Physics Exam  >  Physics Notes  >  Modern Physics  >  Special Theory of Relativity

Special Theory of Relativity | Modern Physics PDF Download

Relative Velocity

There is one inertial frame S, S’ is another inertial frame moving with respect to S in the x-direction and A is another inertial frame which is moving with respect to S' with velocity component (u'x, u'y, u'z)
So, u'x = dx'/dt'  u'y = dy'/dt'   u'z = dz'/dt'
The velocity component of A from the S frame is given by
ux = dx/dt ,   uy = dy/dt  , uz = dz/dt

Special Theory of Relativity | Modern Physics
From the inverse Lorentz Transformation,

Special Theory of Relativity | Modern Physics

Special Theory of Relativity | Modern Physics

Differentiating both sides, we get
dx = γ(dx’ + vdt') , dy = dy',  dz = dz',
Special Theory of Relativity | Modern Physics
Special Theory of Relativity | Modern Physics

Special Theory of Relativity | Modern Physics
Special Theory of Relativity | Modern Physics

Relativistic Mass

The mass of a body moving at a speed v relative to an observer is larger than its mass when it is at rest relative to the observer by the factor 

Special Theory of Relativity | Modern Physics
Thus,
Special Theory of Relativity | Modern Physics
Special Theory of Relativity | Modern Physics
where m0 is the rest mass of the body and m is the observed mass.
Relativistic Momentum  

Special Theory of Relativity | Modern Physics

Relativistic Second Law of Motion

Special Theory of Relativity | Modern Physics

Relativistic Energy 

Einstein suggested, that if m is the relativistic mass of the body then relativistic energy E is given by 

Special Theory of Relativity | Modern Physics
Rest Energy 
If the rest mass of a particle is m0 then the rest mass energy is given by moc2 
Relativistic Kinetic Energy

Special Theory of Relativity | Modern Physics
Relationship between total Energy and Momentum

Special Theory of Relativity | Modern Physics
                                                                                                           E2 = /W20C4 + p2c⇒ E = (/W20C4 + p2c2)1/2  

The Doppler Effect in Light 

The Doppler Effect in sound varies depending on whether the source, the observer, or both are moving, which appears to violate the principle of relativity. All that should count is the relative motion of the source and observer. But sound waves occur only in a material medium such as air or water, and this medium is itself a frame of reference with respect to which motions of the source and observer are measurable. Hence, there is no contradiction. In the case of light, however, no medium is involved and only the relative motion of the source and observer is meaningful. The Doppler Effect in light therefore must differ from that in sound.
We can analyze the Doppler Effect in light by considering a light source as a clock that ticks v0 times per second and emits a wave of light with each tick. We will examine the three situations as shown in the figure given below.

Transverse Doppler Effect in Light

The observer is moving perpendicular to a line between him and the light source. The proper time between ticks is t0 = 1/v0, so between one tick and the next tick, time  

Special Theory of Relativity | Modern Physics
elapses in the reference frame of the observer. 

Special Theory of Relativity | Modern Physics

The frequency he finds is accordingly,

Special Theory of Relativity | Modern Physics
The observed frequency v is always less than the source frequency v0.  

Observer and Source Moving Apart  

The observer is receding from the light source. Now the observer travels the distance vt away from the source between ticks, which mean that the light wave from a given tick takes vt/c longer to reach him than the previous one. Hence, the total time between the arrivals of successive waves is 

Special Theory of Relativity | Modern Physics
and the observed frequency is 

Special Theory of Relativity | Modern Physics

Special Theory of Relativity | Modern Physics

The observed frequency v is lower than the source frequency v0. Unlike the case of sound waves, which propagate relative to a material medium, it makes no difference whether the observer is moving away from the source or the source is moving away from the observer. 

Observer and Source Moving Towards Each Other (Approaching)

The observer is approaching the light source. The observer here travels the distance vt toward the source between ticks, so each light wave takes vt / c less time to arrive than the previous one. In this case, T = t - vt / c and the result is

Special Theory of Relativity | Modern Physics

Special Theory of Relativity | Modern Physics

The observed frequency is higher than the source frequency. Again, the same formula holds for the motion of the source toward the observer. 

Four Vectors and Relativistic Invariance  

  • Four position vector,  ds = (dx, dy, dz, icdt) 
  • Four velocity vector,
    Special Theory of Relativity | Modern Physics
    Special Theory of Relativity | Modern Physics
  • Four momentum – Four Energy vectors,
    Special Theory of Relativity | Modern Physics
  • Four Force,
    Special Theory of Relativity | Modern Physics

Four Dimensional Space-Time Continuums

The square of the interval is represented as
S212 = (x2 - x1)2 + (y2 - y1)2 + (z2 - z1)2 - c2(t2 - t1)2   
S212 = r212 - c2(t2 - t1)2
(i) Space-like Intervals: The time separation between the two events is less than the time taken by light to cover the distance between them.
Special Theory of Relativity | Modern Physics
(ii) Time-like intervals: The time separation between two events is more than the time taken by light to cover the distance between them
Special Theory of Relativity | Modern Physics
(iii) Light-like intervals: The Time separation between two events is equal to the time taken by light to cover the distance between them
Special Theory of Relativity | Modern Physics

Example 1: Determine the length and the orientation of a rod of length l0 in a frame of reference which is moving with v velocity in a direction making θ angle with rod.

Proper length of the rod in the direction of moving frame Ix = l0 cos θ, the length measured in the moving frame
Special Theory of Relativity | Modern Physics
Special Theory of Relativity | Modern Physics

Example 2: A cube of density ρo in the rest frame is moving with velocity v with respect to the observer parallel to one of its edges. What is density measured by the observer?

In rest frame m0/V0 = ρo and from moving frame ρ = mass/volume
Special Theory of Relativity | Modern Physics
and relativistic volume 

Special Theory of Relativity | Modern Physics

Special Theory of Relativity | Modern Physics

Example 3: A spaceship is moving away from the Earth with a velocity of 0.5c and fires a rocket whose velocity relative to space is 0.5c (a) Away from Earth (b) Towards the Earth. Calculate the velocity of the rocket as observed from the earth in two cases.

(a) u' = 0.5c, v = 0.5c
Special Theory of Relativity | Modern Physics
(b) u' = -0.5c, v = 0.5c
Special Theory of Relativity | Modern Physics

Example 4: Show that the rest mass of the particle of momentum p and kinetic energy T given by Special Theory of Relativity | Modern Physics

E = E+ E0 ⇒ E = T + m0c2 
E2 = p2c2 + m20c4 

Special Theory of Relativity | Modern Physics

Example 5: A π-meson at rest mass mx decays into p-meson of mass mμ and neutrino of mass mv. Find the total energy of μ -meson.

Ex = mxc2, E2μ = p2μc2 + m2μc4, E2v = p2vc2 + m2vc4 
From conservation of energy Ex = Eμ + Ev and from conservation of momentum
Pv = -Pμ = P
Using, E2μ - E2v = (m2μ - m2v)c4 and Ex = Eμ + Ev 

 Special Theory of Relativity | Modern Physics

Example 6: The rate of a clock in spaceship Suryashakti is observed from Earth to be 3/5 at the rate of the clock on Earth.
(a) What is the speed of spaceship Suryashakti relative to Earth?
(b) If the rate of the clock in spaceship Akashganga is observed from Earth to be 5/13 at the rate of the clocks on Earth. If both Aakashganga and Suryashakti are moving in the same direction relative to someone on Earth, then what is the speed of Aakashganga relative to Suryashakti?

(a) From the time dilation
Special Theory of Relativity | Modern Physics
The velocity of Suryashakti is (4/5)c
(b) Similarly,
Special Theory of Relativity | Modern Physics
Velocity of Akashganga with respect to Suryashakti is givenSpecial Theory of Relativity | Modern Physics
Hence, both are moving in same direction Special Theory of Relativity | Modern Physics
Velocity of Aakashganga with respect to Suryashakti is Special Theory of Relativity | Modern Physics

Example 7: In the laboratory frame, a particle P at rest mass m0 is moving in the positive x-direction with the speed of 5c/19. It approaches an identical particle Q moving in the negative x-direction with a speed of 2c/5.
(a) What is the speed of the particle P in the rest frame of the particle Q?
(b) What is the Energy of the particle P in the rest frame of the particle Q?

Special Theory of Relativity | Modern Physics

Special Theory of Relativity | Modern Physics

Example 8: The mass m of a moving particle is 2m0/√3, where m0 is its rest mass. Then what is the linear momentum of the particle?

Special Theory of Relativity | Modern Physics

Example 9: A distant galaxy in the constellation Hydra is receding from the earth at 6.12 x 107 m /s by how much is a green spectral line of wavelength 500 nm emitted by this galaxy shifted towards the red at spectrum.

Special Theory of Relativity | Modern Physics
since v = 0.204c, λ0 = 500
which is orange part of spectrum. The shift is λ - λ0 = 115 nm

The document Special Theory of Relativity | Modern Physics is a part of the Physics Course Modern Physics.
All you need of Physics at this link: Physics
37 videos|16 docs|19 tests
37 videos|16 docs|19 tests
Download as PDF
Explore Courses for Physics exam
Signup for Free!
Signup to see your scores go up within 7 days! Learn & Practice with 1000+ FREE Notes, Videos & Tests.
10M+ students study on EduRev
Related Searches

Free

,

shortcuts and tricks

,

Viva Questions

,

Important questions

,

Exam

,

Sample Paper

,

practice quizzes

,

Special Theory of Relativity | Modern Physics

,

past year papers

,

pdf

,

mock tests for examination

,

Special Theory of Relativity | Modern Physics

,

study material

,

Previous Year Questions with Solutions

,

Semester Notes

,

MCQs

,

video lectures

,

ppt

,

Summary

,

Objective type Questions

,

Special Theory of Relativity | Modern Physics

,

Extra Questions

;