IIF-Time Dilation.pdf

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Time Dilation

DOMINGO B. BOGNALBAL, ME-Phy
Asst. Prof. IV, BU Tabaco
Time dilation
Is a fundamental concept in Einstein's theory of special
relativity, which describes how time can be experienced
differently for observers in different states of motion.
It is based on the principle that time is not absolute but
relative and depends on the relative velocity between
observers.
key principles and concepts underlying time dilation:
1. Principle of Relativity
The principle of relativity states that the laws of physics
are the same in all inertial reference frames, meaning that
no frame of reference is "privileged" over another. This
means that motion is relative, and what one observer sees
as "at rest," another may see as "in motion."

For time dilation:

If two observers are in relative motion, each will perceive
the other's clock to tick more slowly than their own.
2. The Constancy of the Speed of Light

A crucial postulate of special relativity is that the speed of
light in a vacuum is constant and the same for all
observers, regardless of their motion relative to the light
source. This invariance of the speed of light leads to
counterintuitive effects on space and time.

In order for the speed of light to remain constant for all observers:

Time must slow down (dilate) for objects moving at high
velocities relative to an observer. This effect ensures that the
distance light travels, and the time taken, remain consistent
between different observers.
3. Time Dilation and Relative Motion
Time dilation occurs because time is measured differently
for an object in motion compared to an object at rest
relative to the observer.

Proper Time (Δt0)- The proper time is the time interval
measured by a clock that is at rest relative to the observer. It
represents the shortest time interval.

Dilated Time (Δt) -The dilated time is the time interval as
measured by an observer for whom the clock is moving.
The moving clock will appear to run more slowly than a
clock at rest relative to the observer.
4. Lorentz Factor and Time Dilation
5. Symmetry of Time Dilation
Time dilation is a symmetric effect. If two observers are
moving relative to one another, each will perceive the
other's clock to be running slower than their own. This is a
direct consequence of the principle of relativity, where
neither observer is in a privileged frame of reference.

For example, if an astronaut is traveling near the speed of light
relative to Earth:

The astronaut will see clocks on Earth as ticking more slowly.
Observers on Earth will see the astronaut's clock as ticking more
slowly.
6. Experimental Evidence for Time Dilation
Time dilation has been confirmed by numerous experiments, including:

Muon Decay: Muons are unstable subatomic particles that decay after a short
lifetime. When muons are created in the upper atmosphere by cosmic rays, they
travel at nearly the speed of light toward the Earth's surface. Due to time dilation,
their lifetime (as observed from Earth) is longer, allowing more muons to reach the
ground than would be expected based on their rest lifetime.

Atomic Clocks on Airplanes: Experiments involving highly precise atomic clocks
flown on airplanes demonstrate time dilation. When these clocks are compared to
synchronized clocks left on the ground, the clocks on the airplanes are found to
have experienced less time, confirming that time slows down for moving objects.
7. Twin Paradox
A famous illustration of time dilation is the twin paradox:

Imagine one twin stays on Earth while the other twin travels into space at a
velocity near the speed of light.

When the traveling twin returns to Earth, they will have aged much less than the
twin who stayed on Earth because of the time dilation experienced at high velocity.

This scenario highlights the asymmetry that can occur when one observer
experiences acceleration and deceleration, breaking the symmetry of relative
motion.
8. Time Dilation in General Relativity
While the time dilation discussed above is a consequence of
special relativity and relative motion, a related effect occurs in
general relativity due to gravitational time dilation:

In general relativity, time slows down in stronger gravitational fields. For example,
time passes more slowly near a massive object like a planet or a black hole
compared to regions with weaker gravitational fields.

This effect is separate from the velocity-based time dilation
described by special relativity but similarly demonstrates that
time is not absolute.
9. No Effect Perpendicular to Motion

Time dilation affects all aspects of time measurement for
the moving observer, regardless of the direction of motion.
It is not dependent on the orientation of motion relative to
the observer, unlike length contraction, which only affects
measurements along the direction of motion.
SAMPLE PROBLEM SOLVING
1. A spaceship travels at 0.8c (80% of the speed of light) on
a journey to a planet 6 light-years away from Earth. How
much time passes for:

An observer on Earth?
The astronauts on the spaceship, given the effects of time
dilation?
solution
sample problem solving

A space probe is moving away from Earth at a speed of
0.95c (95% of the speed of light). An observer on Earth
measures that 10 years have passed since the probe was
launched. How much time has passed on the space probe
according to a clock on board?
SUMMARY

1. Time dilation is the phenomenon where time passes
more slowly for objects moving relative to an observer.
2. It results from the constancy of the speed of light and
the need to preserve this constancy for all observers.
3. The relationship between proper time and dilated time is
given by the equation
4. Time dilation becomes significant at speeds close to the
speed of light but is negligible at everyday speeds.
5. The Lorentz factor γ determines the degree of time
dilation.
6. Experiments such as muon decay and atomic clock tests
have confirmed the reality of time dilation.
7. The twin paradox is a famous example illustrating time
dilation and the asymmetry when one observer accelerates.
8. Time dilation is a symmetric phenomenon, meaning that
observers in relative motion both see the other's clock
running slower.
9. Gravitational time dilation, a consequence of general
relativity, shows that time also slows down in stronger
gravitational fields.
EXERCISES

An astronaut is traveling in a spaceship, and the clock on
board shows that 6 years have passed during the journey.
However, according to an observer on Earth, 10 years
have passed. What is the speed of the spaceship relative
to Earth?