Physics 161 Lecture 14 Kinetic Theory of Gas. October 18, 2018

Similar documents
Lecture 24. Ideal Gas Law and Kinetic Theory

Lecture 24. Ideal Gas Law and Kinetic Theory

17-1 Ideal Gases. Gases are the easiest state of matter to describe - All ideal gases exhibit similar behavior.

17-6 The Gas Laws and Absolute Temperature

Lecture PowerPoints. Chapter 13 Physics: Principles with Applications, 7 th edition Giancoli

Revision Guide for Chapter 13

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

Chapter 10. Thermal Physics

Lecture Outline Chapter 17. Physics, 4 th Edition James S. Walker. Copyright 2010 Pearson Education, Inc.

Chapter 15 Thermal Properties of Matter

Physics 1501 Lecture 35

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

Chapter 17 Temperature & Kinetic Theory of Gases 1. Thermal Equilibrium and Temperature

Rate of Heating and Cooling

Gases. Measuring Temperature Fahrenheit ( o F): Exceptions to the Ideal Gas Law. Kinetic Molecular Theory

(2) The volume of molecules is negligible in comparison to the volume of gas. (3) Molecules of a gas moves randomly in all direction.

Apparatus for Studying the Relationship Between Pressure and Volume of a Gas

Note: You will receive no credit for late submissions. To learn more, read your instructor's Grading Policy. The Ideal Gas Law Derived

Gases. Chapter 5. Copyright The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

14 The IDEAL GAS LAW. and KINETIC THEORY Molecular Mass, The Mole, and Avogadro s Number. Atomic Masses

10 TEMPERATURE, THERMAL EXPANSION, IDEAL GAS LAW, AND KINETIC THEORY OF GASES.

vapors: gases of substances that are normally liquids or solids 1 atm = 760 mm Hg = 760 torr = kpa = bar

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

Module 5: Rise and Fall of the Clockwork Universe. You should be able to demonstrate and show your understanding of:

Thermal Physics. Temperature (Definition #1): a measure of the average random kinetic energy of all the particles of a system Units: o C, K

CHAPTER 21 THE KINETIC THEORY OF GASES-PART? Wen-Bin Jian ( 簡紋濱 ) Department of Electrophysics National Chiao Tung University

Unit 3 - Part 2: Gas Laws. Objective - learn the main gas laws that all molecules follow.

Physics 231 Lecture 30. Main points of today s lecture: Ideal gas law:

Handout 11: Ideal gas, internal energy, work and heat. Ideal gas law

Temperature, Thermal Expansion and the Gas Laws

This should serve a s a study guide as you go on to do the problems in Sapling and take the quizzes and exams.

Quantitative Exercise 9.4. Tip 9/14/2015. Quantitative analysis of an ideal gas

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

Red Sox - Yankees. Baseball can not get more exciting than these games. Physics 121, April 17, Kinetic theory of gases.

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

Gas Laws. Gas Properties. Gas Properties. Gas Properties Gases and the Kinetic Molecular Theory Pressure Gas Laws

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

Gas Laws. Labs, Activities & Demonstrations:

Thermal Properties of Matter (Microscopic models)

CHEMISTRY Matter and Change. Chapter 13: Gases

ATMOS Lecture 3

HOMEWORK 11-1 (pp )

Chapter 14. The Ideal Gas Law and Kinetic Theory

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

A).5 atm B) 1 atm C) 1.5 atm D) 2 atm E) it is impossible to tell

CHEMISTRY NOTES Chapter 12. The Behavior of Gases

Chapter 14. The Ideal Gas Law and Kinetic Theory

Chapter 13: Temperature, Kinetic Theory and Gas Laws

The Gas Laws. Learning about the special behavior of gases

Moving Observer and Source. Demo 4C - 02 Doppler. Molecular Picture of Gas PHYSICS 220. Lecture 22. Combine: f o = f s (1-v o /v) / (1-v s /v)

Gases. What are the four variables needed to describe a gas?

Warm Up Questions: 1. Define temperature. 3. Draw and label the table on the board. well as the latent heat of fusion and vaporization.

Gases! n Properties! n Kinetic Molecular Theory! n Variables! n The Atmosphere! n Gas Laws!

19-9 Adiabatic Expansion of an Ideal Gas

18.13 Review & Summary

IMPORTANT CONCEPTS. 5.1 Pressure Units for pressure STP. 5.6 Kinetic Molecular Theory. 5.3 Ideal Gas Law. 5.4 Gas Stoichiometry Gas density Molar mass

Boyle s law states the relationship between the pressure and the volume of a sample of gas.

Why study gases? A Gas 10/17/2017. An understanding of real world phenomena. An understanding of how science works.

Gas laws. Relationships between variables in the behaviour of gases

Properties of Matter. Heat. Summary

Unit 2 review for finals

Chapter 11 Gases 1 Copyright McGraw-Hill 2009

10/16/2018. Why study gases? An understanding of real world phenomena. An understanding of how science works.

A Level Physics G484 PHYSICS DEPARTMENT. Assessment. Assessed with a 1 hour 15 minute, 60 mark paper where all questions are answered.

Serway_ISM_V1 1 Chapter 10. Thermal Physics. it would if filled with the material making up the rest of the object.

4. Find the average velocities and average accelerations of a particle moving in 1-D given its position at various times.

Worksheet 1.1. Chapter 1: Quantitative chemistry glossary

Ch. 19: The Kinetic Theory of Gases

STP : standard temperature and pressure 0 o C = 273 K kpa

PHYSICS - CLUTCH CH 19: KINETIC THEORY OF IDEAL GASSES.

Handout 11: Ideal gas, internal energy, work and heat. Ideal gas law

Chapter 17. Temperature. Dr. Armen Kocharian

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

density (in g/l) = molar mass in grams / molar volume in liters (i.e., 22.4 L)

Part One: The Gas Laws. gases (low density, easy to compress)

Gases. Section 13.1 The Gas Laws Section 13.2 The Ideal Gas Law Section 13.3 Gas Stoichiometry

Learning and Teaching Heat and Gases. Breath and Depth

Kinetic Molecular Theory and Gas Law Honors Packet. Name: Period: Date: Requirements for honors credit: Read all notes in packet

Chapter 14. The Ideal Gas Law and Kinetic Theory

Chapter 6 The States of Matter. Examples of Physical Properties of Three States of Matter

Gases and Gas Laws. Relationships of the Physical Properties of Gases. What is a gas?

States of Matter. The Solid State. Particles are tightly packed, very close together (strong cohesive forces) Low kinetic energy (energy of motion)

Atomic Mass and Atomic Mass Number. Moles and Molar Mass. Moles and Molar Mass

Engr. Yvonne Ligaya F. Musico Chemical Engineering Department

Unit 10: Gases. Section 1: Kinetic Molecular Theory and the Combined Gas Law

Process Nature of Process

C H E M 1 CHEM 101-GENERAL CHEMISTRY CHAPTER 5 GASES INSTR : FİLİZ ALSHANABLEH

Chapter 10 Notes: Gases

Physics 161 Lecture 17 Simple Harmonic Motion. October 30, 2018

KINETICE THEROY OF GASES

10/12/10. Chapter 16. A Macroscopic Description of Matter. Chapter 16. A Macroscopic Description of Matter. State Variables.

I. Gas Laws A. Four properties of gases 1. Volume - V

The Gas Laws. Types of Variation. What type of variation is it? Write the equation of the line.

10/15/2015. Why study gases? An understanding of real world phenomena. An understanding of how science works.

Gases, Liquids and Solids

11/22/11. If you add some heat to a substance, is it possible for the temperature of the substance to remain unchanged?

Chapter 6: The States of Matter

KINETIC MOLECULAR DESCRIPTION OF THE STATES OF MATTER

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

Conceptual Chemistry

Transcription:

Physics 161 Lecture 14 Kinetic Theory of Gas October 18, 2018 1

Exam 1, Thursday 18 Oct The exam will start promptly at 10:00pm. You will be permitted to open your exam at 10:00pm. You will have until 11:20pm to complete your exam. You must arrive five minutes early to find the exam that has your name (by section and alphabetic within section). DO NOT USE SOMEONE ELSES EXAM. The exam in some official lists may show to start at 9:40pm, because that is when we have been assigned the room. You will not be allowed to enter at that time, because we have to set up the room. Remember: no phones, no bags. If you are found with a phone during the exam, you will automatically receive a grade of 0% for the exam. 2

Exam-1 Topics (1) 1. Kinematic equations for constant acceleration: - one dimension - two dimensions - projectile motion 2. Newton s second law + third law 3. Friction and the normal force: - static friction - kinetic friction 4. Collisions - elastic - inelastic - perfectly inelastic 3

Exam-1 Topics (2) 5. Uniform circular motion - angular variables - angular-linear relations 6. Conservation of energy - kinetic energy - spring potential energy - gravitational potential energy - work done 7. Conservation of momentum - Collisions, elastic, inelastic, perfectly inelastic - impulse 4

Lecture 14: learning objectives Review from lecture 13 - Temperature, scales and how to measure. - Heat, internal energy, atomic/molecular picture. - Thermal expansion, specific heat, phase change. This lecture 14 We will state the properties of an ideal gas and apply the ideal gas law. A miracle that it works for all gases What are the assumptions of the kinetic theory of gases. We will relate the pressure and temperature to the average kinetic energy of atoms/molecules and define the internal energy of a gas. Sep. 1, 2015 5

Back to Problem: 11.39 10 gram of steam at 100 C is added to 50 gram of ice at 0 C. a)find the amount of ice melted and the final temperature. b)repeat with steam of mass 1.0 g and ice of mass 50 g. 6 Sep. 1, 2015

Problem: 11.39 Condense 10 gram steam at 100 o C produces 22,600 J Melting 50 gram of ice at 0 o C requires 16,500 J. We end up with 50 gram of 0 o C water + 10 gram of 100 o C water + (22,600 16,500) J CONCLUSION: Final state will be 60 gram of water of final temperature T f. Heat required = Heat produced 16,000 + c w 0.050 (T f 0) = c w 0.010 (100 T f ) + 22,600 7 Sep. 1, 2015

iclicker question: temperature What describes temperature best? -a) Energy transferred from one object to another. NO -b) Heat transferred from one object to another. NO -c) Work done by one object on another. NO +d) Measure of kinetic energy of atoms/molecules. YES? +e) Can you feel the temperature by touching (hot or cold). YES? 8 9/29/1 5

iclicker question: feel surfaces Which surface has the greater temperature? a) The metal surface. b) The plastic surface. c) The surfaces are at the same temperature. 9 9/29/1 5

iclicker question: ice melting On which surface will the ice melt first? a) The metal surface. b) The plastic surface. c) The ice will melt equally fast on both. 10 9/29/1 5

What are Ideal gases Ideal gas: System containing a (very) large number of widelyseparated point particles that interact only through perfectly elastic collisions. NO FRICTION, NO INELASTIC COLLISIONS Most real gases closely approximate an ideal gas 11

Avogadro s number, N A Avogadro s number: The number of particles in one mole of a substance. Avogadro s number is given by N A = 6.02 x 10 23 particles/mole Mole: One mole of any substance is that amount of the substance that contains as many particles (atoms, molecules) as there are atoms in 12 g of the isotope Carbon-12. What is the mass of one mole of He-4? 12

Ideal gas law (1) Ideal gas law: The product of the pressure P and volume V of an ideal gas is proportional to the number of moles n of gas times the Kelvin temperature T of the gas. Here R is the ideal gas constant, R = 8.31 J/ (mol.k) and n is the number of moles of gas. The Ideal gas law is an Equation of state that relates the pressure, volume and temperature of the gas. This follows from 3 experimental observations: - (1) gas pressure P is inversely proportional to volume V at fixed temperature (Boyle s law) - (2) volume V of the gas is proportional to the Kelvin temperature T at fixed pressure (Charles law) - (3) gas pressure P is directly proportional to the Kelvin 13 temperature T at fixed volume (Gay-Lussac s law)

Ideal gas law (2) Ideal gas law: The product of the pressure P and volume V of an ideal gas is proportional to the number of molecules N of gas times the Kelvin temperature T of the gas. Here R is the ideal gas constant, R = 8.31 J/ (mol.k) and n is the number of moles of gas. Here k B is Boltzmann s constant, k B = R/N A = 1.38 x 10-23 J/ K and N = n x N A is the number of molecules in the gas. The temperature T must be measured in Kelvin! 14

Problem: 10.35 Gas is confined in a tank at a pressure of 11.0 atm and a temperature of 25.0 C. If two-thirds of the gas is withdrawn and the temperature is raised to 75.0 C, what is the new pressure of the gas remaining in the tank? 15

Kinetic theory of gases The kinetic theory of gases is based on the following assumptions: 1. Number of molecules is large. 2. Molecules are separated by an average distance much larger than the molecular size. Molecules are treated as point particles. 3. Molecules obey Newton s laws of motion individually. 4. Molecules interact with each other only via shortrange forces during elastic collisions. 5. Molecules collide elastically with the container walls. 6. Molecules are all identical. 16

Pressure P and kinetic theory of gases MICROSCOPIC PICTURE: Pressure P of gas is caused by gas atoms knocking on the container wall Pressure in kinetic theory of gases: The pressure of an ideal gas is proportional to the number of molecules per unit volume, N/V, and to the average translational kinetic energy of a molecule. p. 338-339 17

Temperature in the kinetic theory of gases Temperature (in microscopic picture): The temperature of an ideal gas is a direct measure of the average molecular kinetic energy of the gas. p. 340 The total kinetic energy of N molecules is p. 341 18

Internal energy in the kinetic theory of gases Internal energy U in the kinetic theory of gases: The internal energy of a monatomic gas is given by the total kinetic energy of the molecules. p. 341 19

iclicker WHAT ARE THE UNITS OF PV a) Pa x m 3 b) N x m c) Joule d) All of the above 20

Root-mean-square speed Root-mean-square speed: The square root of the average of the speed-squared of each molecule. p. 341 Here M is the molar mass in kilograms per mole. 21

Problem: 10.46 Two gases in a mixture pass through a filter at rates proportional to the gases rms speeds. Find a) The ratio of speeds for the two isotopes of chlorine, 35 Cl and 37 Cl, as they pass through the filter. b) Which isotope moves faster? 22 9/29/1 5

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