Scientific Notation - Physics - Past Paper, Exams of Physics

This is the Past Paper of Physics which includes Wind Energy Per Unit Time, Horizontal Axis, Temperature Dependence, Unit of Energy, Freely- Oating Ball, Period of Oscillations, Intrinsic Parity, Experimental Determination etc. Key important points are: Scientific Notation, Equivalent Resistance, Internal Resistance, Power Dissipated, Potential Difference, Capacitance of System, Monochromatic Green Light, Resulting Pattern, Peak Wavelength

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2012/2013

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Physics 152 Roster No.:
December 12, 2005
Score:
Final Exam, Part A
Exam time limit: 2 hours. You may use a calculator and both sides of TWO sheets of notes, handwritten only.
Closed book; no collaborat ion. For multiple choice questions, circle the letter of the one best answer (unless more
than one answer is asked for). Ignore friction, air resistance, and gravity in all problems unless told otherwise, and
ignore relativistic effects in non-relativistic problems.
Physical constants:
ke = 8.988 × 109 N·m2/C2 e = 1.602 × 10–19 C h = 6.626 × 10–34 J·s
ε0 = 1/(4πke) = 8.854 × 10–12 C2/(N·m2) c = 2.998 × 108 m/s = 4.136 × 10–15 eV·s
µ
0 = 4π × 10–7 T·m/A σB = 5.671 × 10–8 W/(m2·K4) Wien constant (λ)=2.898×10–3 m·K
Wien constant (f)=1.034×1011 Hz/K
Useful rest masses:
mp = 1.672 623 1 × 10–27 kg mn = 1.674 928 6 × 10–27 kg me = 9.109 389 7 × 10 31 kg
= 1.007 276 470 u = 1.008 664 904 u = 0.000 548 579 903 u
Conversions:
1 T = 104 G 1 u = 1.6605 × 10–27 kg = 931.49432 MeV/c2
1. (8 pts.) Convert the fo llowing quantities into the given units. Fill in the blanks. (You do NOT need to show
your work.) Use scientific notation where appropriate (very large or very small values), and express all final values
to 2 significant figures.
a. 2.8 × 10–5 mA = nA
b. 8.2 × 10–14 J = keV
c. 197 u = kg
d. 96 µC/cm2 = C/m2
2. a. (2 pts.) What is the equivalent resistance for
the circuit shown here? (Assume the battery has zero
internal resistance.)
A. 7.67 Ω D. 18.3 Ω
B. 10.8 Ω E. 22.2 Ω
C. 15.4 Ω F. 26.0 Ω
b. (2 pts.) If Vbatt = 25.0 V, what is the power
dissipated in the 12.0-Ω resistor only?
A. 31.5 W D. 52.9 W
B. 38.7 W E. 72.5 W
C. 45.1 W F. 79.0 W
+
12.0 Ω
Vbatt
8.00 Ω
6.00 Ω
pf3
pf4
pf5
pf8

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Physics 152 Roster No.: December 12, 2005 Score:

Final Exam, Part A

Exam time limit: 2 hours. You may use a calculator and both sides of TWO sheets of notes, handwritten only****. Closed book; no collaboration. For multiple choice questions, circle the letter of the one best answer (unless more than one answer is asked for). Ignore friction, air resistance, and gravity in all problems unless told otherwise, and ignore relativistic effects in non-relativistic problems. Physical constants: k e = 8.988 × 109 N·m^2 /C^2 e = 1.602 × 10 –^19 C h = 6.626 × 10 –^34 J·s ε 0 = 1/(4π k e) = 8.854 × 10 –^12 C^2 /(N·m^2 ) c = 2.998 × 108 m/s = 4.136 × 10 –^15 eV·s μ 0 = 4π × 10 –^7 T·m/A σB = 5.671 × 10 –^8 W/(m^2 ·K^4 ) Wien constant (λ)=2.898× 10 –^3 m·K Wien constant ( f )=1.03 4 × 1011 Hz/K Useful rest masses: m p = 1.672 623 1 × 10 –^27 kg m n = 1.674 928 6 × 10 –^27 kg m e = 9.109 389 7 × 10 –^31 kg = 1.007 276 470 u = 1.008 664 904 u = 0.000 548 579 903 u Conversions: 1 T = 10^4 G 1 u = 1.6605 × 10 –^27 kg = 931.49432 MeV/ c^2

1. (8 pts.) Convert the following quantities into the given units. Fill in the blanks. (You do NOT need to show your work.) Use scientific notation where appropriate (very large or very small values), and express all final values to 2 significant figures. a. 2.8 × 10 –^5 mA = nA b. 8.2 × 10 –^14 J = keV c. 197 u = kg d. 96 μC/cm^2 = C/m^2 2. a. (2 pts.) What is the equivalent resistance for the circuit shown here? (Assume the battery has zero internal resistance.) A. 7.67 Ω D. 18.3 Ω B. 10.8 Ω E. 22.2 Ω C. 15.4 Ω F. 26.0 Ω b. (2 pts.) If V batt = 25.0 V, what is the power dissipated in the 12.0-Ω resistor only? A. 31.5 W D. 52.9 W B. 38.7 W E. 72.5 W C. 45.1 W F. 79.0 W + –

V batt

3. a. (2 pts.) If a charge of 0.220 nC resides on each of the plates of a capacitor while their potential difference is maintained at 95.0 V, what is the capacitance of the system? A. 2.3 pF D. 13 pF B. 5.0 pF E. 28 pF C. 8.9 pF F. 54 pF b. (2 pts.) How much energy is stored in the capacitor? A. 1.0 × 10 –^9 J D. 1.0 × 10 –^6 J B. 1.0 × 10 –^8 J E. 1.0 × 10 –^5 J C. 1.0 × 10 –^7 J F. 1.0 × 10 –^4 J 4. The metal ring shown at right lies in the plane of the page, and it is located in a region of strong, uniform B - field. a. (1 pt.) If the strength of the B - field quickly dropped to zero, in which direction would a current be induced in the ring? A. clockwise B. counter-clockwise C. no current is induced b. (1 pt.) Suppose, instead of the strength of the B - field changing, that the region of B - field ends at the edge of the page, and that the ring is quickly removed from the B - field by pulling it in the + x - direction. In which direction would a current be induced in the wire? A. clockwise B. counter-clockwise C. no current is induced 5. a. (2 pts.) A slide projector uses a converging lens with a focal length of 21.0 cm to form a real image of a slide on a distant screen. In order to form an image on a screen that is 12.0 m away from the lens, you should position the slide (the “object”)… A. 19.8 cm away from the lens D. 21.4 cm away from the lens B. 20.2 cm away from the lens E. 21.8 cm away from the lens C. 20.6 cm away from the lens F. 22.2 cm away from the lens b. (1 pt.) In order for the real image on the distant screen to be right-side-up, how should you orient the slide itself? A. right-side-up B. upside-down 6. (2 pts.) Monochromatic green light (λ = 532 nm) from a laser passes through two very narrow slits spaced 0.50 mm apart. The resulting pattern is observed on a white wall 10. m away. What is the distance between any two neighboring bright maxima near the middle of the pattern? A. 2.0 mm D. 1.1 cm B. 5.9 mm E. 2.4 cm C. 8.4 mm F. 5.3 cm

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x y uniform B

13. a. (2 pts.) In order to balance this nuclear reaction: 32 He + 32 He → 42 He + 2 _______ + energy two of what particle are created? A. photon D. positron B. proton E. neutron C. electron F. alpha b. (2 pts.) If the mass of all reactants is 0.029 u greater than the mass of all products in the above nuclear reaction, how much energy is produced? A. 3.4 × 10 –^21 J D. 4.3 × 10 –^12 J B. 4.3 × 10 –^19 J E. 3.4 × 10 –^9 J C. 3.4 × 10 –^15 J F. 4.3 × 10 –^2 J 14. (1 pt.) What fraction of any radioactive substance remains after exactly 8 half-lives have elapsed? A. 1/8 D. 1/ B. 1/16 E. 1/ C. 1/64 F. zero — none remains after the 2nd^ half-life 15. (2 pts.) Carbon-14 has a half-life of 5730 years. What percentage of a sample of initially pure carbon-14 will have decayed after 2005 years? A. 11.7% D. 21.5% B. 13.8% E. 26.7% C. 17.5% F. 35.0% 16. (2 pts.) All of the following are true EXCEPT which one? A. The mass of a 42 He nucleus is less than the sum of the masses of 2 protons plus 2 neutrons. B. There is only one stable isotope of each chemical element. C. All isotopes of a given element share the same atomic number. D. Nuclear fusion is the main source of energy inside all stars. 17. (2 pts.) All of the following are true EXCEPT which one? A. Electrons are leptons. D. Photons have no charge. B. Neutrinos are nucleons. E. Neutrons and protons are baryons. C. Positrons are anti-matter. Φ. Physics is phun. (This one is true !)

Physics 152 Roster No.: December 12, 2005 Score:

Final Exam, Part C

Show your work on all free-response questions. Be sure to use proper units and significant figures in your final answers. Ignore friction, air resistance, gravity, and relativistic effects in all problems, unless told otherwise.

1. Two infinite, ideal, parallel metal plates are shown edge-on at right. They are connected to an emf so that the left-hand plate is held at 0.0 V and the right- hand plate at +80.0 V. The plate separation is 5.0 cm. a. (2 pts.) On the diagram at right, draw E field lines between the plates. Include arrowheads. (Ignore the effect of “fringes” near the ends of the plates.) b. (2 pts.) Also on the diagram at right, draw and label equipotential lines at 20, 40, and 60 volts. c. (5 pts.) An electron is released at rest at a point exactly halfway between the two plates. Find the magnitude and direction of the electric force FE on the electron. After it is released from rest, the electron travels freely until it hits one of the two plates. d. (3 pts.) As the electron moves closer to one plate, which ONE OR MORE of the following remain(s) constant? Circle ALL that apply: A. magnitude of electric force C. magnitude of acceleration E. magnitude of velocity B. direction of electric force D. direction of acceleration F. direction of velocity e. (2 pts.) What is the electron’s speed the instant before it hits the plate? ( Possibly useful formulas: F = m a, v^2 = v 02 + 2 a Δ x, K = (1/2) m v^2 ) A. 6.5 × 104 m/s D. 4.5 × 105 m/s B. 7.9 × 104 m/s E. 8.1 × 105 m/s C. 1.8 × 105 m/s F. 3.8 × 106 m/s

0.0 V 80.0 V

Physics 152 Roster No.: December 12, 2005 Score:

Final Exam, Part D

3. The triangular glass prism shown here has an index of refraction n = 1.55 and internal angles of exactly 37˚, 53˚, and 90˚. A beam of monochromatic light (λ = 514.5 nm) enters the prism horizontally from air ( n = 1.00) on the left. (Ignore reflected rays throughout this problem.) a. (2 pts.) Carefully draw the path of the ray as it passes through the prism and emerges to the right. Continue the ray well into the air on the right side. (You do NOT need to measure exact angles for this sketch.) Use a straightedge! b. (5 pts.) Calculate the angle to the horizontal made by the ray emerging from the glass back into air on the right side. c. (2 pts.) A second prism of exactly the same shape but different n is used to replace the prism above. Instead of emerging to the right, the beam of light experiences total internal reflection at the right surface. What is the minimum possible index of refraction of this new prism’s glass? A. 1.61 D. 1. B. 1.66 E. 1. C. 1.71 F. 1. d. (3 pts.) As the light passes from air into glass , does each of its following properties increase , decrease , or remain unchanged? (You do NOT need to show your work.) i. speed : A. increases B. decreases C. unchanged ii. wavelength : A. increases B. decreases C. unchanged iii. frequency : A. increases B. decreases C. unchanged e. (1 pt.) How would your answer to part (b) change if the prism were surrounded by water ( n = 1.33) instead of by air ( n = 1.00)? A. increase B. decrease C. remain unchanged incoming ray (horizontal)

90˚ glass 53˚ air

4. An imaginary atom has only 4 bound energy levels for electrons, as shown at right: the ground state and the 1st, 2nd, and 3rd^ excited states. (Use the energies shown at right; do NOT attempt to calculate E n yourself. Assume that the energies shown remain constant, regardless of the number of electrons present in each state.) a. (4 pts.) If an electron is in the ground state, calculate the frequency of the lowest-energy photon that could successfully excite the electron to any other state. Show your work clearly. b. (5 pts.) Later, suppose that an electron is in the E = – 1.00 eV state. The electron can spontaneously de-excite to either of the two lower levels. Calculate the wavelengths of the photons that would be emitted by those two possible transitions. Show your work clearly. c. (3 pts.) Draw the three transitions you calculated in parts (a) & (b) on the energy-level diagram above. Include directional arrowheads. Clearly label each transition “a” for part (a), or “b” for part (b). d. (3 pts.) Is each of the three photons in parts (a) & (b) visible , ultraviolet , or infrared? (You do NOT need to show your work.) part (a): _______________ part (b): _______________ & _______________ e. (1 pt.) In order for an electron in the ground state to become ionized , what must happen? A. The electron must absorb a photon of < 4.50 eV. B. The electron must absorb a photon of > 4.50 eV. C. The electron must emit a photon of < 4.50 eV. D. The electron must emit a photon of > 4.50 eV. 0.00 eV

  • 0.50 eV
  • 4.50 eV
  • 1.00 eV
  • 2.00 eV