't slow down or speed up according to either reference frame
- It is important to note that the time has been measured at the same position
- In other words, the time interval is the position at which the light leaves the first mirror and at which it returns to the second mirror in the reference frame of the mirror
Worked example
Alex's spacecraft is on a journey to a star travelling at 0.7 c. Emma is on a space station on Earth at rest. According to Emma, the distance from the base station to the star is 14.2 ly.
Show that Alex measures the time taken for her to travel from the base station to the star to be about 14.5 years.
Answer:
Step 1: List the known quantities:
- Distance of space station according to Emma = 14.2 ly
- Speed of Alex's spacecraft, v = 0.7c
Step 2: Analyse the situation
- We are trying to find the time that Alex measures for her travel i.e. the time she would measure on her own clock in the spaceship which she is stationary relative to
- This is the proper time, Δt0
Step 3: Calculate the time taken according to Emma, Δt
- 1 ly (light year) is the distance, s, light (at speed c) travels in a year
- Therefore it takes the light 14.2 years (time) to travel the distance at speed c
- Therefore, the time taken according to Emma is:
Step 4: Substitute values into the time dilation equation
Step 5: Check whether your answer makes sense
- Since Emma (who is stationary) is viewing Alex's clock (which is moving) she would measure a longer time for Alex to reach the star than Alex will
- As Emma records 20.29 years, but Alex only records 14.5 years, this time makes sense
Exam Tip
A nice way to remember this is 'moving clocks run slower'. The caveat is what is considered 'moving' depends on the reference frame.
You will not be expected to remember this derivation, but it's helpful to know where all the factors have come from. The time dilation equation is given on your data sheet.
The notion of 'proper time' is incredibly important here, as it depends on the reference frame the time interval is being measured from.
The maths for the derivation is only using and Pythagoras' theorem.