Physics Homework

Solve the equation on the far right for v. Then substitute this expression for “v” into the first set of equations. Now solve for “r,” the radius of the discrete orbit.

Calculate the orbital radius of the hydrogen atom for the first principal quantum number. Use the general expression given in the test to calculate this value. (Hint: Quantum numbers are not significant digits and should not be counted as such in determining your final answer. Thus, this answer should have 2 significant digits.)

[removed] A

Calculate the speed of an electron in the innermost orbit of a hydrogen atom.

[removed] x 10[removed] m/sec

Use the Energy Levels for Hydrogen chart in the text to calculate the wavelength corresponding to the following electron transition. (Due to significant figure rules, energy answers should be written to the nearest tenth and wavelengths should have 2 significant figures.)

Transition Energy in ev’s Emitted wavelengths in m
 1 [removed]a0 [removed]a1 x 10[removed]a2

 

Calculate the orbital radius of the hydrogen atom for the second principal quantum number.

[removed] A

Calculate the orbital radius of the hydrogen atom for the fifth principal quantum number.

[removed] A

Assume that the radius of the hydrogen nucleus is 1.4 · 10-15 meters. How much larger than the nucleus is the entire hydrogen atom? (Calculate the atomic radius for n = 1. Round answer to nearest tenth.)

[removed] x 10[removed] times larger than the nucleus.

A pure sample of atomic gas has atoms with six principal quantum numbers that can yield several emission lines. What is the number of possible electron shell transitions for which energy is radiated? (Hint: if an electron has jumped form n = 1 to n = 6, it can have these transitions: n=6 to n=5, n=6 to n=4, n=6 to n=3, n=6 to n=2, n=6 to n=1. That’s 5 of them – can you find the rest? Remember, the electron didn’t have to jump all the way to the n=6 level to start out with.)

[removed]

Use the Energy Levels for Hydrogen chart in the text to calculate the wavelength corresponding to the following electron transition. (Due to significant figure rules, energy answers should be written to the nearest tenth and wavelengths should have 2 significant figures.)

Transition Energy in ev’s Emitted wavelengths in m
 
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PHYICS

1. You and a friend are moving a very heavy and irregular piece of furniture across a room. You are lifting it to prevent it from scratching your wooden floor. Your friend lets you pick where you are going to hold it and your friend will hold it at the other end (or some other place you tell your friend to hold it). To make it easier on yourself, you would:

A. Hold the end closer to the center of mass (your friend holds the other end). B. Hold the end farther from the center of mass (your friend holds the other end). C. Hold it at the center of mass and have your friend hold it from one of the other ends. D. It doesn’t matter where you pick – you’ll both have to exert the same force no matter where

you hold it. E. Hold either end since you have to exert the same force no matter which end you pick.

2. Two acrobats flying through the air grab and hold onto each other in midair as part of a circus act. One acrobat has a mass of 60 kg and has a horizontal velocity of 5 m/s just before the grab. Another acrobat has a mass of 50 kg and has a horizontal velocity of -3 m/s just before the grab. Their horizontal velocity immediately after they grab onto each other is:

A. 1.4 m/s B. 3.0 m/s C. 0.6 m/s D. 2.0 m/s E. 4.1 m/s

3. Your kid sister is making a mobile representing the earth, moon, and sun for her grade school science fair. The ruler is provided below to help you determine positions of the three hanging balls, of mass 15 g, 5 g, and 30 g, respectively. Of the five options provided, where would you connect a string to this mobile so that it would remain balanced when you hung it from the string? (The rods and strings all have negligible mass compared to the balls.)

1 2 3 4 5 6 7 8 9 10 11 12

15 g 5 g

30 g

A B C E D

Page 1

4. An 60-kg diver stands at the edge of a lightweight diving board, which is supported at two locations, as shown in the figure below. Determine the strength and direction of the force exerted on the diving board by the right-most support.

2.0 m 1.2 m

60 kg

A. 100 N downard B. 360 N upward C. 360 N downward D. 980 N downward E. 980 N upward

5. What additional torque must your bicep muscle exert around your elbow if you are holding a 4.5 kg (10 lb) weight horizontally? (Assume your forearm is 0.30 meters long.)

A. 3 Nm B. 11 Nm C. 13 Nm D. 4 Nm E. 1 Nm

6. Two children are riding on a merry-go-round. Child A is at a greater distance from the axis of rotation than child B. Which child has the larger angular speed?

A. They have the same angular speed. B. In order to find the speed we need to know the masses. C. child A D. In order to find the speed we need to know the radii. E. child B

7. A karate student throws a round kick to a target pad during her workout in the dojo. Her foot moves at 15 m/s just before landing the kick and is in contact with the pad for 0.02 seconds until it comes to rest on the pad (for an instant). If the effective combined mass of her foot & lower leg is 8 kg, with what average force does she hit the pad?

A. 6000 N B. 1200 N C. 225 N D. 80 N E. 1800 N

Page 2

8. Swimmers at a water park have a choice of two frictionless water slides (see figure). Although both slides drop over the same height h, slide 1 is straight while slide 2 is curved, dropping quickly at first and then leveling out. How does the speed v1 of a swimmer reaching the end of slide 1 compare with v2, the speed of a swimmer reaching the end of slide 2?

A. v1 < v2 B. v1 = 2 v2 C. v1 = v2 D. v1 > v2 E. We cannot compare the two speeds without knowing the swimmers’ masses.

9. An object of mass 10.0 kg is initially at rest. A 100 N force causes it to move horizontally through a distance of 6.00 m along a frictionless surface. What is the change in the kinetic energy of this object?

A. 200 J B. 60.0 J C. 0.00 J D. 20.0 J E. 600 J

10. A constant force is applied to an object. If the angle between the force and the displacement is 90°, the work done by this force is:

A. negative. B. positive. C. 0 J. D. Can’t answer without knowing the speed of the object E. Can’t answer without knowing the exact angle.

Page 3

11. The drive chain in a bicycle is applying a torque of 0.945 N m to the wheel of the bicycle. Treat the wheel as a hoop with a mass of 0.740 kg and a radius of 35.0 cm. What is the angular acceleration of the wheel?

A. 7.30 rad/s2 B. 10.4 rad/s2 C. 4.20 rad/s2 D. 3.64 rad/s2 E. 20.8 rad/s2

12. A piece of dirt (0.01 kg) is stuck in the tread of a spinning bicycle wheel. If the wheel is spinning at 60 RPM (rev/min) and the wheel has a radius of 0.35 meters, what is the magnitude of acceleration of the piece of dirt?

A. 2 m/s2 B. 5 m/s2 C. 10 m/s2 D. 18 m/s2 E. 14 m/s2

13. A metal bar has a frictionless axle going through its center of mass. You notice that the bar is not level (flat), but that it is tilted at a 30 degree angle (the right end is below the horizontal and the left end is above the horizontal) and that the bar is not rotating away from this orientation. You can say that:

A. The net force isn’t zero and the net torque is counter-clockwise on the bar. B. The net force is zero but the net torque is counter-clockwise in the bar. C. The net force is zero but the net torque is clockwise on the bar. D. The net force isn’t zero and the net torque is clockwise on the bar. E. The net force is zero and the net torque is zero on the bar.

14. Mars has about 1/10 the mass of the Earth and a radius 1/2 that of the Earth. Approximately, what is the acceleration of gravity (g) on Mars?

A. 25 m/s2 B. 10 m/s2 C. 4 m/s2 D. 2 m/s2 E. 12 m/s2

Page 4

15. Mars has a radius 3.41 x 106 m and a mass of 6.42 x 1023kg. What is the acceleration due to gravity on the surface of Mars?

A. 3.7 m/s2 B. 9.8 m/s2 C. 14.7 m/s2 D. 15.9 m/s2 E. 1.26 x 107 m/s2

16. An object of mass 7.0 kg is released from rest a certain height above the ground. Just before it strikes the ground it has a kinetic energy of 1750 J. From what height was the object dropped? Ignore air resistance and use g = 10 m/s2.

A. 0.0 m B. 30 m C. 15 m D. 10 m E. 25 m

17. Below, a set of five dumbbells are shown, where the weights have been moved around to different locations along the bar. The mass of the dumbbell in each case is the same as in all the others. Which dumbbell would require the greatest torque in order to rotate it about the axis indicated by the dashed line with a constant angular acceleration of 5 rad/s2?

A. B. C.

D. E.

Page 5

18. A firecracker, initially at rest on a level, frictionless table, explodes into three fragments. The momentum vectors of two of the fragments are shown, as viewed from above. What would the momentum vector of the third fragment have to be? Each grid unit represents one kilogram-meter- per-second (kg·m/s).

x

y 1p 

2p 

A.    3 ˆ ˆ2 kg m/s 1 kg m/sp x y    

B.    3 ˆ ˆ6 kg m/s 1 kg m/sp x y      

C.  3 ˆ7 kg m/sp x   

D.    3 ˆ ˆ2 kg m/s 5 kg m/sp x y      

E.    3 ˆ ˆ2 kg m/s 5 kg m/sp x y    

19. In a particular case, to stretch a relaxed muscle 2.6 cm requires a force of 25 N. Find the Young’s modulus for the muscle tissue, assuming it to be a uniform cylinder of length 0.24 m and cross-sectional diameter of 8.2 cm.

A. 12500 N/m2 B. 25040 N/m2 C. 53500 N/m2 D. 43700 N/m2 E. 35050 N/m2

Page 6

20. A 0.100 kg rubber ball is thrown horizontally with a speed of 10 m/s at a vertical wall. The ball rebounds with the same speed. The force of the collision on the ball is shown in the graph below.

( )t s

( )F N

maxF

0.010 s What is the value of the maximum force?

A. 2 N B. 20 N C. 2000 N D. 200 N E. Impossible to tell.

Page 7

Answer Key for Test “Sample MT2Fa15.tst”, 10/13/2015 No. in

Q-Bank No. on

Test Correct Answer 26 8 1 B 23 28 2 A 25 4 3 D 26 5 4 D 22 18 5 C 21 1 6 A 20 20 7 A 16 1 8 C 15 3 9 E 14 7 10 C 22 2 11 B 13 11 12 E 26 9 13 E 8 3 14 C

38 2 15 A 16 8 16 E 22 17 17 B 23 9 18 B 32 1 19 D 20 6 20 D

Page 1

 
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Physics Lab Report

I need some one do my physics lab reports. Do not copy from other lap report, please. 

Each student should write his/her own laboratory report.

Duplicating reports will result in an “E” in your final grade.

Lab Manuals (contained within each week)

•KET simulationshttp://virtuallabs.ket.org/physics/. Students will receive an e-mail from the KET Virtual Physics Labs with an invitation to enroll into the class.

•PhET Interactive simulations: http://phet.colorado.edu/en/simulations/category/physics.

Expression of the experimental results is an integral part of science. The lab report should have the following format:

• Cover page (10 points) – course name (PHY 132), title of the experiment, your name (prominent), section number, TA’s name, date of experiment, an abstract. An abstract (two paragraphs long) is the place where you briefly summarize the experiment and cite your main experimental results along with any associated errors and units. Write the abstract after all the other sections are completed.

The main body of the report will contain the following sections, each of which must be clearly labeled:

•Objectives (5 points) – in one or two sentences describe the purpose of the lab. What physical quantities are you measuring? What physical principles/laws are you investigating?

•Procedure (5 points) – this section should contain a brief description of the main steps and the significant details of the experiment.

•Experimental data (15 points) – your data should be tabulated neatly in this section. Your tables should have clear headings and contain units. All the clearly labeled plots (Figure 1, etc.) produced during lab must be attached to the report. The scales on the figures should be chosen appropriately so that the data to be presented will cover most part of the graph paper.

•Results (20 points) – you are required to show sample calculation of the quantities you are looking for including formulas and all derived equations used in your calculations. Provide all intermediate quantities. Show the calculation of the uncertainties using the rules of the error propagation. You may choose to type these calculations, but neatly hand write will be acceptable. Please label this page Sample Calculations and box your results. Your data sheets that contain measurements generated during the lab are not the results of the lab.

•Discussion and analysis (25 points) – here you analyze the data, briefly summarize the basic idea of the experiment, and describe the measurements you made. State the key results with uncertainties and units. Interpret your graphs and discuss what trends were observed, what was the relationship of the variables in your experiment. An important part of any experimental result is a quantification of error in the result.  Describe what you learned from your results. The answers to any questions posed to you in the lab packet should be answered here.

•Conclusion (5 points) – Did you meet the stated objective of the lab? You will need to supply reasoning in your answers to these questions.

Overall, the lab report should to be about 5 pages long.

Each student should write his/her own laboratory report.

Duplicating reports will result in an “E” in your final grade.

All data sheets and computer printouts generated during the lab have to be labeled Fig.1, Fig. 2, and included at the end of the lab report.

Lab report without attached data sheets and/or graphs generated in the lab will automatically get a zero score.

 
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OIS Homework (Statistics)

OIS 3660 Homework 1, Fall 2016

4-1

University of Utah

David Eccles School of Business

OIS 3660: Fall 2016: HW1

Due Monday September 19th, 11:59PM

Q1. Cruz runs a bakery. She has an oven that bakes 20 cookies at a time. It takes 40 minutes on average

for her to bake a cookie. What is the average number of cookies Cruz bakes an hour?

Q2. Clare works at the front desk of DESB. Between 10:30am and 11:00am, 10 students stop by to ask

questions on average. It usually takes 3 minutes to answer a question. What is the average number of

students either waiting or asking questions to Clare at the front desk? (Be careful when you find the

flow rate for this question!)

Q3. Hayden commutes to school from Park City. It usually takes her 40 minutes to get to school. She

finds that there are, on average, 60 cars that travel to school each hour from Park City. What is the

average number of cars on the way to school from Park City?

Jake’s Beer, Bait, & Tackle Co. (Q4-Q6)

Jake’s Beer, Bait, & Tackle Co. is a small chain of fishing tackle stores in northern Minnesota. In 2009,

the company’s revenue was $4,300,000 and its cost of goods sold was $3,200,000. Assume 52 weeks and

365 days per year. Assume that the annual inventory holding cost for Jake’s is 40%.

Q4. Jake keeps only 5.5 days-of-supply of inventory on average because much of his inventory is live bait

and micro-brew beer, both of which have a short shelf life. What is his annual inventory turns? (Round

your answer to two decimal places)

Q5. Given that he has 5.5 days-of-supply of inventory on average, how much inventory does Jake

have on average (in $)?

Q6. What is the inventory holding cost (in $) of an item that costs Jake $20 and is sold to his customers

at $30? (Round your answer to two decimal places)

OIS 3660 Homework 1, Fall 2016

4-2

B&K Consulting (Q7-Q9)

B&K is a strategy consulting firm that divides its consultants into three classes: Associates, Managers,

and Partners. The firm has been stable in size for the last 30 years, and on average, there have been 200

Associates, 60 Managers, and 20 Partners.

The work environment at B&K is rather competitive. After four years of working as an Associate, a

consultant goes “either up or out”; that is, becomes a Manager or is dismissed from the company.

Similarly, after working as a Manager for six years, a Manager either becomes a Partner or is dismissed.

The company recruits MBAs as Associates; no hires are made at the Manager or Partner level.

Q7. How many new MBA graduates does B&K hire every year? (Hint: Think of the Associate stage

itself as a process and use Little’s law to find the number of MBA graduates that are hired each year.

The following picture may help.)

Q8. What percentage (in %) of new hires at B&K will become Managers (as opposed to being

dismissed after 4 years of working as an Associate)? (Hint: Think of the Manager stage itself as a

separate process and find how many managers should be appointment each year. The following picture

may help.)

Q9. Every year, 2 Managers are promoted to Partner level. How many years on average does a

Partner stay in the company as a Partner?

4 years

200 Associates ? Associates/year

6 years

60 Managers ? Managers/year

OIS 3660 Homework 1, Fall 2016

4-3

A Simple Process (Q10 – Q13)

Consider the following process that makes customized suits. When an order is placed, measurement is

taken, which takes 30 minutes to complete. After taking the measurement, materials are prepared and

cut, and this takes one hour. Once the materials are prepared and cut, the materials are sewed. Sewing

takes 2.5 hours on average per order. The process operates for 10 hours a day. The following picture

summarizes the process.

Q10. What is the capacity of the process in [suits/day]?

Q11. Assume that the demand for the customized suit is 0.2[suits/hour]. What should the flow rate of

the process be in [suits/day]?

Q12. Assume that the demand for the customized suit is 0.5[suits/hour]. What is the implied utilization

(in %) of the Sewing stage?

Q13. Assume that the demand for the customized suit is 0.5[suits/hour]. What is the utilization (in %)

of the Measuring stage?

Howard County Hospital (Q14-Q19)

The Howard County Hospital is assessing its Emergency Department (ED) capacity so it knows how to

expand as the county population grows. The hospital has the following information about the ED:

Resource Number

Nurses 12

Physicians 5

X-ray Technicians 4

Examination rooms 10

Trauma bays 3

On average, nurses need to spend 35 minutes with each patient that comes in. Additionally, physicians

need to spend an average of 19 minutes with each patient. Each technician can X-ray up to 5 patients

per hour. All patients have to go through one nurse, one physician and the X-ray.

Preparing/cutting Materials

30 minutes 1 hour 2.5 hours

Taking Measurement

Sewing

OIS 3660 Homework 1, Fall 2016

4-4

Q14. What is the total capacity of Nurses, as in the maximum number of patients the Nurses can see in

one hour? Round your answer to one decimal place.

Q15. What is the total capacity of the X-Ray Technicians (max number of patients that can be X-rayed

in one hour)? Round your answer to one decimal place.

Thereafter, the patients are parsed into two categories: 20% of all patients that come into the ED are

trauma victims that need to be placed in a trauma bay. The other 80% of the patients go into normal

examination rooms. Each trauma patient spends an average of 30 minutes in a trauma bay before

leaving the ED (usually then being admitted to the main part of the hospital), whereas non-trauma

patients spend an average of 45 minutes in an examination room before leaving the ED.

Q16. Suppose on average 50 patients come to the emergency department every hour. What is the

implied utilization (in %) at the trauma bays? (Recall there are 3 trauma bays.)

Q17. Suppose on average 50 patients come to the emergency department every hour. What is the

implied utilization at the examination rooms (in %)? (Recall there are 10 examination rooms.)

Q18. Which resource is the bottleneck?

a) Nurses b) Physicians c) X-Ray Technicians d) Examination Rooms e) Trauma Bays

Q19. Suppose we hired one more physician so that the total number of physicians becomes 6. What will

be the capacity of the process, as in the maximum number of patients the Emergency Department can

treat in one hour? Round your answer to one decimal place

Q20. Which of the following statements is TRUE?

a. Implied utilization of a bottleneck stage is always greater than 100%. b. Utilization of a bottleneck stage is always equal to 100%. c. A non-bottleneck stage has excess capacity compared to the bottleneck stage, and the implied

utilization of a non-bottleneck stage is always less than 100%.

d. A non-bottleneck stage has excess capacity compared to the bottleneck stage, and the utilization of a non-bottleneck stage is always less than 100%.

e. It is possible for utilization of a stage to exceed 100%.

 
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Setup Of The Quantitative Description Of Your Rube Goldberg Device Step

The final project for this course is the creation of an analysis report. For Milestone Three, you will submit Setup of the Quantitative Description of Your Rube Goldberg Device Step.

This milestone is due in Module Five. It will provide an additional step towards the completion of the final project. This step should be fully analyzed in the final submission. Your submission will demonstrate the knowledge of how to calculate the values that give a quantitative description of what is going on during the selected step and at the transitions to/from the neighboring steps, using the quantitative description as a starting point.

Specifically, the following critical elements must be addressed:

I. Step Selection: Select a step or stage in the Rube Goldberg device. Provide a concise description of the step.

II. Previous Step A. Description: Analyze the behavior of the object in the interaction between the previous step and the selected step, qualitatively describing the transfer of energy that occurs. Which principles of conservation of energy and momentum can you apply to this behavior? B. Equations: Provide the equations that can be used to describe the transfer of energy and the momentum of the object from the previous step to the selected step. What is the connection between the basic physics concepts in the equations and the interaction of the object and force(s) from step to step? C. Calculations: Using the applicable equations you identified, calculate the transfer of energy and the momentum from the previous step to the selected step. How do these calculations help you predict the object’s location and velocity from the previous step to the step you selected?

III. Selected Step B. Equations: If applicable, provide the equations that can be used to describe the change in type and amount of energy across the selected step. C. Energy Calculation: Calculate the amount of energy that is converted from one form to another form using the changes in mass and height. For example, if appropriate for your selected step, you could calculate the transformation of potential energy to kinetic energy.

IV. Subsequent Step A. Description: Analyze the behavior of the object in the interaction between the selected step and the subsequent step, qualitatively describing the transfer of energy that occurs. Which principles of conservation of energy and momentum can you apply to this behavior? B. Equations: Provide the equations that can be used to describe the transfer of energy and the momentum of the object. What is the connection between the basic physics concepts in the equations and the interaction of the object and force(s) from step to step? C. Calculations: Using the applicable equations you identified, calculate the transfer of energy and the momentum from your selected step to the subsequent step. How do these calculations help you predict the object’s location and velocity from the step you selected to the subsequent step?

Guidelines for Submission:  Submit assignment as a Word document with double spacing, 12-point Times New Roman font, and one-inch margins. Your paper should be 2- to 3-pages.

 

 
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Physics: Projectile Motion Experiment

Projectile Motion Experiment

 

By Monday, August 19, perform the following experiments online at the Projectile Motion – Galileo website. (http://galileo.phys.virginia.edu/classes/109N/more_stuff/Applets/ProjectileMotion/jarapplet.html)

Fill in the tables, and post your answers to the questions.

Question 1

Procedure: Keep the initial velocity fixed at 50 m/s. Perform the experiment for each of the following angles:

  • 15 degrees
  • 30 degrees
  • 45 degrees
  • 60 degrees
  • 75 degrees

Record in table 1:

  • The maximum horizontal distance (Range) traveled by the projectile at various angles
  • The total time of flight at various angles
  • The maximum height attained

Table 1: Experiment 1 – Range & Time of flight

S. No. Initial Velocity Angle of Projection Range Time of Flight  Maximum Height Attained
1.          
2.          
3.          
4.          
5.          

 

Observe and Analyze:

  • What angle produces the maximum range? Why?
  • What angle produces the maximum height? Why?
  • Are there angles which produce the same range? If so, how would you explain this?

Question 2 

Procedure: Set the angle to 45 degrees. Perform the experiment with the following initial velocities.

  • 30 m/s
  • 40 m/s
  • 50 m/s
  • 60 m/s

Record in Table 2: The horizontal and vertical components of the velocity and the ranges for each of the velocities.

Table 2: Experiment 2 – Range at 45°

 

S. No. Initial Velocity Horizontal Velocity Vertical Velocity Range at 45°
1.        
2.        
3.        
4.        

 

Observe and Analyze:

  • As the velocity is increased what happens to the Range?
  • Using the initial horizontal and vertical velocities from your table, verify mathematically that the range is correct for the initial speed of 60 m/s.

Attached are assignment related online lectures and textbook chapters

 
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Newton Second & Third Law

Name

Tutorials in Introductory Physics ©Pearson Custom Publishing McDermott, Shaffer, & P.E.G., U. Wash. Updated Preliminary Second Edition, 2011

Mech HW–39

1. A block initially at rest is given a quick push by a hand. The block slides across the floor, gradually slows down, and comes to rest.

a. In the spaces provided, draw and label separate free-body diagrams for the block at each of the three instants shown.

A quick push by a hand…

1. (Initially at rest)

the sliding block slows…

2.

v

and is finally at rest.

3.

b. Rank the magnitudes of all the horizontal forces in the diagram for instant 1. Explain.

c. Are any of the forces that you drew for instant 1 missing from your diagram for instant 2?

If so, for each force that is missing, explain how you knew to include the force on the first diagram but not on the second.

d. Are any of the forces that you drew for instant 1 missing from your diagram for instant 3? If so, for each force that is missing, explain how you knew to include the force on the first diagram but not on the third.

NEWTON’S SECOND AND THIRD LAWS

Newton’s second and third laws

Tutorials in Introductory Physics ©Pearson Custom Publishing McDermott, Shaffer, & P.E.G., U. Wash. Updated Preliminary Second Edition, 2011

Mech HW–40

2. Two crates, A and B, are in an elevator as shown. The mass of crate A is greater than the mass of crate B.

a. The elevator moves downward at constant speed.

i. How does the acceleration of crate A compare to that of crate B? Explain.

ii. In the spaces provided below, draw and label separate free-body diagrams for the crates.

Free-body diagram for crate A

Free-body diagram for crate B

iii. Rank the forces on the crates according to magnitude, from largest to smallest. Explain your reasoning, including how you used Newton’s second and third laws.

iv. In the spaces provided at right, draw arrows to indicate the direction of the net force on each crate. If the net force on either crate is zero, state so explicitly. Explain.

Is the magnitude of the net force on crate A greater than, less than, or equal to that on crate B? Explain.

Elevator (moving down

at constant speed)

A

B

Cable

Crate A Crate B

Direction of net force

Newton’s second and third laws Name

Tutorials in Introductory Physics ©Pearson Custom Publishing McDermott, Shaffer, & P.E.G., U. Wash. Updated Preliminary Second Edition, 2011

Mech HW–41

b. As the elevator approaches its destination, its speed decreases. (It continues to move downward.)

i. How does the acceleration of crate A compare to that of crate B? Explain.

ii. In the spaces provided below, draw and label separate free-body diagrams for the crates in this case.

Free-body diagram for crate A

Free-body diagram for crate B

iii. Rank the forces on the crates according to magnitude, from largest to smallest. Explain your reasoning, including how you used Newton’s second and third laws.

iv. In the spaces provided at right, draw arrows to indicate the direction of the net force on each crate. If the net force on either crate is zero, state so explicitly. Explain.

Is the magnitude of the net force on crate A greater than, less than, or equal to that on crate B? Explain.

Crate A Crate B

Direction of net force

Newton’s second and third laws

Tutorials in Introductory Physics ©Pearson Custom Publishing McDermott, Shaffer, & P.E.G., U. Wash. Updated Preliminary Second Edition, 2011

Mech HW–42

3. A hand pushes three identical bricks as shown. The bricks are moving to the left and speeding up. System A consists of two bricks stacked together. System B consists of a single brick. System C consists of all three bricks. There is friction between the bricks and the table. a. In the spaces

provided at right, draw and label separate free-body diagrams for systems A and B.

b. The vector representing the acceleration of system A is shown at right. Draw the acceleration vectors for systems B and C using the same scale. Explain.

c. The vector representing the net force on system A is shown at right. Draw the net force vectors for systems B and C using the same scale. Explain.

d. The vector representing the frictional force on system A is shown below. Draw the remaining force vectors using the same scale.

N BH

N AB

N BA

f AT

f BT

Explain how you knew to draw the force vectors as you did.

A

B

Free-body diagram for system A

Free-body diagram for system B

Acceleration of A

Acceleration of B

Acceleration of C

Net force on A

Net force on B

Net force on C

 
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A Barge Floating In Fresh Water

A barge floating in fresh water (A? = 1000 kg/m3) is shaped like a hollow rectangular prism with base area A =650 m2 and height H= 2.0 m. When empty the bottom of the barge is located H0 =0.4 m below the surface of the water. When fully loaded with coal the bottom of the barge is located H1 = 1 m below the surface. Randomized Variables A = 650 m2 H0 = 0.4 m H1 = 1 m kqxmevrn.phr.png

 

No Attempt No Attempt 14% Part (b) Write an equation for the buoyant force on the empty barge in terms of the known data. No Attempt No Attempt 14% Part (c) Determine the mass of the barge in kilograms. No Attempt No Attempt 14% Part (e) Find the mass of the coal in terms of the given data. No Attempt No Attempt 14% Part (f) Find the mass of the coal in kilograms.
 
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Physics Of Cell HW1

11

2.3 A feeling for the numbers: microbes as the unseen majority

(a) Use Figure 2.1 to justify the assumption that a typical bacterial cell (that is, E. coli) has a surface area of 6µm2 and a volume of 1µm3. Also, express this volume in femtoliters. Make a corresponding estimate of the mass of such a bacterium. (b) Roughly 2–3 kg of bacteria are harbored in your large intestine. Make an estimate of the total number of bacteria inhabiting your intestine. Estimate the total number of human cells in your body and compare the two figures. (c) The claim is made (see Whitman et al., 1998) that in the top 200m of the world’s oceans, there are roughly 1028 prokaryotes. Work out the total volume taken up by these cells in m3 and km3. Compute their mean spacing. How many such cells are there per milliliter of ocean water?

(a) E. coli has (roughly) the shape of a cylinder that is 2 µm in length and 0.5 µm in radius. For those that are so inclined, the bacterium can alternatively be treated as a spherocylinder, though the results will not change in any interesting way. Using these numbers we calculate the area of an E. coli to be:

Acell = ⇡ ⇥ 1 µm⇥ 2 µm ⇡ 6 µm2. (2.28)

Its volume is:

Vcell = ⇡ ⇥ ✓ 1

2 µm

◆2 ⇥ (2µm) ⇡ 1µm3 (2.29)

= 1 fL. (2.30)

If we assume that the density of a bacterium is the same as that of water, the mass of one bacterium is 103kg/m3 ⇥ 10�18 m3 ⇡ 10�15 kg = 1 pg.

(b) The fact that each bacterium has a mass of 1 pg implies that 2�3 kg worth of bacteria in the intestines of one person amounts to 2 ⇠ 3⇥ 1015 bacteria.

Assume that the size of a typical human cell is roughly 10 µm in diameter and has a spherical shape with the same density as that of water. Let’s assume that the mass of a “typical” human body is roughly 80 kg. Further, let’s assume that thirty percent of the human mass corresponds to cells. On the basis of these assumptions, we find that the number of the cells in a human body is approximately

Mhuman Vcell⇢H2O

= 1 3 ⇥ 80 kg

4/3⇡ ⇥ (5⇥ 10�6 m)3 ⇥ 1000 kg/m3 ‘ 5⇥ 1013. (2.31)

By this estimate, the number of bacterial cells outnumbers the number of human cells by more than a factor of ten.

(c) Using (a) we can estimate the volume of 1028 prokaryotes to be about 10�18 m3 ⇥ 1028 = 1010 m3, which is equal to 10 km3.

HW 1

27

section of this cylinder with the same cross-sectional area. The schematic of the mature virion in fig. 2.31(C) shows that the CA proteins come together to form the capsid with inward pointing “spokes,” in the same way that the GAG polyproteins form the initial outer shell of the virion. This means that CA and GAG have the same surface areas per protein. Because the surface area of the capsid is less than that of the virion and because each CA protein is cleaved o↵ a GAG polyprotein, this fact immediately implies that not all the CA proteins can be used up to form the capsid.

From the micrographs, the capsid can be approximated as a cone with base radius r = 25 nm and side length s = 100 nm. Its surface area is then ⇡rs+⇡r2 ⇡ 1·104 nm2, and the number of CA proteins making up the capsid is then roughly 104

4⇡ ⇡ 800 CA proteins. This result can also be obtained by multiplying the ready-made estimate of 3500 total GAG proteins by the ratio of the surface areas

GAG proteins total· surface area capsid surface area virion

= 3500· 10 4 nm2

4⇡ · 60 nm2 ⇡ 800 CA proteins in capsid, (2.49)

where the virion radius used is 60 nm instead of 65 nm because the outer 5 nm of the virion shell are taken up by a lipid bilayer.

2.9 Areas and volumes of organelles

(a) Calculate the average volume and surface area of mitochondria in yeast based on the confocal microscopy image of Figure 2.18(C). (b) Estimate the area of the endoplasmic reticulum when it is in reticular form using a model for its structure of interpenetrating cylinders of diameter d ⇡ 10 nm separated by a distance a ⇡ 60 nm, as shown in Figure 2.25.

(a) The mitochondria in this yeast are shaped like a cylinder with a diameter of 400 nm approximately (which could be the resolution limit of the microscope). The total extension of this cylinder is about 20 µm. This results in a total mitochondrial volume of ⇡(0.2 µm)2 ⇥ 20 µm ⇡ 2.5 µm3. The total area is 2⇡ ⇥ 0.2 µm⇥ 20 µm ⇡ 25 µm2.

Mitochondria are thus just a small fraction of the total yeast volume, which is around 500 µm3. (b) Each “cross”, the unit that gets repeated in this structure, can be approxi- mated by two cylinders of length a and diameter d. Therefore, its surface area is 2⇥ ⇡ ⇥ 10 nm ⇥ 60 nm ⇡ 4000 nm2. Now, each one of this units occupies a volume a3 ⇡ 0.22⇥ 10�3 µm3.

We assume that a fibroblast has a height of approximately 1 µm and, based on figure 2.15, we approximate the area of the fibroblast were the ER is present to be 25 µm2, around one fourth of the total area of the field of view. Therefore, in this volume of 25 µm3 we can fit 25 µm3/(0.22⇥10�3 µm3) ⇡ 105 such units. This in turn corresponds to a total surface area of 105 ⇥ 4000 nm2 = 400 µm2.

 

 

Chapter 3

When: Stopwatches at Many Scales

3.1 Growth and the logistic equation

In the chapter, we described the logistic equation as a simple toy model for constrained growth of populations. In this problem, the goal is to work out the dynamics in more detail. (a) Rewrite the equation in dimensionless form and explain what units this means time is measured in. (b) Find the value of N at which the growth rate is maximized. (c) Find the maximum growth rate. (d) Use these results to make a one-dimensional phase portrait like that shown in Figure 3.10.

(a) Recall that the logistic equation can be written as

dN

dt = rN(1� N

K ). (3.16)

If we now define ⌧ = rt, this implies that

d

dt =

d

d⌧

d⌧

dt (3.17)

Now we can rewrite the original logistic equation as

dN

d⌧ = N(1� N

K ), (3.18)

with time measured in units of 1/r. (b) By di↵erentiating the right side with respect to N , we have

d

dN [N(1� N

K )] = (1� N

K )� N

K = 1� 2N

K = 0 (3.19)

31

45

proteins by 50% (we assume ideal situation). However, in the case of degrada- tion, the amount of removed protein will depend on its concentration and it can vary from protein to protein.

3.7 The sugar budget in minimal medium

In rapidly dividing bacteria, the cell can divide in times as short as 1200 s. Make a careful estimate of the number of sugars (glucose) needed to provide the carbon for constructing the macromolecules of the cell during one cell cycle of a bacterium. Use this result to work out the number of carbon atoms that need to be taken into the cell each second to sustain this growth rate.

The number of sugars used was already worked out in problem 2.5. In this solution, we consider the implications for fast growing cells. How does all of this sugar get into the bacterium. If we consider fast growth, each cell cycle is approximately 20 minutes (or 1200 seconds), so the intake is:

109 sugars

1200 seconds = 8⇥ 105 sugar molecules/sec

There are approximately 1000 transmembrane proteins that transport sugar in the membrane of an E. coli, so the rate at which each protein must work at is:

8⇥ 105 sugars sec · 1000 proteins ⇡ 800

sugar molecules

transmembrane protein · sec

3.8 Metabolic rates

Assume that 1 kg of bacteria burn oxygen at a rate of 0.006mol/s. This oxygen enters the bacterium by di↵usion through its surface at a rate given by � = 4⇡DRc0, where D = 2µm2/ms is the di↵usion constant for oxygen in water, c0 = 0.2mol/m

3 is the oxygen concentration, and R is the radius of the typical bacterium, which we assume to be spherical. (a) Show that the amount of oxygen that di↵uses into the bacterium is greater than the amount used by the bacterium in metabolism. For simplicity, assume that the bacterium is a sphere. (b) What conditions does (a) impose on the radius R for the bacterial cell? Compare it with the size of E. coli.

(a) To estimate the amount of oxygen di↵using into a bacterium we assume that all the oxygen arriving at the cell membrane is absorbed. Furthermore, assuming that the bacterium is a sphere of radius R = 1µm (the typical size of an E.coli cell), the rate of oxygen entering the cell is

� = 4⇡DRc0 = 3⇥ 109 1/s . (3.68)

Given that bacteria burn oxygen at a rate of r = 0.2mole/kg s and that the

 
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Physics Momentum

CONSERVATION OF MOMENTUM Name INTWO DIMENSIONS

1. Two objects are arranged on a level, frictionless table as shown. Two experiments are conducted in which object A is launched toward the stationary block B. The initial speed of object A is the same in both experiments; the direction is not. The initid and final velocities of object A in each experiment are shown.

The mass of block B is four times that of object A (m” = 4m^).

Top views Velocity Yectors (drawn to scale)

Mech HW-63

{ do,

Experiment 1 – before collision

ld”,l= o ilur: ?

– after collision

Tn, . uei

Direction of Lfio

Experiment2 – before collision 2 – after collision

a. In the space provided, draw separate arrows represeiting the direction of the change in momentum vector of object A in the two experiments.

Is the magnitude of the change in m.omcntum of object A in experiment I greater than, less than, or equal to that in experiment 2? Explain.

Experiment I Experiment 2

b. In the space provided, draw separate arrows representing the direction of the change in momentum vector of block B in the two experiments.

Afier the collisions, is the magnitude of the momentum of block B in experiment I greater than, less than, or equal to that in experiment 2? If the momentum of block B is zero in either case, state that explicitly. Explain.

Direction of Al^

Experiment I Experiment 2

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Mech HW-64

Conseroation of momentum in two dimensions

Two objects collide on a level, frictionless table. The mass of object A is 5.0 kg; the mass of object n is f .O tg. The objects stick together after the collision. The initial velocity of object A and the final velocity of both objects are shown.

2.

Before collision dltAi

After collision 1do, = d”r)

(One side of a square represents 0.1 m/s)

In the space provided, draw separate arrows for object A and for object B representing the direction of the change in momentum vector of the object.

Is the magnitude of the change in m,omentum of object A greater than, less than, or equal to that of object B? Explain your reasoning.

Direction of Al Object A Object B

b. System C is the system of both objects A and B combined. How does the momentum of system C before the collision compare to the momentum of system C after the collision? Discuss both magnitude and direction.

Construct and label a vector showing the momentum 6f system C at an instant before the collision. Show your work clearly.

c, Construct and label a vector showing the initial velocity of object B. Show your work clearly.

(Each side of a square represents 0.4 kg’m/s)

(Each side of a square represents 0.1 m/s)

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Consentation of momentum in two dimensions Name

3. Object A collides on a horizontal frictionless surface with an Frictionless horizontal surface

Mech HW-65

initially stationary target, object X. The initial and final velocities of object A are shown. The final velocity of object X is not given.

a, At an instant during the collision, is the net force on object A zero ot nbn-zero?

b. During the collision, is the momentum of object A conserved? Explain.

Is the momentum of the system consisting of objects A and X conserved? Explain.

c. On the same horizontal surface, object C collides with an initially stationary target, objectZ, The initial speeds of objects C and A are the same, ild trtx= trlz) tne.= tltc, After the collisions, object C moves in the direction shown and has the same final speed as object A.

i. In the space below, copy the vectors d6; and d6l with their tails togbther. Use these vectors to draw the change in velocity vector for glider C, AAc.

Top view

Before collision

A X oH

ax at rest

Aftercollision

AX€o 6o,

Arter collision

ii. Is the magnitude of the change in velocity vector of object A greater than, less than, or equal to the magnitude of the change in velocity vector of object C? Explain.

iii. Is the magnitude of the change in momentum vector of object A greater than, less than, or equal to the magnitude of the change in momentum vector of object C? Explain.

iv. Is the final speed of object X greater than, less than, or equal to the final speed of objectZ? Explain.

d. Consider the following incorrect statement: ‘6liders A ond C have the some chonge in momentum. They hove the some moss, ond because they have the some initiql speed ond same f inol speed, Av is the some for eoch of ,them.”

Discuss the error(s) in the reasoning.

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Before collision

Z o

At rest

 

 

DYNAMICS OF RIGID BODIES Name Mech HW-69

1. Energy analysis of the block-and-spool problem

A block and a spool are each pulled across a level, frictionless surface by a string, as illustrated at right.

The string pulling the block is tied to a small hook at the center of the front face of the block (not shown). The string pulling the spool is wrapped many times around the spool and may unwind as it is pulled.

The block and the spool have the same mass. The strings are pulled with the szlme constant tension and start pulling at the same instant.

Make the approximation that the strings and the hook are massless.

a. Does the spool cross the finish line before, afier, or at the sante instant as the block? Explain.

Tbp view

Start Finish k– -_-_- d — *–4

Bloc

Spooll

u Same

b. Consider the following dialogue between two students:

Student l: “f think thot there’s the some omount of work done on block ond spool os they ore pulled from the stort to the f inish since they both move the some distonce.”

Student 2: ‘f disogree. f think thot the hond pullirg the spool does more work thon the hond pulling the block since the string unwinds qs the spool is pulled.”

With which student, if either, do you agree? Explin.

When each crosses the finish line, is the total kinetic energy of the spool greater than, Iess than, or equal to that of the block? Explain. (Hint: Use the work-energy theorem.)

d. When each crosses the finish line, is the translational kinetic energy of the spool greater than,less than, or equal to that of the block? Explain.

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Mech Dynamics of rigid.bodies HW-70

2. Three identical rectangular blocks are at rest on a level, frictionless surface. Forces of equal magnitude that act in the same direction are exerted on each of the three blocks. Each force is exerted at a different point on the block (indicated by the symbol “Xo’), as shown in the top-view diagram below. The location of each block’s center of mass is indicated by a small circle.

For each of the blocks, draw an affow on the diagram above to indicate the direction of the acceleration of the block’s center of mass at the instant shown. If the magnitude of the acceleration of the center of mass of any block is zero, state that explicitly. Explain.

b. Rank the blocts according to magnitude of center-of-mass acceleration, fromlargest to smallest. If any two blocks have the same magnitude center-of-mass acceleration, state so explicitly. Support your ranking by drawinga point free-body diagram for each block.

3, A uniform rigid rod rests on a level, frictionless surface. The diagram below indicates four different combinations of (1) net force on the rod and (2) net torque on the rod about its center of mass. In each box, draw vectors that represent one or two forces that achieve the given combination of net force and net torque. If any combination is not possible, state so explicitly.

For example: In the second case, indicate one or two forces that could be exerted on the rod so that at the instant shown the net force on it is zero, but the net torque on it is not zero.

Tbp view

li,,l = o, l(-,1 = o l{,,*l = o, l(,,1 * o l{,,,1 + o, li,,l = o lF”.,l * o, l?”.,1 * o

.,,

Block I

Tbp view

Block 2 Block 3

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Dynamics of rigid bodies Name Mech HW-71

4. Three objects of equal mass, A, B, and C, are released from rest at the same instant from the same height on identical ramps. Objects A and B are both blocks, and they slide down their respective ramps without rotating. Object C rolls down the ramp without slipping. Its moment of inertia is unknown.

Objects A, B, and C are made of different materials, thus the coefficients of friction between the objects and their coffesponding ramps are not necessarily the same.

Object A reaches the bottom of its ramp first, followed by objects B and C, which reach the bottom at the same instant.

a. Rank the objects according to magnitude of center-of-mass acceleration,from largest to smallest. If any objects have the same magnitude center-of-mass acceleration, state so explicitly. Explain.

b. Rank the net forces exerted on the three objects according to magnitude, from largest to smallest. If the net force on arly two objects is the same, state so explicitly. Explain.

c. In the spaces provided, draw and label a (point) free- body diagram for each object.

Free-body diagraur for object i\

F-ree-bocly dia*uram

for object B Free-body diagram

for object C

d. Rank the frictional forces exerted on the three objects according to magnitude, from largest to smallest. If the magnitude of the frictional force is the same on any two objects, state so explicitly. Explain your reasoning.

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All three objects are relea.sed

 

 

Mech Dynamics of rigiilbodies HW:72

5. Energy analysis of falling-spools experiment

The modified Atwood’s machine shown at right consists of two identical spools connected by a massless, ‘ ” inextensible thread that runs over an ideal pulley. The thread is wrapped around spool A many times, but it is attached to a fixed point on spool B, so that spool B will not rotate.

The spools are released from rest from the same height at the same instant.

a. In tutorial, you observed the motion of the spools after they were released. Ignoring small dffirences in their nntions:

. In which direction did each spool move?

. Did spool A hit the ground before, after, or at the same instant as spool B?

Is the mngnitude of the center-of-nutss acceleration of spool A (while it is fallin g) greater than,less than, or equal to that of spool B? Explain.

Is the translational kinetic energy of spool A just before it hits the ground greater thsn, less than, or equal to that of spool B? Explain.

d. Is the total kinetic energy of spool A just before it hitsothe ground greater than, less than, or equal to that of spool B? Explain.

Consider the system consisting of all of these objects: spool A, spool B, the thread, the pulley, and the Eafth.

i. Explain how you can tell that the total energy of this system(i.e., Ugnv,o+ Ug^”,n * Kton,,e * K,*nr. n * Kro’ a, * K,o’ s) is constant as spools A and B fall.

b.

c.

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Dynamics of rtgtd bodies Narne Mech HW-73

Suppose that this system starts with Ugo”, o = f/srr, B = 9 J. Just before the spools hit the ground, which is where the zero for gravitational potential energy is chosen, spool A has translational kinetic energy K,on,”a = 4 J. Determine the value of the rotational kinetic energy of spool A at this instant. Show your work.

6. A third identical spool, spool C, is added to the falling-spools experiment described in the preceding problem.

As above, all spools are released from rest from the same height at the same instant. Spool C is not in contact with any other objects as it falls.

a, Rank the spools according to magnitude of center -of-mas s acc eleration (while falling), from largest to smallest. If any spools have the same center-of-mass acceleration, state so explicitly. Explain.

b. As in the preceding problem, suppose that Ugrrr. n = Ugr,, s = 9 J before the spools are released. Just before the spools hit the ground, which is where the zero for gravitational potential energy is chosen, spool A has trarrslational kinetic energy K,*,, e,= 4J.

i. Rank the spools according to maximum tanslatianal kinetic energy, from largest to smallest. If any spools have the same maximrrtn translational kinetic energy, state so explicitly. Explain. (Use the definition K*, = lma”^’.)

ii. Rank the spools according to maximum total kinetic energy, from largest to smallest. If any spools have the same maximum total kinetic energy, state so explicitly. Explain.

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CONSERVATION OF ANGULARMOMENTUM

Name Mech HW-77

1. In tutorial, you observed the following three experiments involving a student sitting at rest on a stool, holding a spinning bicycle wheel as shown at right:

Experiment 1: The student places his arm against the side of the wheel, slowing it to half its initial angular speed.

Experiment 2: The student places his arm against the side of the wheel, bringing it to a stop.

Experiment 3: The student quickly flips the wheel over (so that it is spinning clockwise when viewed from above, with the same angular speed it had initially).

Student initially at rest

Initial sense of wheel’s

rotation

a. You observed that the final angular speed of the student in experiment 3 is greater than that in experiment2, Account for this result using the ideas developed in the tutorial.

b. Rank the experiments according to final kinetic energy of the wheel, from largest to smallest. If the final kinetic energy of the wheel is the same in any two experiments, state so explicitly. (Hint: Can kinetic energy ever be negative?) Explain.

Rank the experiments according to final kinetic energy of the student, from largest to smallest. If the final kinetic energy of the student is the same in any two experiments, state soexplicitly. Explain.

d. Rank the followingfour quantities from largest to smallest: the initial kinetic energy of the wheel (K*i) and the final kinetic energy of the student-wheel system in experiments 1 ,2, and 3 (Kstr, etc.). Explain. (Hint: It may be helpful to think about changes in energy other than mechanical energy.)

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– Mech

HW-78 Conseruation of angular momentum

Z. The diagram below illustrates four hypothetical collisions that take placg on a level, frictionless surface.- The collisions are shown from a top-view perspective. All pucks are identical. If a linear or angular velocity is not specified, it is zero. If distances appear to be equal, assume that they are.

For each hypothetical collision:

a. Specify the direction of the angular momentum of the rod-puck(s) system with respect to the center of the rod both before and after the collision. If necessary, use the convention that a vector into the page is represented by the symbol I and a vector out of the page is represented by the symbol O.

b, Specify the direction of the linear momentum of the rod-puck(s) system, both before and after the collision.

c. On the basis of your answers above, state whether each hypothetical collision could ot could not occrfi. If a particular hypothetical collision could not occur, state whether it violates (l) the principle of conservation of linear momentum, (2) the principle of conservation of angular momentum, or (3) both.

Before collision

Case I

Case 2

Case 3

Case 4

Ball sticks to

rod

Sense of rotation

After collision

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