Solution Manual for
Modern Physics for
Scientists and Engineers
5th Edition by Stephen
Thornton & Andrew Rex
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,Chapter 2 Special Theory of Relativity 1
Chapter 2
d 2x d 2 y d 2z
1. For a particle Newton’s second law says F = ma = m 2 iˆ + 2 ˆj + 2 kˆ .
dt dt dt
Take the second derivative of each of the expressions in Equation (2.1):
d 2 x d 2 x d 2 y d 2 y d 2 z d 2 z
= 2 = 2 = 2 . Substitution into the previous equation gives
dt 2 dt dt 2 dt dt 2 dt
d 2 x ˆ d 2 y ˆ d 2 z ˆ
F = ma = m 2 i + 2 j + 2 k = F .
dt dt dt
dx dy ˆ dz ˆ
2. From Equation (2.1) p = m iˆ + j + k .
dt dt dt
dx dx dy dy dz dz
In a Galilean transformation = −v = = .
dt dt dt dt dt dt
dx ˆ dy ˆ dz ˆ
Substitution into Equation (2.1) gives p = m + v i + j+ k p .
dt dt dt
dx dy ˆ dz ˆ
However, because p = m iˆ + j + k the same form is clearly retained, given
dt dt dt
dx dx
the velocity transformation = −v.
dt dt
3. Using the vector triangle shown, the speed of light coming toward the mirror is c 2 − v 2
distance 2 2
and the same on the return trip. Therefore the total time is t2 = = .
speed c2 − v2
v v
Notice that sin = , so = sin −1 .
c c
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2 Chapter 2 Special Theory of Relativity
0.350 m/s
4. As in Problem 3, sin = v1 / v2 , so = sin −1 (v1 / v2 ) = sin −1 = 16.3 and
1.25 m/s
v = v22 − v12 = (1.25 m/s)2 − (0.35 m/s)2 = 1.20 m/s .
5. When the apparatus is rotated by 90°, the situation is equivalent, except that we have
effectively interchanged 1 and 2 . Interchanging 1 and 2 in Equation (2.3) leads to
Equation (2.4).
d
6. Let n = the number of fringes shifted; then n = . Because d = c ( t − t ) , we have
c ( t − t ) v2 ( + ) . Solving for v and noting that
n= = 1 2
1 + 2 = 22 m,
c
2
n ( 0.005) ( 589 10−9 m )
v=c = ( 3.00 10 m/s ) 8
= 3.47 km/s.
1+ 2 22 m
7. Letting 1 → 1 1 − 2 (where = v / c ) the text equation (not currently numbered) for
t1 becomes
2 1− 2 2 1
t1 = 1
=
c (1 − ) c 1− 2
which is identical to t 2 when 1 = 2 so t = 0 as required.
8. Since the Lorentz transformations depend on c (and the fact that c is the same constant
for all inertial frames), different values of c would necessarily lead two observers to
different conclusions about the order or positions of two spacetime events, in violation of
postulate 1.
9. Let an observer in K send a light signal along the + x-axis with speed c. According to the
Galilean transformations, an observer in K measures the speed of the signal to be
dx dx
= − v = c − v . Therefore the speed of light cannot be constant under the Galilean
dt dt
transformations.
10. From the Principle of Relativity, we know the correct transformation must be of the form
(assuming y = y and z = z ):
x = ax + bt ; x = ax − bt .
The spherical wave front equations (2.9a) and (2.9b) give us:
ct = (ac + b)t ; ct = (ac − b)t .
Solve the second wave front equation for t and substitute into the first:
(ac + b)(ac − b)t
ct = or c2 = (ac + b)(ac − b) = a2c2 − b2 .
c
Modern Physics for
Scientists and Engineers
5th Edition by Stephen
Thornton & Andrew Rex
More than 60,000 Solution Manual and Test
Bank are available in our archive.
If you want full complete of this solution Manual, don’t hesitate to contact me:
Email:
WhatsApp: https://wa.me/message/2H3BV2L5TTSUF1
Telegram: https://t.me/solutionmanual
We can access any Solution Manual, Test Bank and E-Books.
Important: Our service is not available for these countries: Libya, Syria,
Yemen, North Korea, Venezuela, Myanmar, Somalia
,Chapter 2 Special Theory of Relativity 1
Chapter 2
d 2x d 2 y d 2z
1. For a particle Newton’s second law says F = ma = m 2 iˆ + 2 ˆj + 2 kˆ .
dt dt dt
Take the second derivative of each of the expressions in Equation (2.1):
d 2 x d 2 x d 2 y d 2 y d 2 z d 2 z
= 2 = 2 = 2 . Substitution into the previous equation gives
dt 2 dt dt 2 dt dt 2 dt
d 2 x ˆ d 2 y ˆ d 2 z ˆ
F = ma = m 2 i + 2 j + 2 k = F .
dt dt dt
dx dy ˆ dz ˆ
2. From Equation (2.1) p = m iˆ + j + k .
dt dt dt
dx dx dy dy dz dz
In a Galilean transformation = −v = = .
dt dt dt dt dt dt
dx ˆ dy ˆ dz ˆ
Substitution into Equation (2.1) gives p = m + v i + j+ k p .
dt dt dt
dx dy ˆ dz ˆ
However, because p = m iˆ + j + k the same form is clearly retained, given
dt dt dt
dx dx
the velocity transformation = −v.
dt dt
3. Using the vector triangle shown, the speed of light coming toward the mirror is c 2 − v 2
distance 2 2
and the same on the return trip. Therefore the total time is t2 = = .
speed c2 − v2
v v
Notice that sin = , so = sin −1 .
c c
, https://unihelp.xyz/solution-manual-modern-physics-thornton/
Contact me on email () to access complete document, if you can't open/access/reach our si
2 Chapter 2 Special Theory of Relativity
0.350 m/s
4. As in Problem 3, sin = v1 / v2 , so = sin −1 (v1 / v2 ) = sin −1 = 16.3 and
1.25 m/s
v = v22 − v12 = (1.25 m/s)2 − (0.35 m/s)2 = 1.20 m/s .
5. When the apparatus is rotated by 90°, the situation is equivalent, except that we have
effectively interchanged 1 and 2 . Interchanging 1 and 2 in Equation (2.3) leads to
Equation (2.4).
d
6. Let n = the number of fringes shifted; then n = . Because d = c ( t − t ) , we have
c ( t − t ) v2 ( + ) . Solving for v and noting that
n= = 1 2
1 + 2 = 22 m,
c
2
n ( 0.005) ( 589 10−9 m )
v=c = ( 3.00 10 m/s ) 8
= 3.47 km/s.
1+ 2 22 m
7. Letting 1 → 1 1 − 2 (where = v / c ) the text equation (not currently numbered) for
t1 becomes
2 1− 2 2 1
t1 = 1
=
c (1 − ) c 1− 2
which is identical to t 2 when 1 = 2 so t = 0 as required.
8. Since the Lorentz transformations depend on c (and the fact that c is the same constant
for all inertial frames), different values of c would necessarily lead two observers to
different conclusions about the order or positions of two spacetime events, in violation of
postulate 1.
9. Let an observer in K send a light signal along the + x-axis with speed c. According to the
Galilean transformations, an observer in K measures the speed of the signal to be
dx dx
= − v = c − v . Therefore the speed of light cannot be constant under the Galilean
dt dt
transformations.
10. From the Principle of Relativity, we know the correct transformation must be of the form
(assuming y = y and z = z ):
x = ax + bt ; x = ax − bt .
The spherical wave front equations (2.9a) and (2.9b) give us:
ct = (ac + b)t ; ct = (ac − b)t .
Solve the second wave front equation for t and substitute into the first:
(ac + b)(ac − b)t
ct = or c2 = (ac + b)(ac − b) = a2c2 − b2 .
c
