Lecture 24. Paths on the pv diagram

Similar documents
Physics 1501 Lecture 35

Chapter 11. Energy in Thermal Processes

Phase Changes and Latent Heat

Chapter 11. Important to distinguish between them. They are not interchangeable. They mean very different things when used in physics Internal Energy

Kinetic Theory continued

Chapter 17. Work, Heat, and the First Law of Thermodynamics Topics: Chapter Goal: Conservation of Energy Work in Ideal-Gas Processes

Kinetic Theory continued

PHYS102 Previous Exam Problems. Temperature, Heat & The First Law of Thermodynamics

Chapter 11. Energy in Thermal Processes

A thermodynamic system is taken from an initial state X along the path XYZX as shown in the PV-diagram.

Energy in Thermal Processes. Heat and Internal Energy

Lecture 25 Goals: Chapter 18 Understand the molecular basis for pressure and the idealgas

(Heat capacity c is also called specific heat) this means that the heat capacity number c for water is 1 calorie/gram-k.

Recap. There are 3 different temperature scales: Celsius, Kelvin, and Fahrenheit

Simpo PDF Merge and Split Unregistered Version -

Chapter 10 Temperature and Heat

11/13/2003 PHY Lecture 19 1

Temperature and Thermometers. Temperature is a measure of how hot or cold something is. Most materials expand when heated.

Chapter 14 Temperature and Heat

First Law of Thermodynamics Second Law of Thermodynamics Mechanical Equivalent of Heat Zeroth Law of Thermodynamics Thermal Expansion of Solids

Physics 5D PRACTICE FINAL EXAM Fall 2013

Lecture 22. Temperature and Heat

General Physics (PHY 2130)

Physics 121, April 24. Heat and the First Law of Thermodynamics. Department of Physics and Astronomy, University of Rochester

Physics 121, April 24. Heat and the First Law of Thermodynamics. Physics 121. April 24, Physics 121. April 24, Course Information

Physics Mechanics

CHAPTER 17 WORK, HEAT, & FIRST LAW OF THERMODYNAMICS

Chapter 12. Temperature and Heat. continued

Chapter 14 Heat. Lecture PowerPoints. Chapter 14 Physics: Principles with Applications, 7 th edition Giancoli

Physics 231. Topic 13: Heat. Alex Brown Dec 1, MSU Physics 231 Fall

Honors Physics. Notes Nov 16, 20 Heat. Persans 1

Chapter 19: The Kinetic Theory of Gases Questions and Example Problems

AP PHYSICS 2 WHS-CH-14 Heat Show all your work, equations used, and box in your answers! 1 108kg

Physics 207 Lecture 25. Lecture 25, Nov. 26 Goals: Chapter 18 Understand the molecular basis for pressure and the idealgas

6. (6) Show all the steps of how to convert 50.0 F into its equivalent on the Kelvin scale.

Conduction is the transfer of heat by the direct contact of particles of matter.

Chapter 18 Temperature, Heat, and the First Law of Thermodynamics. Thermodynamics and Statistical Physics

Thermodynamics Test Wednesday 12/20

A) 2.0 atm B) 2.2 atm C) 2.4 atm D) 2.9 atm E) 3.3 atm

1. How much heat was needed to raise the bullet to its final temperature?

Thermodynamics. Atoms are in constant motion, which increases with temperature.

18.13 Review & Summary

2,000-gram mass of water compared to a 1,000-gram mass.

Physics 231. Topic 14: Laws of Thermodynamics. Alex Brown Dec MSU Physics 231 Fall

Distinguish between an isothermal process and an adiabatic process as applied to an ideal gas (2)

CHAPTER 19: Heat and the First Law of Thermodynamics

CHAPTER 3 TEST REVIEW

Physics 2: Fluid Mechanics and Thermodynamics

Lecture PowerPoints. Chapter 14 Physics: Principles with Applications, 6 th edition Giancoli

Heat Transfer. Phys101 Lectures 33, 34. Key points: Heat as Energy Transfer Specific Heat Heat Transfer: Conduction, Convection, Radiation.

Three special ideal gas processes: one of, W or Q is 0

Assess why particular characteristics are necessary for effective conduction KEY POINTS

Physics 111. Lecture 36 (Walker: ) Heat Capacity & Specific Heat Heat Transfer. May 1, Quiz (Chaps. 14 & 16) on Wed.

2012 Thermodynamics Division C

The Kinetic Theory of Gases

7. (2) Of these elements, which has the greatest number of atoms in a mole? a. hydrogen (H) b. oxygen (O) c. iron (Fe) d. gold (Au) e. all tie.

Matter exchange - type of wall Yes - permeable - absence of wall. Energy exchange - type of wall. - diathermic - moving wall. Yes

Chapter 14 Temperature and Heat

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

Thermal energy. Thermal energy is the internal energy of a substance. I.e. Thermal energy is the kinetic energy of atoms and molecules.

Tells us the average translational kinetic energy of the particles

Temperature. Temperature Scales. Temperature (cont d) CHAPTER 14 Heat and Temperature

Speed Distribution at CONSTANT Temperature is given by the Maxwell Boltzmann Speed Distribution

There are four phases of matter: Phases of Matter

International Academy Invitational Tournament Keep the Heat Test Team Name. Team Number. Predicted Water Temp C

Temperature Thermal Expansion Ideal Gas Law Kinetic Theory Heat Heat Transfer Phase Changes Specific Heat Calorimetry Heat Engines

Agenda. Chapter 10, Problem 26. All matter is made of atoms. Atomic Structure 4/8/14. What is the structure of matter? Atomic Terminology

Thermal Physics. Topics to be covered. Slide 2 / 105. Slide 1 / 105. Slide 3 / 105. Slide 4 / 105. Slide 5 / 105. Slide 6 / 105.

High temperature He is hot

Physics 2: Fluid Mechanics and Thermodynamics

Bernoulli s Principle. Application: Lift. Bernoulli s Principle. Main Points 3/13/15. Demo: Blowing on a sheet of paper

S15--AP Phys Q4--Heat-Thermo Ch13_14_15 PRACTICE

Chapters 17 &19 Temperature, Thermal Expansion and The Ideal Gas Law

The First Law of Thermodynamics

Thermodynamics. Thermodynamics is the study of the collective properties of a system containing many bodies (typically of order 10 23!

Handout 10: Heat and heat transfer. Heat capacity

A) 3.1 m/s B) 9.9 m/s C) 14 m/s D) 17 m/s E) 31 m/s

Chapter: Heat and States

Energy, Temperature, & Heat. Energy, Temperature, & Heat. Temperature Scales 1/17/11

Heat and Temperature

UNIVERSITY COLLEGE LONDON. University of London EXAMINATION FOR INTERNAL STUDENTS. For The Following Qualifications:-

Thermodynamics I - Enthalpy

Chapter 10. Thermal Physics. Thermodynamic Quantities: Volume V and Mass Density ρ Pressure P Temperature T: Zeroth Law of Thermodynamics

Thermodynamics and Energy. First Law of Thermodynamics and Energy Transfer Mechanisms. Applications of Thermodynamics

TEMPERATURE. 8. Temperature and Heat 1

Preview. Heat Section 1. Section 1 Temperature and Thermal Equilibrium. Section 2 Defining Heat. Section 3 Changes in Temperature and Phase

Physics 111. Lecture 34 (Walker 17.2,17.4-5) Kinetic Theory of Gases Phases of Matter Latent Heat

SPH3U1 Lesson 03 Energy

Zeroth Law of Thermodynamics

Thermal Equilibrium. Zeroth Law of Thermodynamics 2/4/2019. Temperature

AAST/AEDT AP PHYSICS B: HEAT

PHYSICS. Chapter 20 Lecture 4/E FOR SCIENTISTS AND ENGINEERS A STRATEGIC APPROACH RANDALL D. KNIGHT Pearson Education, Inc.

Chapter 15 Thermal Properties of Matter

Understanding KMT using Gas Properties and States of Matter

Lesson 12. Luis Anchordoqui. Physics 168. Tuesday, November 28, 17

Chapter 1 - Temperature and Heat

Thermal Conductivity, k

Handout 12: Thermodynamics. Zeroth law of thermodynamics

Chapter 2 Heat, Temperature and the First Law of Thermodynamics

PHYSICS 149: Lecture 26

Transcription:

Goals: Lecture 24 Chapter 17 Apply heat and energy transfer processes Recognize adiabatic processes Chapter 18 Follow the connection between temperature, thermal energy, and the average translational kinetic energy molecules Understand the molecular basis for pressure and the idealgas law. To predict the molar specific heats of gases and solids. Assignment HW10, Due Wednesday 9:00 AM For Thursday, Read through all of Chapter 18 Physics 207: Lecture 24, Pg 1 Paths on the p diagram (4) Isobaric (3) Isothermal (2) Isochoric (1) Adiabatic W = - p???? W = 0???? p 2 4 3 1 T 1 T 2 Ideal gas T 4 T 3 Physics 207: Lecture 24, Pg 2 Page 1

Isothermal processes Work done when P = nrt = constant P = nrt / W W = = final initial f i p d nrt = (area under curve) d / = nrt f i d / W = nrt ln( / ) f i p 3 T 1 T 2 T 3 T 4 Physics 207: Lecture 24, Pg 3 Adiabatic Processes An adiabatic process is process in which there is no thermal energy transfer to or from a system (Q = 0) A reversible adiabatic process involves a worked expansion in which we can return all of the energy transferred. In this case P γ = const. All real processes are not. p 2 4 3 1 T 1 T 2 T 4 T 3 Physics 207: Lecture 24, Pg 4 Page 2

Work and Ideal Gas Processes (on system) Isothermal W = nrt ln( / ) f i Isobaric W Isochoric W = p = 0 ( f - ) FYI: Adiabatic (and reversible) W 2 = Pd = 1 i 2 1 const γ d = const γ γ γ ( 2 1 Physics 207: Lecture 24, Pg 5 ) Combinations of Isothermal & Adiabatic Processes All engines employ a thermodynamic cycle W = ± (area under each p curve) W cycle = area shaded in turquoise Watch sign of the work! Physics 207: Lecture 24, Pg 6 Page 3

Relationship between energy transfer and T Physics 207: Lecture 24, Pg 7 Heat and Latent Heat Latent heat of transformation L is the energy required for 1 kg of substance to undergo a phase change. (J / kg) Q = ±ML Specific heat c of a substance is the energy required to raise the temperature of 1 kg by 1 K. (Units: J / K kg ) Q = M c T Molar specific heat C of a gas at constant volume is the energy required to raise the temperature of 1 mol by 1 K. Q = n C T If a phase transition involved then the heat transferred is Q = ±ML+M c T Physics 207: Lecture 24, Pg 8 Page 4

Q : Latent heat and specific heat The molar specific heat of gasses depends on the process path C = molar specific heat at constant volume C p = molar specific heat at constant pressure C p = C +R (R is the universal gas constant) γ = C p C Physics 207: Lecture 24, Pg 9 Mechanical equivalent of heat Heating liquid water: Q = amount of heat that must be supplied to raise the temperature by an amount T. [Q] = Joules or calories. 1 Cal = 4.186 J 1 kcal = 1 Cal = 4186 J calorie: energy to raise 1 g of water from 14.5 to 15.5 C (James Prescott Joule found the mechanical equivalent of heat.) Sign convention: +Q : heat gained - Q : heat lost Physics 207: Lecture 24, Pg 10 Page 5

Exercise The specific heat (Q = M c T) of aluminum is about twice that of iron. Consider two blocks of equal mass, one made of aluminum and the other one made of iron, initially in thermal equilibrium. Heat is added to each block at the same constant rate until it reaches a temperature of 500 K. Which of the following statements is true? (a) The iron takes less time than the aluminum to reach 500 K (b) The aluminum takes less time than the iron to reach 500 K (c) The two blocks take the same amount of time to reach 500 K Physics 207: Lecture 24, Pg 11 Heat and Ideal Gas Processes (on system) Isothermal Expansion/Contraction E Th = 0 = W + Q Q = W Isobaric Q = nc T = n( C + R) T p Isochoric Q = nc T Adiabatic Q = 0 Physics 207: Lecture 24, Pg 12 Page 6

Two process are shown that take an ideal gas from state 1 to state 3. Compare the work done by process A to the work done by process B. A. W A > W B B. W A < W B C. W A = W B = 0 D. W A = W B but neither is zero ON BY A 1 3 W 1 2 = 0 (isochoric) B 1 2 W 1 2 = -½ (p 1 +p 2 )( 2-1 ) < 0 -W 1 2 > 0 B 2 3 W 2 3 = -½ (p 2 +p 3 )( 1-2 ) > 0 -W 2 3 < 0 B 1 3 = ½ (p 3 - p 1 )( 2-1 ) > 0 < 0 Physics 207: Lecture 24, Pg 13 Exercise Latent Heat Most people were at least once burned by hot water or steam. Assume that water and steam, initially at 100 C, are cooled down to skin temperature, 37 C, when they come in contact w ith your skin. Assume that the steam condenses extremely fast, and that the specific heat c = 4190 J/ kg K is constant for both liquid water and steam. Under these conditions, which of the following statements is true? (a) Steam burns the skin worse than hot water because the thermal conductivity of steam is much higher than that of liquid water. (b) Steam burns the skin worse than hot water because the latent heat of vaporization is released as well. (c) Hot water burns the skin worse than steam because the thermal conductivity of hot water is much higher than that of steam. (d) Hot water and steam both burn skin about equally badly. Physics 207: Lecture 24, Pg 14 Page 7

Energy transfer mechanisms Thermal conduction (or conduction) Convection Thermal Radiation For a material of cross-section area A and length L, spanning a temperature difference T = T H T C, the rate of heat transfer is Q / t = k A T / x where k is the thermal conductivity, which characterizes whether the material is a good conductor of heat or a poor conductor. Physics 207: Lecture 24, Pg 15 Energy transfer mechanisms Thermal conduction (or conduction): Energy transferred by direct contact. e.g.: energy enters the water through the bottom of the pan by thermal conduction. Important: home insulation, etc. Rate of energy transfer ( J / s or W ) Through a slab of area A and thickness x, with opposite faces at different temperatures, T c and T h Q / t = k A (T h - T c ) / x k :Thermal conductivity (J / s m C) Physics 207: Lecture 24, Pg 16 Page 8

Thermal Conductivities Aluminum J/s m C J/s m C J/s m C 238 Air 0.0234 Asbestos 0.25 Copper 397 Helium 0.138 Concrete 1.3 Gold 314 Hydrogen 0.172 Glass 0.84 Iron 79.5 Nitrogen 0.0234 Ice 1.6 Lead 34.7 Oxygen 0.0238 Water 0.60 Silver 427 Rubber 0.2 Wood 0.10 Physics 207: Lecture 24, Pg 17 Home Exercise Thermal Conduction Two identically shaped bars (one blue and one green) are placed between two different thermal reservoirs. The thermal conductivity coefficient k is twice as large for the blue as the green. You measure the temperature at the joint between the green and blue bars. 100 C T joint 300 C Which of the following is true? (A) T top > T bottom (B) T top = T bottom (C) T top < T bottom (D) need to know k Physics 207: Lecture 24, Pg 18 Page 9

Home Exercise Thermal Conduction Two identically shaped bars (one blue and one green) are placed between two different thermal reservoirs. The thermal conductivity coefficient k is twice as large for the blue as the green. 100 C T joint 300 C Top: P green = P blue = Q / t = 2 k A (T high - T j ) / x= k A (T j - T low ) / x 2 (T high - T j ) = (T j - T low ) 3 T j(top) = 2 T high T low By analogy for the bottom: 3 T j(bottom) = 2 T low T high 3 (T j(top) - T j(bottom ) = 3 T high 3 T low > 0 (A) T top > T bottom Physics 207: Lecture 24, Pg 19 Exercise Thermal Conduction Two thermal conductors (possibly inhomogeneous) are butted together and in contact with two thermal reservoirs held at the temperatures shown. Which of the temperature vs. position plots below is most physical? 100 C (A) (B) (C) 300 C Temperature Position Temperature Position Temperature Position Physics 207: Lecture 24, Pg 20 Page 10

Energy transfer mechanisms Convection: Energy is transferred by flow of substance 1. Heating a room (air convection) 2. Warming of North Altantic by warm waters from the equatorial regions Natural convection: from differences in density Forced convection: from pump of fan Radiation: Energy is transferred by photons e.g.: infrared lamps Stefan s Law P = σ A e T 4 (power radiated) σ = 5.7 10-8 W/m 2 K 4, T is in Kelvin, and A is the surface area e is a constant called the emissivity Physics 207: Lecture 24, Pg 21 Minimizing Energy Transfer The Thermos bottle, also called a Dewar flask is designed to minimize energy transfer by conduction, convection, and radiation. The standard flask is a double-walled Pyrex glass with silvered walls and the space between the walls is evacuated. acuum Silvered surfaces Hot or cold liquid Physics 207: Lecture 24, Pg 22 Page 11

Anti-global warming or the nuclear winter scenario Assume P/A = I = 1340 W/m 2 from the sun is incident on a thick dust cloud above the Earth and this energy is absorbed, equilibrated and then reradiated towards space where the Earth s surface is in thermal equilibrium with cloud. Let e (the emissivity) be unity for all wavelengths of light. What is the Earth s temperature? P = σ A T 4 = σ (4π r 2 ) T 4 = I π r 2 T = [I / (4 x σ )] ¼ σ = 5.7 10-8 W/m 2 K 4 T = 277 K (A little on the chilly side.) Physics 207: Lecture 24, Pg 23 Ch. 18, Macro-micro connection Molecular Speeds and Collisions A real gas consists of a vast number of molecules, each moving randomly and undergoing millions of collisions every second. Despite the apparent chaos, averages, such as the average number of molecules in the speed range 600 to 700 m/s, have precise, predictable values. The micro/macro connection is built on the idea that the macroscopic properties of a system, such as temperature or pressure, are related to the average behavior of the atoms and molecules. Physics 207: Lecture 24, Pg 24 Page 12

Molecular Speeds and Collisions A view of a Fermi chopper Physics 207: Lecture 24, Pg 25 Molecular Speeds and Collisions Physics 207: Lecture 24, Pg 26 Page 13

Mean Free Path If a molecule has N coll collisions as it travels distance L, the average distance between collisions, which is called the mean free path (lowercase Greek lambda), is Physics 207: Lecture 24, Pg 27 Macro-micro connection Assumptions for ideal gas: # of molecules N is large They obey Newton s laws Short-range interactions with elastic collisions Elastic collisions with walls (an impulse..pressure) What we call temperature T is a direct measure of the average translational kinetic energy What we call pressure p is a direct measure of the number density of molecules, and how fast they are moving (v rms ) v 2 T = ε 3 rms k B p = = 2 3 avg N ε 2 ( v ) avg avg = 3k BT m Physics 207: Lecture 24, Pg 28 Page 14

Lecture 24 Assignment HW10, Due Wednesday (9:00 AM) Tuesday review Reading assignment through all of Chapter 18 Physics 207: Lecture 24, Pg 29 Page 15

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback