Q19.1 A system can be taken from state a to state b along any of the three paths shown in the pV–diagram. If state b has greater internal energy than state.

Slides:

Advertisements

Similar presentations

QUICK QUIZ 22.1 (end of section 22.1)

Advertisements

Chapter 12: Laws of Thermo

APHY201 5/31/ The First Law of Thermodynamics A systems internal energy can be changed by doing work or by the addition/removal of heat: ΔU.

Chapter 18: Heat,Work,the First Law of Thermodynamics

Using the “Clicker” If you have a clicker now, and did not do this last time, please enter your ID in your clicker. First, turn on your clicker by sliding.

Kinetic Theory and Thermodynamics

ConcepTest Clicker Questions

Physics 52 - Heat and Optics Dr. Joseph F

The Laws of Thermodynamics Chapter 12. Principles of Thermodynamics Energy is conserved FIRST LAW OF THERMODYNAMICS Examples: Engines (Internal -> Mechanical)

1 UCT PHY1025F: Heat and Properties of Matter Physics 1025F Heat & Properties of Matter Dr. Steve Peterson THERMODYNAMICS.

PHYSICS 231 INTRODUCTORY PHYSICS I Lecture 18. The Laws of Thermodynamics Chapter 12.

Physics 101: Lecture 25, Pg 1 Work Done by a System W W yy W = p  V W > 0 if  V > 0 expanding system does positive work W < 0 if  V < 0 contracting.

How much work is done by the gas in the cycle shown? A] 0 B] p 0 V 0 C] 2p 0 V 0 D] -2p 0 V 0 E] 4 p 0 V 0 How much total heat is added to the gas in the.

The Laws of Thermodynamics Chapter 12. Principles of Thermodynamics  Energy is conserved oFIRST LAW OF THERMODYNAMICS oExamples: Engines (Internal ->

Fig A p-V diagram of an adiabatic process for an ideal gas from state a to state b.

How much work is done by the gas in the cycle shown? A] 0 B] p 0 V 0 C] 2p 0 V 0 D] -2p 0 V 0 E] 4 p 0 V 0 How much total heat is added to the gas in the.

Thermodynamics.

Absolute Zero Physics 313 Professor Lee Carkner Lecture 15.

Fig The infinitesimal work done by the system (gas) during the small expansion dx is dW = p A dx.

AP Physics – 1 st Law Continued 1.Collect and read the handout on Heat Engine Efficiency from the front of the room 2.When finished work your way through.

Fig The net work done by the system in the process aba is –500 J.

For the cyclic process shown, W is:D A] 0, because it’s a loop B] p 0 V 0 C] - p 0 V 0 D] 2 p 0 V 0 E] 6 p 0 V 0 For the cyclic process shown,  U is:

Copyright © 2008 Pearson Education Inc., publishing as Pearson Addison-Wesley PowerPoint ® Lectures for University Physics, Twelfth Edition – Hugh D. Young.

MHS Physics Department AP Unit II C 2 Laws of Thermodynamics Ref: Chapter 12.

P-V Diagrams and processes Contents:

First Law of Thermodynamics Introduction First Law of Thermodynamics Calculation of Work PVT diagrams Thermodynamic processes Simple Examples The “everything”

Thermodynamics. Thermodynamic Process in which energy is transferred as heat and work.

Work and heat oWhen an object is heated and its volume is allowed to expand, then work is done by the object and the amount of work done depends generally.

Results from kinetic theory, 1 1. Pressure is associated with collisions of gas particles with the walls. Dividing the total average force from all the.

Adiabatic Processes. Pressure/Temp and Vol/Temp Adiabatic Compression If I compress air at atmospheric pressure and room temperature by a factor of 10.

Dr.Salwa Al Saleh Internal Energy Energy Transfers Conservation of Energy and Heat Work Lecture 9.

Chapter 15: Thermodynamics

The Laws of Thermodynamics

Some common processes Isobaric Isobaric. Some common processes Isovolumetric Isovolumetric.

Thermodynamics The First Law of Thermodynamics Thermal Processes that Utilize an Ideal Gas The Second Law of Thermodynamics Heat Engines Carnot’s Principle.

Lecture Outline Chapter 12 College Physics, 7 th Edition Wilson / Buffa / Lou © 2010 Pearson Education, Inc.

Determine the heat capacity (in calories/C°) of a lake containing two million gallons (approximately 8 million kilograms) of water at 15C°. Select.

Chapter 19. “A theory is the more impressive the greater the simplicity of its premises, the more different kinds of things it relates, and the more extended.

Thermodynamics How Energy Is Transferred As Heat and Work Animation Courtesy of Louis Moore.

The internal energy of a substance can be changed in different ways. Work can transfer energy to a substance and increase its internal energy.

Thermodynamics. System / environment Diathermal / adiabatic Walls between the system and surroundings are called diathermal if they permit energy flow.

when system is subdivided? Intensive variables: T, P Extensive variables: V, E, H, heat capacity C.

Thermodynamics. Announcements – 1/21 Next Monday, 1/26 – Readiness Quiz 1 –Chapter 19, sections 1 – 4 –Chapter 20, sections 1 – 4 Next Wednesday, 1/28.

The Thermodynamic Cycle. Heat engines and refrigerators operate on thermodynamic cycles where a gas is carried from an initial state through a number.

Ch15 Thermodynamics Zeroth Law of Thermodynamics If two systems are in thermal equilibrium with a third system, then they are in thermal equilibrium with.

Thermodynamics. Thermodynamic Systems, States and Processes Objectives are to: define thermodynamics systems and states of systems explain how processes.

Thermodynamics Thermal Processes The 2 nd Law of Thermodynamics Entropy.

Thermodynamics Internal energy of a system can be increased either by adding energy to the system or by doing work on the system Remember internal energy.

First Law of Thermodynamics

Physics 207: Lecture 27, Pg 1 Physics 207, Lecture 27, Dec. 6 l Agenda: Ch. 20, 1 st Law of Thermodynamics, Ch. 21  1 st Law of thermodynamics (  U=

B2 Thermodynamics Ideal gas Law Review PV=nRT P = pressure in Pa V = volume in m3 n = # of moles T= temperature in Kelvin R = 8.31 J K -1 mol -1 m = mass.

Thermodynamics Davidson College APSI Ideal Gas Equations P 1 V 1 / T 1 = P 2 V 2 / T 2 PV = n R T (using moles) P V = N k B T (using molecules)  P:

Thermodynamics Thermodynamics is a branch of physics concerned with heat and temperature and their relation to energy and work.

Work in Thermodynamic Processes

KIMIA LINGKUNGAN BAGIAN 2: TERMODINAMIKA. PREVIEW In this third part of the course we:  define and apply a number of thermodynamic ideas and concepts.

On expanding isothermally from 2L to 4L, an ideal gas does 6J of work, as the pressure drops from 2 atm to 1 atm. By how much must it expand to do an additional.

The Laws of Thermodynamics Enrolment No.: Noble Group of Institutions - Junagadh.

Lecture 26Purdue University, Physics 2201 Lecture 26 Thermodynamics I PHYSICS 220.

Chapter 11 Super Review. 1. A two mole sample of a gas has a temperature of 1000 K and a volume of 6 m 3. What is the pressure?

Chapter 11 Thermodynamics Worksheet

Which statement about these two thermodynamic processes is correct?

D. |Q| is the same for all three paths.

First Law of Thermodynamics

Quasistatic processes The relation of heat and work

Q20.1 Metal box at 0°C Metal box at 0°C

Three cylinders Three identical cylinders are sealed with identical pistons that are free to slide up and down the cylinder without friction. Each cylinder.

First Law of Thermodynamics

This pV–diagram shows two ways to take a system from state a (at lower left) to state c (at upper right): • via state b (at upper left), or • via state.

ConcepTest 15.1 Free Expansion

Consider an isothermal reversible expansion of an ideal gas

Presentation transcript:

Q19.1 A system can be taken from state a to state b along any of the three paths shown in the pV–diagram. If state b has greater internal energy than state a, along which path is the absolute value |Q| of the heat transfer the greatest? 1. path 1 2. path 2 3. path 3 4. |Q| is the same for all three paths 5. not enough information given to decide

A19.1 A system can be taken from state a to state b along any of the three paths shown in the pV–diagram. If state b has greater internal energy than state a, along which path is the absolute value |Q| of the heat transfer the greatest? 1. path 1 2. path 2 3. path 3 4. |Q| is the same for all three paths 5. not enough information given to decide

Q19.2 A system can be taken from state a to state b along any of the three paths shown in the pV–diagram. If state b has greater internal energy than state a, along which path is there a net flow of heat out of the system? 1. path 1 2. path 2 3. path 3 4. all of paths 1, 2, and 3 5. none of paths 1, 2, or 3

A19.2 A system can be taken from state a to state b along any of the three paths shown in the pV–diagram. If state b has greater internal energy than state a, along which path is there a net flow of heat out of the system? 1. path 1 2. path 2 3. path 3 4. all of paths 1, 2, and 3 5. none of paths 1, 2, or 3

Q19.3 A system is taken around the cycle shown in the pV–diagram, from state a to state b and back to state a in a clockwise direction. For this complete cycle, 1. Q > 0 and W > 0 2. Q > 0 and W < 0 3. Q < 0 and W > 0 4. Q < 0 and W < 0 5. none of the above

A19.3 A system is taken around the cycle shown in the pV–diagram, from state a to state b and back to state a in a clockwise direction. For this complete cycle, 1. Q > 0 and W > 0 2. Q > 0 and W < 0 3. Q < 0 and W > 0 4. Q < 0 and W < 0 5. none of the above

Q19.4 This pV–diagram shows two ways to take a system from state a (at lower left) to state b (at upper right): • via the path acb (in purple), or • via the path adb (in green) Which statement is correct? 1. W > 0 for both path acb and path adb 2. W > 0 for path acb but W < 0 for path adb 3. W < 0 for path acb but W > 0 for path adb 4. W < 0 for both path acb and path adb 5. none of the above

A19.4 This pV–diagram shows two ways to take a system from state a (at lower left) to state b (at upper right): • via the path acb (in purple), or • via the path adb (in green) Which statement is correct? 1. W > 0 for both path acb and path adb 2. W > 0 for path acb but W < 0 for path adb 3. W < 0 for path acb but W > 0 for path adb 4. W < 0 for both path acb and path adb 5. none of the above

Q19.5 In an isothermal expansion of an ideal gas, the amount of heat that flows into the gas 1. is greater than the amount of work done by the gas 2. equals the amount of work done by the gas 3. is less than the amount of work done by the gas, but greater than zero 4. is zero 5. is negative (heat flows out of the gas)

A19.5 In an isothermal expansion of an ideal gas, the amount of heat that flows into the gas 1. is greater than the amount of work done by the gas 2. equals the amount of work done by the gas 3. is less than the amount of work done by the gas, but greater than zero 4. is zero 5. is negative (heat flows out of the gas)

Q19.6 An ideal gas begins in a thermodynamic state a. When the temperature of the gas is raised from T1 to a higher temperature T2 at a constant volume, a positive amount of heat Q12 flows into the gas. If the same gas begins in state a and has its temperature raised from T1 to T2 at a constant pressure, the amount of heat that flows into the gas is 1. greater than Q12 2. equal to Q12 3. less than Q12, but greater than zero 4. zero 5. negative (heat flows out of the system)

A19.6 An ideal gas begins in a thermodynamic state a. When the temperature of the gas is raised from T1 to a higher temperature T2 at a constant volume, a positive amount of heat Q12 flows into the gas. If the same gas begins in state a and has its temperature raised from T1 to T2 at a constant pressure, the amount of heat that flows into the gas is 1. greater than Q12 2. equal to Q12 3. less than Q12, but greater than zero 4. zero 5. negative (heat flows out of the system)

Q19.7 An ideal gas is taken around the cycle shown in this pV–diagram, from a to c to b and back to a. Process ac is at constant pressure, process cb is adiabatic, and process ba is at constant volume. For process cb, 1. Q > 0, W > 0, and DU = 0 2. Q > 0, W > 0, and DU > 0 3. Q = 0, W > 0, and DU < 0 4. Q = 0, W < 0, and DU > 0 5. Q < 0, W > 0, and DU > 0

A19.7 An ideal gas is taken around the cycle shown in this pV–diagram, from a to c to b and back to a. Process ac is at constant pressure, process cb is adiabatic, and process ba is at constant volume. For process cb, 1. Q > 0, W > 0, and DU = 0 2. Q > 0, W > 0, and DU > 0 3. Q = 0, W > 0, and DU < 0 4. Q = 0, W < 0, and DU > 0 5. Q < 0, W > 0, and DU > 0

Q19.8 An ideal gas is taken around the cycle shown in this pV–diagram, from a to c to b and back to a. Process ac is at constant pressure, process cb is adiabatic, and process ba is at constant volume. For process ac, 1. Q > 0, W > 0, and DU = 0 2. Q > 0, W > 0, and DU > 0 3. Q = 0, W > 0, and DU < 0 4. Q = 0, W < 0, and DU > 0 5. Q < 0, W > 0, and DU > 0

A19.8 An ideal gas is taken around the cycle shown in this pV–diagram, from a to c to b and back to a. Process ac is at constant pressure, process cb is adiabatic, and process ba is at constant volume. For process ac, 1. Q > 0, W > 0, and DU = 0 2. Q > 0, W > 0, and DU > 0 3. Q = 0, W > 0, and DU < 0 4. Q = 0, W < 0, and DU > 0 5. Q < 0, W > 0, and DU > 0