1. Physics 7A Section C, D Lecturer Dr. Yu Sato
Lecture slides available at

2. Course Website
Click on Physics 7A-C/D

3. Course Policy Highlights
Text College Physics: A Models Approach, Part I by W. Potter
 Text
 Discussion/Lab Workbook
Final Examination March 18, Tuesday, 10:30am –12:30pm
Course Grading = Exam grade +/- DL grade.
 Exam grade (8 quizzes and the final)
 D/L grade
Your quiz grade is the average of seven highest individual quiz grades.
Your Exam grade is then the higher of either of the two weighting schemes.
(a) 50% Quiz grade + 50% Final grade
(b) 20%Quiz grade + 80% Final grade

4. Eight Quizzes during lectures
Go to your assigned lecture time
Eight Quizzes during lectures
Q R S T
We need the red circled boxes to identify you
The blue circled boxes helps us sort and enter results, getting them back to you faster
We categorise/grade your responses based on :
(1) your understanding of the problem
(2) choice of appropriate model
(3) logic to arrive at the (hopefully correct) answer.
To find out the meaning of each of the letters, look on the website.

5. Attendance in the DL(Discussion/Lab) section is MANDATORY
Academic Dishonesty
Copying during quizzes/exams.
Taking a test for another student.
Modifying a quiz before asking for a re-grade.

6. DLs start immediately after lecture. All DLs are in 168 Roessler
(i.e. upstairs)
First DL starts TODAY
IMPORTANT All people who are wait-listed or not enrolled in the DL: Do not join a table or go up to the TA immediately.
Collect in a corner, allow the TA to get the lab started
and then the TA will address wait-list and enrollment issues.

7. What is physics? Can ice be colder than 0°C? Why is the sky blue?
We begin with the child-like wonder about our everyday world.
How does a lightswitch work?
How do magnets work?
Why does she start spinning
so much faster when she
pulls her arms and legs in?
How do planes fly?
What is “rainbow” really?

8. What does a physicist do?
Ouch…
Umm why does an apple
fall ??
How far does the power of gravity extend??
What does apple’s fall to do with celestial motion?
Sir. Isaac Newton

9. a model is valid and when it is not.
Physicists...
they observe phenomena and ask questions about them
Try to explain phenomena using a few principles (models)
- You cannot “pick and choose” when an explanation works
- you must have understanding of when
a model is valid and when it is not.
Physics is taking this approach to explain phenomena in the physical world.

10. What is physics 7? Models… Discussion/Lab lecture Text Quiz & Final
It will require your active participation! (DL grade will reflect this.)
Models…
Discussion/Lab
lecture
Text
Quiz & Final

11. What is physics 7?
Physics 7 is a 3-quarter series of physics classes, typically taken by bio-science and other non-physical science majors.
Physics 7A: Energy conservation, thermodynamics, particle models of matter.
Physics 7B: Classical Mechanics, rotational motion, fluids, circuits.
Physics 7C: Wave phenomena, optics, electricity and magnetism, the atom and modern quantum mechanics.

12. Models Useful way to think of and address questions about phenomena (e
Models Useful way to think of and address questions about phenomena (e.g. Ideal gas model)

13. Models in Physics 7A Models can help us organize our thinking, can contain other models, and can be very useful. Models also have limitations: experiment is the final judge.
Three-phase model of matter
Energy-interaction model
Mass-spring oscillator
Particle model of matter
Particle model of bond energy
Particle model of thermal energy
Thermodynamics
Ideal gas model
Statistical model of thermodynamics
We start with
These two…

14. Three-Phase model of Matter
Example H2O
Solid: Keeps its shape without a container
Liquid: Takes the shape of the (bottom of) the container. Keeps its volume the same.
Gas: Takes the shape and volume of the container.

15. Three-Phase model of Matter
Example H2O
Q How do we change the phase of matter?
How do we change the temperature of matter?
A By adding or removing energy. Often this energy is transferred from, or to the substance as heat Q.

16. Three-Phase model of Matter
Example Melting ice
At constant pressure, changes of phase occur at specific temperatures.
The phase change temperatures (TMP, TBP) are the same going through the phase change in both directions.
The amount of energy added/removed at a phase change (∆HM:Heat of melting, ∆HV:Heat of vaporization) is unique to each substance.

17. Three-Phase model of Matter
Temperature
gas
l-g coexist
TBP
s-l coexist
liquid
TMP
solid
Energy added or removed

18. Melting ice Ti= 20°C => Tf = room temperature
gas
l-g coexist
TBP
s-l coexist
liquid
TMP
solid
Energy of substance

19. Melting ice Temperature Final gas Initial l-g coexist TBP s-l coexist
liquid
TMP
solid
Energy of substance

20. Energy-Interaction Model
Energy systems:
There are many different types of energies called energy systems:
Emovement (KE)
Ethermal
Ebond
Espring
Eelectric
Egravity
For each energy system, there is an indicator that tells us how that energy system can change.
Ethermal: indicator is temperature
Ebond: indicator is the initial and final phases

21. Let’s talk about Conservation of Energy
Energy is both a thing (quantity) and a process. You & I contain energy, as do the chairs you sit on and the air we breathe.
We cannot see it, but we can measure the transformation of energy (or change, E).
Conservation of Energy
Energy cannot be created nor destroyed, simply
converted from one form to another.
If the energy of an object increases, something else must have given that object its energy.
If it decreases, it has given its energy to something else. Energy transfer is done through Heat or Work.

22. Energy Interaction Diagrams Based on the energy interaction model, it shows you how energy is transferred, how energy is conserved between energy systems.

23. Energy interaction diagrams - closedEa Eb Ec
Conservation of Energy
The total energy of a closed physical system must remain
constant. In other words, the change of the energies of all
energy systems associated with the physical system must
sum to zero.
Change in system energy = ∆Ea + ∆ Eb + ∆ Ec = 0

24. Energy interaction diagrams - openEa Eb Ec
Energy added
Energy removed
Conservation of Energy
The change of the energies of all energy systems associated with an open physical system must sum to the net energy added/removed as heat or work.
Change in system energy = ∆Ea + ∆ Eb + ∆ Ec
= (Energy added) - (Energy removed) = Q+W

25. Energy interaction diagrams
Example Melting ice
Ti= 0°C => Tf = room temperature
Temperature
Final
gas
Initial
l-g coexist
TBP
s-l coexist
liquid
TMP
solid
Energy of substance

26. Energy interaction diagrams
Example Melting ice
Process 1 : Ice at T= 0°C => Water at T = 0°C
Process 2 : Water at T = 0°C => Water at room temperature
Temperature
Process1
Final =
Process2
initial
gas
Process1
Initial
l-g coexist
liquid
TMP
s-l coexist
Process2
Final
solid
Energy of substance

27. Energy-Interaction Model
Example Melting ice
Process 1 : Ice at T= 0°C => Water at T = 0°C
Ice
Ethermal
Ebond
∆T=0
∆Eth=0
Initial phase Solid, Final phase Liquid

28. Energy-Interaction Model
Example Melting ice
Process 1 : Ice at T= 0°C => Water at T = 0°C
Ice
Heat
Ethermal
Ebond
∆T=0
∆Eth=0
Initial phase Solid, Final phase Liquid

29. Energy-Interaction Model
Example Melting ice
Process 1 : Ice at T= 0°C => Water at T = 0°C
Ice
Heat
Ethermal
Ebond
∆T=0
∆Eth=0
Initial phase Solid, Final phase Liquid
∆Eth + ∆Ebond= Q+W
∆Ebond= Q

30. Energy-Interaction Model
Example Melting ice
Process 2 : Water at T = 0°C => Water at room temperature
Ice
Ethermal
Ebond
Initial phase Liquid, Final phase Liquid

31. Energy-Interaction Model
Example Melting ice
Process 2 : Water at T = 0°C => Water at room temperature
Ice
Ethermal
Ebond T
Initial phase Liquid, Final phase Liquid
∆Ebond= 0

32. Energy-Interaction Model
Example Melting ice
Process 2 : Water at T = 0°C => Water at room temperature
Ice
Heat
Ethermal
Ebond T
Initial phase Liquid, Final phase Liquid
∆Ebond= 0
∆Eth + ∆Ebond= Q+W
∆Eth= Q

33. Energy-Interaction Model Example Melting ice Freezing
(Ice at T= 0°C <= Water
at T = 0°C)
Ice
Ethermal
Ebond
∆T=0
∆Eth=0
Initial phase Liquid, Final phase Solid

34. Energy-Interaction Model Example Melting ice Freezing
(Ice at T= 0°C <= Water
at T = 0°C)
Ice
Ethermal
Ebond
Heat
∆T=0
∆Eth=0
Initial phase Solid, Final phase Liquid

35. Next lecture Jan 15
Quiz 2 will cover today’s lecture, Discussion/Lab 1 material INCLUDING FNT(For Next Time) questions.