When a block of mass M , connected to the end of a spring of mass m s = 7.40 g and force constant k , is set into simple harmonic motion, the period of its motion is T = 2 π M + ( m s / 3 ) k A two-part experiment is conducted with the use of blocks of various masses suspended vertically from the spring as shown in Figure P15.76. (a) Static extensions of 17.0, 29.3, 35.3, 41.3, 47.1, and 49.3 cm are measured for M values of 20.0, 40.0, 50.0, 60.0, 70.0, and 80.0 g, respectively. Construct a graph of Mg versus x and perform a linear least-squares fit to the data. (b) From the slope of your graph, determine a value for k for this spring. (c) The system is now set into simple harmonic motion, and periods are measured with a stopwatch. With M = 80.0 g, the total time interval required for ten oscillations is measured to be 13.41 s. The experiment is repeated with M values of 70.0, 60.0, 50.0, 40.0, and 20.0 g, with corresponding time intervals for ten oscillations of 12.52, 11.67, 10.67, 9.62, and 7.03 s. Make a table of these masses and times. (d) Compute the experimental value for T from each of these measurements. (e) Plot a graph of T 2 versus M and (f) determine a value for k from the slope of the linear least-squares fit through the data points. (g) Compare this value of k with that obtained in part (b). (h) Obtain a value for m s from your graph and compare it with the given value of 7.40 g.
When a block of mass M , connected to the end of a spring of mass m s = 7.40 g and force constant k , is set into simple harmonic motion, the period of its motion is T = 2 π M + ( m s / 3 ) k A two-part experiment is conducted with the use of blocks of various masses suspended vertically from the spring as shown in Figure P15.76. (a) Static extensions of 17.0, 29.3, 35.3, 41.3, 47.1, and 49.3 cm are measured for M values of 20.0, 40.0, 50.0, 60.0, 70.0, and 80.0 g, respectively. Construct a graph of Mg versus x and perform a linear least-squares fit to the data. (b) From the slope of your graph, determine a value for k for this spring. (c) The system is now set into simple harmonic motion, and periods are measured with a stopwatch. With M = 80.0 g, the total time interval required for ten oscillations is measured to be 13.41 s. The experiment is repeated with M values of 70.0, 60.0, 50.0, 40.0, and 20.0 g, with corresponding time intervals for ten oscillations of 12.52, 11.67, 10.67, 9.62, and 7.03 s. Make a table of these masses and times. (d) Compute the experimental value for T from each of these measurements. (e) Plot a graph of T 2 versus M and (f) determine a value for k from the slope of the linear least-squares fit through the data points. (g) Compare this value of k with that obtained in part (b). (h) Obtain a value for m s from your graph and compare it with the given value of 7.40 g.
When a block of mass M, connected to the end of a spring of mass ms = 7.40 g and force constant k, is set into simple harmonic motion, the period of its motion is
T
=
2
π
M
+
(
m
s
/
3
)
k
A two-part experiment is conducted with the use of blocks of various masses suspended vertically from the spring as shown in Figure P15.76. (a) Static extensions of 17.0, 29.3, 35.3, 41.3, 47.1, and 49.3 cm are measured for M values of 20.0, 40.0, 50.0, 60.0, 70.0, and 80.0 g, respectively. Construct a graph of Mg versus x and perform a linear least-squares fit to the data. (b) From the slope of your graph, determine a value for k for this spring. (c) The system is now set into simple harmonic motion, and periods are measured with a stopwatch. With M = 80.0 g, the total time interval required for ten oscillations is measured to be 13.41 s. The experiment is repeated with M values of 70.0, 60.0, 50.0, 40.0, and 20.0 g, with corresponding time intervals for ten oscillations of 12.52, 11.67, 10.67, 9.62, and 7.03 s. Make a table of these masses and times. (d) Compute the experimental value for T from each of these measurements. (e) Plot a graph of T2 versus M and (f) determine a value for k from the slope of the linear least-squares fit through the data points. (g) Compare this value of k with that obtained in part (b). (h) Obtain a value for ms from your graph and compare it with the given value of 7.40 g.
Video Video
(a)
Expert Solution
To determine
To draw: The graph of
Mg versus
x and perform the linear least- square fit to the data.
Answer to Problem 15.76AP
The graph of
Mg versus
x is,
Explanation of Solution
Given info: The block of mass is
M, the mass of spring is
7.40g and the force constant is
k.
The values of mass and the static extension are given and calculate the value of the
Mg.
Static extension (x) in
m
Mass (M) in
kg
Weight
(Mg) in
N
0.17
0.02
0.196
0.293
0.04
0.392
0.353
0.05
0.49
0.413
0.06
0.588
0.471
0.07
0.686
0.493
0.08
0.784
Table (1)
Conclusion:
The table (1) indicates the values required to plot the graph of
Mg versus
x.
Figure (1)
(b)
Expert Solution
To determine
The value of
k for spring using the slope of graph.
Answer to Problem 15.76AP
The value of
k for spring using the slope of graph is
1.7386N/m.
Explanation of Solution
Given info: The block of mass is
M, the mass of spring is
7.40g and the force constant is
k.
The equation of the graph is,
y=1.7386x−0.1128
The slope intercept form of the equation of the line is,
y=mx+c
Here,
m is the slope.
c is the intercept.
Compare equation (1) and (2).
m=1.7386
Since the slope of the graph indicates the force constant of the spring.
k=1.7386N/m
Conclusion:
Therefore, the value of
k for spring using the slope of graph is
1.7386N/m.
(c)
Expert Solution
To determine
To draw: The table of given masses and the times.
Answer to Problem 15.76AP
The table of given masses and the times is,
Mass in
g
Time intervals in
s.
20
7.03
40
9.62
50
10.67
60
11.67
70
12.52
80
13.41
Explanation of Solution
Given info: The block of mass is
M, the mass of spring is
7.40g and the force constant is
k.
The values of mass and the static extension are given and calculate the value of the
Mg.
Mass in
g
Time intervals in
s.
20
7.03
40
9.62
50
10.67
60
11.67
70
12.52
80
13.41
Table (2)
Conclusion:
The table (1) indicates the values of mass and the time intervals.
(d)
Expert Solution
To determine
The experimental value for
T from each of the measurements.
Answer to Problem 15.76AP
The experimental values for
T from each of the measurements are
0.703s,
0.962s,
1.067s,
1.167s,
1.252s and
1.341s.
Explanation of Solution
Given info: The block of mass is
M, the mass of spring is
7.40g and the force constant is
k.
The expression for the time periods for each experiment is,
Tn=Tn
Here,
n is total number of experiments.
The ten experiments are conducted.
Calculate time periods for each experiment.
Total time period
(T) in
s
Time period for one experiment
(Tn=T10s)
7.03
0.703
9.62
0.962
10.67
0.1067
11.67
1.167
12.52
1.252
13.41
1.341
Table (3)
Conclusion:
Therefore, the experimental values for
T from each of the measurements are
0.703s,
0.962s,
1.067s,
1.167s,
1.252s and
1.341s.
(e)
Expert Solution
To determine
To draw: The graph of
T2 versus
M.
Answer to Problem 15.76AP
The graph of
T2 versus
M is,
Explanation of Solution
Given info: The block of mass is
M, the mass of spring is
7.40g and the force constant is
k.
Time period for one experiment
(T) in
s
T2
Mass (M) in
kg
0.703
0.494209
0.02
0.962
0.925444
0.04
0.1067
1.138489
0.05
1.167
1.361889
0.06
1.252
1.567504
0.07
1.341
1.798281
0.08
Table (4)
The table (4) indicates the values required to plot the graph of
T2 versus
M.
Figure (2)
(f)
Expert Solution
To determine
The value of
k for spring using the slope of graph.
Answer to Problem 15.76AP
The value of
k for spring using the slope of graph is
1.82N/m.
Explanation of Solution
Given info: The block of mass is
M, the mass of spring is
7.40g and the force constant is
k.
The equation of the graph is,
y=21.665x+0.0589T2=21.665M+0.0589 (3)
The given expression is,
T=2πM+ms3k
Square both sides in above expression.
T2=4π2kM+4π23kms (4)
Compare equation (3) and (4).
4π2k=21.665k=1.82N/m
Conclusion:
Therefore, the value of
k for spring using the slope of graph is
1.82N/m.
(g)
Expert Solution
To determine
The comparison in value of
k obtained between the part (b) and part (f) of the question.
Answer to Problem 15.76AP
The value of
k obtained in part (b) of the question is less than the value of
k obtained in part (f) of the question.
Explanation of Solution
Given info: The block of mass is
M, the mass of spring is
7.40g and the force constant is
k.
The value of
k obtained in part (b) of the question is,
kb=1.7386N/m
The value of
k obtained in part (f) of the question is,
kf=1.82N/m
Compare the values.
kb<kf1.7386N/m<1.82N/m
Conclusion:
Therefore, the value of
k obtained in part (b) of the question is less than the value of
k obtained in part (f) of the question.
(h)
Expert Solution
To determine
The value of
ms for spring using graph and compare it with
7.40g
Answer to Problem 15.76AP
The value of
ms for spring using graph is
8.14g and it is greater than
7.40g.
Explanation of Solution
Given info: The block of mass is
M, the mass of spring is
7.40g and the force constant is
k.
Question B3
Consider the following FLRW spacetime:
t2
ds² = -dt² +
(dx²
+ dy²+ dz²),
t2
where t is a constant.
a)
State whether this universe is spatially open, closed or flat.
[2 marks]
b) Determine the Hubble factor H(t), and represent it in a (roughly drawn) plot as a function
of time t, starting at t = 0.
[3 marks]
c) Taking galaxy A to be located at (x, y, z) = (0,0,0), determine the proper distance to galaxy
B located at (x, y, z) = (L, 0, 0). Determine the recessional velocity of galaxy B with respect
to galaxy A.
d) The Friedmann equations are
2
k
8πG
а
4πG
+
a²
(p+3p).
3
a
3
[5 marks]
Use these equations to determine the energy density p(t) and the pressure p(t) for the
FLRW spacetime specified at the top of the page.
[5 marks]
e) Given the result of question B3.d, state whether the FLRW universe in question is (i)
radiation-dominated, (ii) matter-dominated, (iii) cosmological-constant-dominated, or (iv)
none of the previous. Justify your answer.
f)
[5 marks]
A conformally…
SECTION B
Answer ONLY TWO questions in Section B
[Expect to use one single-sided A4 page for each Section-B sub question.]
Question B1
Consider the line element
where w is a constant.
ds²=-dt²+e2wt dx²,
a) Determine the components of the metric and of the inverse metric.
[2 marks]
b) Determine the Christoffel symbols. [See the Appendix of this document.]
[10 marks]
c)
Write down the geodesic equations.
[5 marks]
d) Show that e2wt it is a constant of geodesic motion.
[4 marks]
e)
Solve the geodesic equations for null geodesics.
[4 marks]
Page 2
SECTION A
Answer ALL questions in Section A
[Expect to use one single-sided A4 page for each Section-A sub question.]
Question A1
SPA6308 (2024)
Consider Minkowski spacetime in Cartesian coordinates th
=
(t, x, y, z), such that
ds² = dt² + dx² + dy² + dz².
(a) Consider the vector with components V" = (1,-1,0,0). Determine V and V. V.
(b) Consider now the coordinate system x' (u, v, y, z) such that
u =t-x,
v=t+x.
[2 marks]
Write down the line element, the metric, the Christoffel symbols and the Riemann curvature
tensor in the new coordinates. [See the Appendix of this document.]
[5 marks]
(c) Determine V", that is, write the object in question A1.a in the coordinate system x'. Verify
explicitly that V. V is invariant under the coordinate transformation.
Question A2
[5 marks]
Suppose that A, is a covector field, and consider the object
Fv=AAμ.
(a) Show explicitly that F is a tensor, that is, show that it transforms appropriately under a
coordinate transformation.
[5 marks]
(b)…
Chapter 15 Solutions
Physics for Scientists and Engineers, Technology Update, Hybrid Edition (with Enhanced WebAssign Multi-Term LOE Printed Access Card for Physics)
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