## 20160729

### Astronomy in-class activity: planet-hunting

Astronomy 210 In-class activity 6 v.16.08.31, fall semester 2016
Cuesta College, San Luis Obispo, CA

Students find their assigned groups of three to four students, and work cooperatively on an in-class activity worksheet to determine where in the sky each naked-eye planet will be observed on a given date (here, September 1, 2016).

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## 20160705

### Physics final exam question: increasing negative electric potential energy value

Physics 205B Final Exam, spring semester 2016
Cuesta College, San Luis Obispo, CA

Two point charges lie along the  x-axis. A –2.0 nC charge is fixed at the origin, and a +1.0 nC charge is at x = +1.0 m. In order to make the electric potential energy of this system a smaller negative number, determine whether the +1.0 nC charge should be moved to the left, or to the right, or if this is not possible. Explain your reasoning by using the properties of charges, electric forces, electric potential, and electric potential energy.

• p:
Correct. Understands that the electric potential energy of these charges of opposite sign is negative, and to make it a smaller negative number, the distance between them must increase, such that the +1.0 nC charge must be moved to the right. May also argue from doing work on the +1.0 nC to increase the electric potential energy of this system.
• r:
As (p), but argument indirectly, weakly, or only by definition supports the statement to be proven, or has minor inconsistencies or loopholes.
• t:
Nearly correct, but argument has conceptual errors, or is incomplete.
• v:
Limited relevant discussion of supporting evidence of at least some merit, but in an inconsistent or unclear manner. Some garbled attempt at applying properties of charges, electric forces, electric potential, and electric potential energy.
• x:
Implementation/application of ideas, but credit given for effort rather than merit. No clear attempt at applying properties of charges, electric forces, electric potential, and electric potential energy.
• y:
Irrelevant discussion/effectively blank.
• z:
Blank.
Sections 30882, 30883
Exam code: finalm4u1
p: 28 students
r: 3 students
t: 2 students
v: 1 student
x: 3 students
y: 2 students
z: 0 students

A sample "p" response (from student 3214):

Another sample "p" response (from student 3158):

Yet another sample "p" response (from student 5396):

### Physics final exam question: invalid Feynman diagram

Physics 205B Final Exam, spring semester 2016
Cuesta College, San Luis Obispo, CA

Discuss why this Feynman diagram is invalid. Explain your reasoning using the properties of Feynman diagrams, particles and antiparticles, and interactions.

• p:
Correct. Recognizes that the diagram is invalid by discussing:
1. this was originally an electron capture process that has been rotated, but the proton path is reversed; or
2. the "one line in, one line out" vertex rule is violated; or
3. charge conservation is violated (net negative charge of electron and antineutrino in does not equal the net positive charge of neutron and proton out).
• r:
As (p), but argument indirectly, weakly, or only by definition supports the statement to be proven, or has minor inconsistencies or loopholes.
• t:
Nearly correct, but argument has conceptual errors, or is incomplete.
• v:
Limited relevant discussion of supporting evidence of at least some merit, but in an inconsistent or unclear manner. Some garbled attempt at applying properties of Feynman diagrams.
• x:
Implementation/application of ideas, but credit given for effort rather than merit.
• y:
Irrelevant discussion/effectively blank.
• z:
Blank.
Sections 30882, 30883
Exam code: finalm4u1
p: 26 students
r: 7 students
t: 2 students
v: 3 students
x: 1 student
y: 0 students
z: 0 students

A sample "p" response (from student 2691):

Another sample "p" response (from student 3158):

### Physics final exam question: solidification age comparison

Physics 205B Final Exam, spring semester 2016
Cuesta College, San Luis Obispo, CA

Two samples currently have certain amounts of a radioactive isotope, embedded gaseous daughter element, and inert material (which is not involved in the decay process). Determine which sample has an older solidification age (as determined by radioactive dating), or if there is a tie. Explain your reasoning using properties of radioactive decay.

• p:
Correct. The samples have the same solidification age, as they have the same ratio of radioactive isotopes today compared to when they first started, as the inert material does not factor into the decay process.
• r:
As (p), but argument indirectly, weakly, or only by definition supports the statement to be proven, or has minor inconsistencies or loopholes.
• t:
Nearly correct, but argument has conceptual errors, or is incomplete.
• v:
Limited relevant discussion of supporting evidence of at least some merit, but in an inconsistent or unclear manner. Some garbled attempt at applying properties of radioactive decay.
• x:
Implementation/application of ideas, but credit given for effort rather than merit. Approach other than that of applying properties of radioactive decay.
• y:
Irrelevant discussion/effectively blank.
• z:
Blank.
Sections 30882, 30883
Exam code: finalm4u1
p: 36 students
r: 0 students
t: 0 students
v: 2 students
x: 1 student
y: 0 students
z: 0 students

A sample "p" response (from student 9950):

### Physics final exam problem: smartphone projector

Physics 205B Final Exam, spring semester 2016
Cuesta College, San Luis Obispo, CA

An inexpensive magnifying glass mounted in a shoebox is used with a smartphone as a light source to project images on a wall in a darkened room.[*] Shown at right is a view of the enlarged, upright image of the smartphone inside the projector when looking through the magnifying glass. Discuss what adjustments must be made (if any) to the location and/or orientation of the smartphone in order to properly display an enlarged, upright image on a wall. Show your work and explain your reasoning by using the properties of lenses, thin lens equations and/or ray tracings.

[*] content.photojojo.com/diy/turn-your-phone-into-a-photo-projector-for-1.

• p:
Correct. Since the smartphone's upright, enlarged virtual image cannot be projected onto a wall, and in order to produce an "upright" image projected on a wall, the smartphone must instead be:
1. turned upside-down; and
2. pushed further away from the magnifying glass (such that it is placed just outside the focal point).
• r:
Nearly correct, but includes minor math errors. Neglects to mention that the phone must be turned upside-down.
• t:
Nearly correct, but approach has conceptual errors, and/or major/compounded math errors.
• v:
Implementation of right ideas, but in an inconsistent, incomplete, or unorganized manner. May claim that the smartphone already projects an image onto a wall, or that only the magnifying glass to wall distance needs to be changed.
• x:
Implementation of ideas, but credit given for effort rather than merit. No clear attempt at applying properties of lenses, thin lens equations, and ray tracings.
• y:
Irrelevant discussion/effectively blank.
• z:
Blank.
Sections 30882, 30883
Exam code: finalm4u1
p: 6 students
r: 2 students
t: 4 students
v: 16 students
x: 9 students
y: 2 students
z: 0 student

A sample "p" response (from student 0001):

Another sample "p" response (from student 1614):

A sample "x" response (from student 1959):

### Physics final exam problem: shunted voltmeter readings

Physics 205B Final Exam, spring semester 2016
Cuesta College, San Luis Obispo, CA

A 4.5 V emf source is connected to two light bulbs (each with different resistances), two voltmeters, and a switch. All of these components are ideal. Discuss why the voltmeters have equal readings while the switch is closed, and have unequal readings after the switch is opened. Show your work and explain your reasoning using the properties of voltmeters, Kirchhoff's rules and Ohm's law.

• p:
Correct. Explicitly explains/demonstrates that the voltmeters in the closed-switch circuit have equal readings, and the voltmeters in the open-switch circuit have unequal readings by:
1. applying Kirchhoff's loop rule to both circuits; and/or
2. explicitly calculating the voltage drops for each of the voltmeters in both circuits.
• r:
Nearly correct, but includes minor math errors. For the closed-switch circuit, may instead compare the different amount of currents flowing through each light bulb, instead of through each ammeter.
• t:
Nearly correct, but approach has conceptual errors, and/or major/compounded math errors.
• v:
Implementation of right ideas, but in an inconsistent, incomplete, or unorganized manner.
• x:
Implementation of ideas, but credit given for effort rather than merit. No clear attempt at applying Kirchhoff's rules, Ohm's law, and properties of voltmeters.
• y:
Irrelevant discussion/effectively blank.
• z:
Blank.
Sections 30882, 30883
Exam code: finalm4u1
p: 11 students
r: 8 students
t: 7 students
v: 7 students
x: 4 students
y: 0 students
z: 2 students

A sample "p" response (from student 1157):

### Physics final exam problem: shunted ammeter readings

Physics 205B Final Exam, spring semester 2016
Cuesta College, San Luis Obispo, CA

A 4.5 V emf source is connected to two light bulbs (each with different resistances), two ammeters, and a switch. All of these components are ideal. Discuss why the ammeters have unequal readings while the switch is closed, and have equal readings after the switch is opened. Show your work and explain your reasoning using the properties of ammeters, Kirchhoff's rules and Ohm's law.

• p:
Correct. Explicitly explains/demonstrates that the ammeters in the closed-switch circuit have unequal readings, and the ammeters in the open-switch circuit have equal readings by:
1. applying Kirchhoff's junction rule to both circuits; and/or
2. explicitly calculating the currents that flow through each of the ammeters in both circuits.
• r:
Nearly correct, but includes minor math errors. For the closed-switch circuit, may instead compare the different amount of currents flowing through each light bulb, instead of through each ammeter.
• t:
Nearly correct, but approach has conceptual errors, and/or major/compounded math errors.
• v:
Implementation of right ideas, but in an inconsistent, incomplete, or unorganized manner.
• x:
Implementation/application of ideas, but credit given for effort rather than merit. No clear attempt at applying Kirchhoff's rules, Ohm's law, and properties of ammeters.
• y:
Irrelevant discussion/effectively blank.
• z:
Blank.