Good news, bad news…  I’ll be the Phys 222 SI Leader.

Slides:

Advertisements

Similar presentations

Chapter 15 Thermodynamics.

Advertisements

The Kinetic Theory of Gases

Do Now (11/7/13): What are the major topics and concepts from our unit on Fluids and Heat?

Lecture 2, p 1 Thermal reservoir Today: Equipartition First Law of Thermodynamics  Internal energy  Work and heat Lecture 2: Ideal Gases.

Question An ice cube is removed from the freezer and put in a cup of hot chocolate. Which statement is most accurate? A) Cold flows from the ice cube.

Standards/Plan.

PHYSICS 231 INTRODUCTORY PHYSICS I

Thermal Physics.

Entropy and the Second Law of Thermodynamics

Announcements 0. Extra study session: Saturday, December 7, 1:00 PM Room 1415 BPS. 1. THE FINAL EXAM WILL TAKE PLACE AT 8:00 PM - 10:00 PM, MONDAY, DEC.

1 Fall 2004 Physics 3 Tu-Th Section Claudio Campagnari Lecture 3: 30 Sep Web page:

Chapter 10 Thermal Physics, Temperature and Heat.

Chapter 13 Vibrations and Waves. When x is positive, F is negative ; When at equilibrium (x=0), F = 0 ; When x is negative, F is positive ; Hooke’s Law.

Wednesday, November 11, 1998 Chapter 10: Zeroth Law, Temperature Ideal Gas Law Kinetic Theory of Gases.

PHY PHYSICS 231 Lecture 39: Review Remco Zegers Question hours: Monday 15:00-17:00 Cyclotron building seminar room.

Fluid Flow and Continuity Imagine that a fluid flows with a speed v 1 through a cylindrical pip of cross-sectional area A 1. If the pipe narrows to a cross-

Chapter 13 Vibrations and Waves.  When x is positive, F is negative ;  When at equilibrium (x=0), F = 0 ;  When x is negative, F is positive ; Hooke’s.

Physics 207: Lecture 30, Pg 1 Lecture 30Goals: Wrap up chapter 20. Wrap up chapter 20. Review for the final. Review for the final. Final exam on Friday,

Simple Harmonic Motion

Chapter 13: Temperature and Ideal Gas

Chapter 9 Preview Objectives Defining Temperature Thermal Equilibrium

Heat and Temperature Matter is made of Atoms Electron Microscope Photo of Germanium Atoms.

Gas molar specific heats Mean kinetic energy of a gas molecule: If we have n moles of gas: Then molar specific heat at constant volume should be: What.

 The average kinetic energy (energy of motion ) is directly proportional to absolute temperature (Kelvin temperature) of a gas  Example  Average energy.

Waves and Sound Ch

A microscopic model of an ideal gas

Thermodynamics I Temperature Heat

Chapter 6.  Temperature ◦ Is something hot or cold? ◦ Relative measure.

Mechanics Exercise Class Ⅳ

Spontaneity of Chemical and Physical Processes: The Second and Third Laws of Thermodynamics 1.

Chapter 15 Thermodynamics.

Kinetic Molecular Theory of Matter

Heat is a form of:. Everything in the universe has heat energy! Your BODY, your CAR…even ICE!

Final Exam Review Phys 221 SUPPLEMENTAL INSTRUCTION Good Luck!

Thermal Physics Thermal Physics is the study of temperature and heat and how they effect matter. Heat leads to change in internal energy which shows as.

Thermodynamics Chapter 12.

Springs We are used to dealing with constant forces. Springs are more complicated - not only does the magnitude of the spring force vary, the direction.

Physics 207: Lecture 21, Pg 1 Physics 207, Lecture 21, Nov. 15 l Agenda: l Agenda: Chapter 16, Finish, Chapter 17, Sound  Traveling Waves  Reflection.

Chapter 11: Vibrations and Waves Periodic Motion – any repeated motion with regular time intervals.

Sound Test Answers. Question 1 What is the frequency of the pendulum given the graph of its horizontal position as a function of time? Show your work.

Thermal contact Two systems are in thermal (diathermic) contact, if they can exchange energy without performing macroscopic work. This form of energy.

Chapter 10 Thermal Energy. Chapter Objectives Define Temperature Converting between the 3 temperature scales Identify Linear Expansion Utilize the Coefficient.

Physics 207: Lecture 30, Pg 1 Lecture 30Goals: Review for the final. Review for the final. Final exam on Monday, Dec 20, at 5:05 pm, at Sterling 1310,

Physics (H) 3rd Quarter Exam Review.

Matter and Energy Chapter 4. Make sure you have everything you need to go home Make sure your phone is turned off Get out your bell work make sure your.

Chapter 19 The Kinetic Theory of Gases To study p, V, E int, T, …etc. from a “molecular” approach 19.1 A new way to look at gases: Warm up: How many moles.

Energy and Matter. In which state of matter does conduction of heat occur? Why?

Chapter 15 Oscillations. Periodic motion Periodic (harmonic) motion – self-repeating motion Oscillation – periodic motion in certain direction Period.

Review for Final Exam  Exam format: - 25 problems; 5 from the last 3 chapters; 3 advanced, 3 intermediate, 19 simple - Time: Wed. Dec. 11, noon-3pm -

Physics 231 Topic 12: Temperature, Thermal Expansion, and Ideal Gases

Thermal Physics Chapter 10. Thermal Physics Thermal physics looks at temperature, heat, and internal energy Heat and temperature are not the same thing.

Chapter 10 Thermal Physics. Thermal physics is the study of Temperature Heat How these affect matter.

Heat & Temperature Chapter 5 Student Learning Objectives Relate kinetic energy to temperature Compare temperature scales Analyze systems to determine methods.

IV. Kinetic theory (continued – see previous lecture) 5. Heat capacitance a) Monoatomic gas } b) Equipartition principle. Degrees of freedom Diatomic gas,

Halliday/Resnick/Walker Fundamentals of Physics

Chapter 23 The First Law of Thermodynamics. Thermal Physics Macroscopic Microscopic The Diffusion The Viscous The Transfer of Heat Exchange molecule T.

Advanced Physics Chapter 13 Temperature and Kinetic Theory.

Chapter 9 Heat.

Chapter 15 Thermodynamics Thermodynamic Systems and Their Surroundings Thermodynamics is the branch of physics that is built upon the fundamental.

 Temperature and thermal expansion  Specific Heat Capacity  Phase changes and Heat  Molecular picture of a gas  Ideal gas law  Kinetic theory of.

THERMODYNAMICS THE NEXT STEP. THERMAL PROPERTIES OF MATTER STATE VARIABLES – DESCRIBE THE SUBSTANCE –PRESSURE –TEMPERATURE –VOLUME –QUANITY OF SUBSTANCE.

States that if the volume and temperature of a fixed amount of gas do not change, the pressure also remains constant. The Ideal Gas Law.

Simple Harmonic Motion (SHM)

Physics 141Mechanics Lecture 24 Heat and Temperature Yongli Gao So far we have concentrated on mechanical energy, including potential and kinetic energy.

Chapter 6 Thermochemistry: pp The Nature of Energy Energy – Capacity to do work or produce heat. – 1 st Law of Thermodynamics: Energy can.

Plan for Today (AP Physics 1)

The Kinetic Theory of Gases

The Kinetic Theory of Gases

Presentation transcript:

Good news, bad news…  I’ll be the Phys 222 SI Leader

How to participate in this review session  Don’t just sit there.  When I solve problems I’ll try to write up the generic equation that I’m using first, then plug in numbers. Generic equations will be in blue. All other work is in some other color.  When you see how I’m solving the problem, try to look up the equation on the equation sheet.

DON’T JUST SIT THERE

Exam Overview “Approximately 1/3 of the problems will stress understanding of the physics concepts, whereas the remainder will be numerical problems to test ability to apply these concepts.” -Syllabus 27 Questions

Verbatim from blackboard  questions on the material covered in exams 1 and 2  questions on the material that has not been tested yet (i.e., after exam 2)  4 questions about the laboratories.

Lectures covered since exam 2 Simple Harmonic Motion Pendulum, damped and forced oscillations Sound waves. Energy, intensity. Resonance Interference. Standing waves. Beats. Doppler Temperature. Thermometers. Thermal expansion Heat and phase changes Heat transfer Equations of state. Ideal gas. Kinetic model Phase diagrams First law of thermodynamics Thermal processes. Heat capacities Heat engines and refrigerators Second law of thermodynamics. Carnot cycle Entropy

Breakdown…

Estimates of what’s most important (from me)  Doppler effect  Entropy  Thermal expansion  Thermal equilibrium  Waves along a string  First law  Simple Harmonic Motion

SHM  A block of mass 6 kg is attached to a spring, and the block is stretched out 30 cm before being released. If the period of the oscillation is 10 seconds, what is the spring constant?

Traveling wave Y(x,t) = (1.00 cm)cos[(10.00 rad/m)x + (30.0 rad/s)t]. What is the velocity of the wave? (remember magnitude and direction) What is the upward velocity of the point x=2 on the string at t=3?

 The molar mass of nitrogen is 14 g/mol. Assume that it can be modeled as a monatomic ideal gas. If you have 2 kg of nitrogen at 30 degrees Celsius, What is the total energy of the gas? What is the average velocity of the gas particles? What is the specific heat of the gas? What is the root-mean-square velocity of the gas particles?

Internal Energy U for gases Degrees of Freedom Energy, single molecule Energy, collection of molecules C V (Specific Heat at Constant Volume) C P (Specific Heat at Constant Pressure) Monatomic Gas 3 Diatomic Gas 5 Elemental Solids 6 Gas with F degrees of freedom F

Examples…

Doppler Effect  You’re running away from your crying sister (producing a sound at 3000 Hz) at a speed of 5 m/s. She’s running towards you at a rate of 3 m/s. What frequency do you hear?

Sound waves  A continuous succession of sinusoidal wave pulses are produced at one end of a very long string and travel along the length of the string. The wave has frequency 10 Hz seconds, amplitude.2 m, and the string has mass 12 kg and a length of 500 meters and the tension through the string is 800 N. Write an equation describing the wave: How long does it take the wave train to travel 5 m along the string? How long does it take a point on the wave to travel a distance of 5 m along the string?

SHM  A block of mass 5 kg is attached to a spring, and the block is stretched out 40 cm before being released. If the period of the oscillation is 5 seconds, what is the spring constant?  Write an equation describing the spring if at t=0 the block is at x=40 cm.

Beats

 Critical point (P and T)?  Triple point?  (P and T)?  At 1000 bar, what are the melting and boiling points?  At 10 bar, what are the melting point and boiling point?

Thermal Equilibrium Problems

Example

 You pee on an icecube at 0 degrees Fahrenheit (m= 11 grams) in a thermally insulated cup with a liquid that has a specific heat very similar to water and is at a temperature of 40 C. How many mL will you have to unload in order to completely melt the icecube at thermal equilibrium?

Conduction Problem

Intensity

 A 1200 Watt speaker is in the center of a 10 x 10 meter square room on a pedestal, at the same height as your ear. If you’re standing on the perimeter of the room, and assuming that your ear has an area of 1 cm 2, What is the intensity of the speaker where your ear is at? What is the power delivered to your ear, in Watts? What is the power delivered to your ear, in decibels? If you double the distance between you and the speaker, what will the new intensity in decibels be?

Heat Transfer  How much heat energy per second is lost due to radiation by a 40 degree Celsius basketball (r=6 in.) inside a 20 degree Celsius room? Assume blackbody radiation.

Thermal Expansion

Do I need to convert to Kelvin?

SituationMust I convert to Kelvin, or can I use Celsius? Celsius OKAY. Kelvin OKAY. Celsius NOT OKAY. Kelvin OKAY.

Carnot Cycle  What is the efficiency of the Carnot Cycle if the T H =30 °C, T c =-100°C?

 Two sides of a room contain gas at a different temperature. After 20 minutes the gases have mixed. This is irreversible. (T/F)  You touch a warm pot with your hand. The heat flow that occurs is reversible. (T/F)  You can convert 30 J of work into 30 J of heat and leave everything else the same. (T/F)  You can convert 30 J of heat into 30 J of work and leave everything else the same. (T/F)

 An Otto cycle expands gas from 30 m 3 to 50 m 3. What is the efficiency if monatomic oxygen is used? What is the efficiency if diatomic oxygen is used?

 You have 5 kg of CO 2 (m=48 g/mol) in a box of volume 4 m 3 at a pressure of 50 kPa. What is the temperature of the gas?

 A monatomic gas increases triples in volume during an adiabatic process. If the initial temperature is 50 degrees Celsius, what is the final temperature?  You do 50 J of work on a system and dump 30 J of heat in; what is the change in internal energy of the system?

 A gas expands at constant pressure from a volume of 10 m 3 to a volume of 30 m 3 at a pressure of 20 kPa. What is the work done on the gas?

 Two moles of an ideal diatomic gas have an initial pressure of 1.00 atm and initial volume of 40.0 L. The gas molecules can translate and rotate but not vibrate. The gas is compressed at constant pressure to a new volume of 30.0 L. The change in the internal energy of the gas during this process is ____ L·atm.

 Consider an Otto cycle where 20 J of energy go in and 10 J of energy go out. What is the efficiency?  A refrigerator operating in a cycle has a coefficient of performance of To remove 9.00 J of heat from inside the refrigerator to the outside per cycle requires ____ J of work to be done on the refrigerator per cycle.

 Past exam problem: A ball of putty with mass m = 0.4 kg and speed v = 5.0 m/s hits a rod of mass M = 0.6 kg and length L = 4.0 m that is suspended from the ceiling by a hinge as shown in the figure. The ball hits the rod half-way between the hinge and its bottom end and sticks to the rod after the collision. What is the angular velocity of the ball-rod system after the collision?