Physics 72 Final Exam Set a Draft 3 (With Feeling Answer Key)
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Transcript of Physics 72 Final Exam Set a Draft 3 (With Feeling Answer Key)
University of the Philippines College of Science
PHYSICS 72
SET A
First Semester 2011-2012 Final Examination
National Institute of Physics 1st Sem AY 2011-2012 Physics 72
1 | A
INSTRUCTIONS: Choose the best answer and shade the corresponding circle on your answer sheet. To change your answer, cross-out and sign your original answer and then shade your new answer. No computational devices allowed (e.g. calculators, mobile phones). Following instructions is part of the exam.
Useful formulas:
Area Volume
Sphere (radius = r)
4 r2
4
3 r
3
Cylinder (radius =r, height = h)
2 rh
r2h
Useful constants: e -1.60 x 10-19 C me 9.1 x 10-31 kg o 8.854 x 10-12 C2/Nm2
k 8.988 x 109 Nm2/C2
θ 0 π/6 π/3 π/4 π/2
sin θ 0 1
2 3
2
2
2
1
cos θ 1 3
2
1
2 2
2
0
tan θ 0 1
3 3
1 ∞
1. Charges at equilibrium. Consider three identical heart-shaped conductors (labeled B, Y and E) with net charges +q, -4q and +3q as shown in the figure. Determine the final charges on each conductor at electrostatic equilibrium if B is put in contact with Y, while Y is placed near, but not in contact with E.
A. B: 0, Y: 0, E: 0 B. B: -4q, Y: +q, E: +3q C. B: +q, Y: -4q, E: +3q D. B: -3q, Y: -3q, E: +3q E. B: -3q/2, Y: -3q/2, E: +3q
2. Force versus field. Consider a charge +Q
placed at the origin which causes an electric field E = Eo j on a point charge –q at point S. Determine the electric field and the electric force that it will cause if the charge –q is moved at point T, which is equidistant from the origin as point S.
A. E = Eo i; F = 0 B. E = Eo i; F = qEo i
C. E = Eo i; F = -qEo i D. E = -Eo i; F = qEo i E. E = -Eo i; F = -qEo i
National Institute of Physics 1st Sem AY 2011-2012 Physics 72
2 | A
3. Electric dipole. Consider two identical, but oppositely oriented, dipoles (labeled C and K) that are placed in a region of uniform electric field directed to the right. Compare the net
force (F) and the net torque (T) acting on each dipole.
A. FC = FK; TC = TK B. FC = FK; TC = -TK C. FC > FK; TC = TK D. FC > FK; TC = -TK E. FC < FK; TC = TK
4. Flux you. Consider the Gaussian surfaces SI,
SII and SIII enclosing charges as shown at the right. If Q > 0, how are the electric fluxes through each surface related?
A. ΦI > ΦII >ΦIII B. ΦIII > ΦII >ΦI C. ΦI = ΦII >ΦIII D. ΦI = ΦII =ΦIII E. ΦI > ΦII =ΦIII
For the next two numbers, consider a uniformly charged sphere with radius RS and volume charge density ρ with a concentric cavity of radius RC.
5. nEar. What is the electric field magnitude at a
point a distance r < RC? A. Zero B. ρ(RS
3-RC3)/(3ε0r
2) C. ρ(r3-RC
3)/(3ε0r2)
D. ρ(RS3-r3)/(3ε0r
2)
E. ρRS3/(3ε0r
2)
6. therE. What is the electric field magnitude at a point a distance r > RS?
A. Zero B. ρ(RS
3-RC3)/(3ε0r
2) C. ρ(r3-RC
3)/(3ε0r2)
D. ρ(RS3-r3)/(3ε0r
2) E. ρRS
3/(3ε0r2)
7. Potential. Two charged metal spheres are connected by a wire. Sphere A is larger
than sphere B. Which of the following is true about the magnitudes of the electric
potential on each surface?
A. VA > VB D. VA = VB B. VA ≥ VB E. It depends on the charges on the spheres. C. VA ≤ VB
RC
RS
ρ
-Q
Q 2Q
Q SI
SII
SIII
National Institute of Physics 1st Sem AY 2011-2012 Physics 72
3 | A
8. Electric Field. The electric potential in a region of space is given by V(x,y,z) = (10 V/m)x3 + (20 V/m)xy + (15 V/m)z2. What is the z-component of the electric field in this region?
A. -(30 V/m)z k D. -(7.5 V/m)z j
B. -(15 V/m)z i E. (30 V/m)z k C. (15 V/m)z j
9. P.E. Two positive point charges are separated by a distance R. If the distance
between the charges is reduced to R/2, what happens to the total electric potential energy of the system?
A. It is doubled. B. It remains the same. C. It increases by a factor of 4. D. It is reduced to one-half of its original value. E. It is reduced to one-fourth of its original value.
For the next two numbers, consider the circuit diagram shown below. The potential difference Vab is 12 V.
10. Equivalent Capacitance. What is the equivalent capacitance of the circuit? A. 1 μF D. 4 μF B. 1/3 μF E. 4/3 μF C. 3 μF
11. Potential Energy. What is the total potential energy stored in the network of
capacitors? A. 24 μJ D. 216 μJ B. 72 μJ E. 288 μJ C. 96 μJ
12. Dielectric. Consider an isolated parallel-plate capacitor with surface charge
density |σ| on each plate. Initially the two plates are separated by Teflon with dielectric constant K = 2. If we replace the Teflon with Mica of K = 4, which of the following statement/s will be TRUE?
I. The electric field between the plates will double. II. The electric field energy density will double.
III. The capacitance will double.
A. I only. D. I and II. B. II only. E. II and III. C. III only.
National Institute of Physics 1st Sem AY 2011-2012 Physics 72
4 | A
13. silindrho. Consider an ohmic conducting cylinder with ends connected to a voltage source V. What will happen to the resistivity of the cylinder through its ends if its length is halved?
A. Quartered D. Doubled
B. Halved E. Quadrupled C. Remains the same
For the next two numbers, consider the network shown in the right figure. Assume that the battery is ideal and is equal to 5 V. The following are the values of each resistor: R1 = 0.5 Ω, R2 = 1 Ω, R3 = 2 Ω, R4 = 2 Ω.
14. Resistance. What is the equivalent resistance of the network?
A. 1 Ω D. 19/6 Ω B. 2 Ω E. 11/2 Ω C. 5/2 Ω
15. Current. What is the current passing through R2 if the current passing through
R1 is 2 A? A. 2 A D. 8 A B. 4 A E. 10 A C. 6 A
16. Selectah. A velocity selector is shown in the figure. The
electric field is -50 N/C i and the magnetic field is -25 T k. The charge of the particle is 1 C. What velocity will allow the charge to move out at the lower end of the selector?
A. 2.5 m/s towards + y-axis B. 2.5 m/s towards - y-axis C. 2 m/s towards + y-axis D. 2 m/s towards - y-axis E. 0.5 m/s towards the - y-axis
For the next two numbers, consider a wire loop parallel to an external uniform magnetic field as shown. The loop has radius r0 and is carrying a current I directed clockwise.
17. Force. What is the direction of the net magnetic force on the current loop?
A. Into the page B. Out of the page C. Up the page D. Down the page E. Zero
National Institute of Physics 1st Sem AY 2011-2012 Physics 72
5 | A
18. Torque. What is the direction of the net torque on the current loop? A. Into the page B. Out of the page C. Up the page
D. Down the page E. Zero
19. 4 Protons. At an instant of time, four
protons (I, II, III and IV) are located at the four corners of a square with side length s and are moving with equal speeds in different directions pointed to by the arrows as shown in the right figure. Which of the protons will produce the largest magnitude of magnetic field at point P located exactly at the center of the square?
A. I B. II C. III D. IV E. All protons have equal magnitudes of magnetic field at point P.
20. Alternating. Consider six infinitely long wires carrying equal currents and
equidistant with each other. The direction of the current for each wire is shown in the figure below. What is the direction of the net magnetic field at point P?
A. Pointing to the right B. Pointing to the left C. Pointing downward D. Pointing upward E. No direction because the net magnetic field at point P is zero.
21. Bubble. Consider two single loops of wire having
different radii (r1 = ½ r2) as shown in the figure. If the two wires carry equal currents but opposite in direction as shown by the arrows, what is the direction of the net magnetic field at point P located at the center of both wires?
A. Out of the page B. Into the page C. Downward D. Upward E. No direction because the net magnetic
field at point P is zero.
National Institute of Physics 1st Sem AY 2011-2012 Physics 72
6 | A
22. Experiment. The north pole of a permanent bar magnet is pushed along the axis of a coil as shown below. The pointer of the sensitive voltmeter connected to the coil moves to the right and gives a maximum reading of 8 units. The experiment is repeated but on this occasion, the south pole of the magnet enters
the coil at twice the previous speed. Which of the following gives the maximum deflection of the pointer of the voltmeter?
V
N Sa x is o f c o i l
A. 8 units to the right B. 8 units to the left C. 16 units to the right D. 16 units to the left E. There is no deflection.
23. Induced E. Which of the following statement/s is/are TRUE about induced electric field?
I. It is not conservative. II. Its field lines do not form closed loops.
III. It is parallel to the changing magnetic field that induces it.
A. I only B. II only D. I and III only C. III only E. I and II only
24. French TGV. Trains move through the earth’s
magnetic field at rather high speeds. The typical value of the earth’s magnetic field is 0.5 x 10-4
T. The French TGV train reach speeds of up to 100 m/s moving on tracks about 2 m. At top speed moving perpendicular to the earth’s magnetic field, what potential difference is induced across the tracks as the wheels roll?
A. 0.02 V D. 0.1 V B. 0.01 V E. 0 V C. 0.2 V
National Institute of Physics 1st Sem AY 2011-2012 Physics 72
7 | A
25. Inductance. At a given instant, the current and self-induced emf in an inductor are directed as indicated in the right figure. If the magnitude of the induced emf is 3 V and the current
decreases at a rate of 2 A/s, which of the following correctly describes the potential and inductance across points a and b?
A. potential increases from a to b and the inductance is equal to -1.5 H. B. potential drops from a to b and the inductance is equal to -1.5 H. C. potential increases from a to b and the inductance is equal to 1.5 H. D. potential drops from a to b and the inductance is equal to 1.5 H. E. potential is unchanged from a to b and the inductance is -1.5 H.
26. R-L Circuits. The figure below shows three circuits with identical batteries,
inductors, and resistors. Which of the following relationships correctly describes the time (t) for the current to reach 50% of its equilibrium value after the switches are closed?
A. tB > tA < tC B. tB > tA > tC C. tB < tA > tC D. tB < tA < tC E. tB = tA = tC
27. R-L-C Circuit. Which among the following plots correctly describes the charge as
a function of time of an R-L-C circuit with R = 4Ω; L = 6μH and C = 8μF?
28. All low shall pass. In electronics, a current passing through a circuit is recorded as signals. A signal is filtered out if the current is not allowed to pass. Which circuit element is the most suitable series filter so that high frequency signals cannot pass through?
A. Resistor D. Transformer B. Capacitor E. Antenna C. Inductor
For the next two numbers: A series RLC circuit with resistance R, capacitance C, and
inductance L is powered by an emf ℰ = ℰ 0 sin t where the frequency is below resonance.
A dielectric slab is then inserted into the capacitor.
29. RLC. How does the impedance change? A. It increases. D. It changes from time to time. B. It decreases. E. It will continuously decrease. C. It is unchanged.
National Institute of Physics 1st Sem AY 2011-2012 Physics 72
8 | A
30. Resonance. If the dielectric has a dielectric constant κ. How does the resonance frequency change after the slab is inserted?
A. It increases by a factor of κ
B. It decreases by a factor of κ
C. It increases by a factor of κ1/2. D. It decreases by a factor of κ1/2. E. It is unchanged.
For the next two numbers, consider a linearly-polarized wave with E = Eo cos[(6 m-1) z + (2c rad/s)t] i propagating in a medium with unknown refractive index.
31. SB. Determine the appropriate directions of the Poynting vector (S) and the oscillating magnetic field (B)?
A. S: +i; B: +j D. S: +k; B: -j B. S: -i; B: -j E. S: -k; B: -j C. S: +k; B: +j
32. Index. What is the value of the medium’s refractive index?
A. ½ D. 3 B. 1 E. 4 C. 2
33. Pressured. Light is normally incident on the cross sectional
area of a heart-shaped surface whose dark-painted left half is 100% absorbing while the other half is 100% reflecting. Compare the total force (F) acting upon each surface.
A. Fleft = Fright D. Fleft = 4 Fright B. Fleft = 2 Fright E. Fleft = ¼ Fright C. Fleft = ½ Fright
34. Refraction. A parallel beam of light in air makes an angle of 30 with the surface
of a glass plate. The angle between the refracted part of the beam and the surface of the glass is 60. What is the refractive index of the glass?
A. 13
D. 3
2
B. 12
E. 3
3
C. 3
35. TIR. Which of the following statement/s is/are ALWAYS TRUE about the
conditions for total internal reflection to occur? I. Only if the material in which the ray would travel is air.
II. Only if the angle of incidence is larger than the critical angle. III. Only when a ray is incident on the interface with a second material whose
index of refraction is smaller than that of the material in which the ray is traveling.
National Institute of Physics 1st Sem AY 2011-2012 Physics 72
9 | A
A. I only D. I and II only B. II only E. I and III only C. III only
36. Two Topics. A parallel beam of unpolarized light in air is incident at an angle of 60
from the normal on a plane glass surface. The reflected beam is completely linearly polarized. What is the refractive index of the glass?
A. 1 D. 3
2
B. 12
E. 3
3
C. 3
37. Plane refracting surface. A dolphin named Flipper is held captive in one of the
pools in Ocean Park. He is 8.0 m beneath the pool’s surface when he saw a small bird flying directly above him. If the bird’s actual height as measured from the pool’s surface is 6.0 m. How far from the pool’s surface does the bird appear to the dolphin? (nair = 1, npool = 4/3)
A. 4.5 m D. 10.6 m B. 6.0 m E. 14.0 m C. 8.0 m
38. Spherical Mirror. Kobe, who stands 6’6’’ (or
6½ ft), looks at himself on a convex mirror
with |R| = 2 ft. If Kobe is 3 ft away from the vertex of the mirror, what is the height of Kobe’s image formed by the convex mirror?
A. 13/4 ft. B. 13/7 ft. D. 13/10 ft. C. 13/8 ft. E. Kobe’s image is infinitely tall.
39. Thin Lens. Consider two
identical converging thin lenses 20 cm apart with focal length magnitude of 4 cm. If an object is placed 6 m to the left of the first lens, where is the final image located as measured from the first lens? (Note: figure is to scale)
A. 5 cm D. 25 cm B. 8 cm E. 28 cm C. 12 cm
National Institute of Physics 1st Sem AY 2011-2012 Physics 72
10 | A
40. Path diff. Two coherent sources S1 and S2 with
wavelength of 50 μm were made to interfere at point P as shown in the figure. If the path traversed
by S1 and S2 were 400 μm and 225 μm respectively, what can be said about the intensity of the interference pattern at point P?
A. The intensity is at maximum. B. The intensity is at minimum. C. The intensity is 1/2 of its maximum value. D. The intensity is 1/4 of its maximum value. E. The intensity is 1/8 of its maximum value.
41. Young’s double slit experiment. In a Young’s double
slit experiment, the observed interference pattern is shown in the right figure. If the distance between the slit and the screen is decreased, which of the following will most likely be the observed new interference pattern in the screen? (Note: The broken line corresponds to the center of the interference pattern.)
42. Anti-UV. If you want to coat a glass (n = 3/2) with a material with index of refraction of 6/5 so that UV light with wavelength of 300 nm will all be reflected, what should be the thickness of the coating?
A. 62.5 nm D. 150 nm B. 75 nm E. 300 nm C. 125 nm
43. Fringe width. Light of wavelength λ = 400 nm is used in a single slit diffraction
setup with three slit width settings (a1 = 0.1 μm, a2 = 10 μm, a3 =100 μm). Arrange the three in order of increasing width of the central bright fringe. A. a1 < a2 < a3 D. a3 < a2 < a1 B. a1 < a3 < a2 E. a3 < a1 < a2 C. a2 < a1 < a3
National Institute of Physics 1st Sem AY 2011-2012 Physics 72
11 | A
44. Snake eyes. In a two–slit diffraction experiment in which each slit has width a and separated by a distance d = 4a, how many bright fringes can be counted inside the diffraction central maximum?
A. 3 D. 6
B. 4 E. 7 C. 5
45. Green lantern. Green light of wavelength λ = 540 nm is used in three diffraction
experiments with varying number of slits (N1 = 2, N2 = 4, N3 = 6). Each slit is very narrow, and any two adjacent slits are separated by the same distance d. Arrange the slit numbers in order of increasing brightness of the principal maxima. A. N1 < N2 < N3 D. N3 < N2 < N1 B. N1 = N2 < N3 E. N3 = N1 < N2 C. N1 = N2 = N3
REMOVAL EXAM 27 OCTOBER 2011
10:00 a.m. - 12:00 p.m. Room: NIP R201