Thermodynamics: The Kinetic Theory of Gases

Similar documents
(1) The size of a gas particle is negligible as compared to the volume of the container in which the gas is placed.

momentum change per impact The average rate of change of momentum = Time interval between successive impacts 2m x 2l / x m x m x 2 / l P = l 2 P = l 3

Statistical Mechanics, Kinetic Theory Ideal Gas. 8.01t Nov 22, 2004

THE IDEAL GAS LAW AND KINETIC THEORY

HEAT UNIT 1.1 KINETIC THEORY OF GASES Introduction Postulates of Kinetic Theory of Gases

Kinetic Theory: Atomic and Molecular Explanation of Pressure and Temperature

CLASSICAL CONCEPT REVIEW 8

CHAPTER 12. Gases and the Kinetic-Molecular Theory

CHEMISTRY. Matter and Change. Section 13.1 Section 13.2 Section The Gas Laws The Ideal Gas Law Gas Stoichiometry

PHYS-2010: General Physics I Course Lecture Notes Section XIII

Gas Laws. Heat and Temperature

Gases. States of Matter. Molecular Arrangement Solid Small Small Ordered Liquid Unity Unity Local Order Gas High Large Chaotic (random)

Gas Laws. The kinetic theory of matter states that particles which make up all types of matter are in constant motion.

The Gas Laws. Our Atmosphere. Pressure = Units of Pressure. Barometer. Chapter 10

Kinetic Theory of Gases. Chapter 33. Kinetic Theory of Gases

Lecture Notes: Gas Laws and Kinetic Molecular Theory (KMT).

10.7 Kinetic Molecular Theory Kinetic Molecular Theory. Kinetic Molecular Theory. Kinetic Molecular Theory. Kinetic Molecular Theory

Boyles Law. At constant temperature the volume occupied by a fixed amount of gas is inversely proportional to the pressure on the gas 1 P = P

Kinetic Theory of Gases

EXPERIMENT 15: Ideal Gas Law: Molecular Weight of a Vapor

19 The Kinetic Theory of Gases

Kinetic Theory & Ideal Gas

Chemistry 13: States of Matter

Topic 3b: Kinetic Theory

A. Kinetic Molecular Theory (KMT) = the idea that particles of matter are always in motion and that this motion has consequences.

F321 MOLES. Example If 1 atom has a mass of x g 1 mole of atoms will have a mass of x g x 6.02 x = 7.

Kinetic Molecular Theory of Matter

THE KINETIC THEORY OF GASES

Thermodynamics AP Physics B. Multiple Choice Questions

= atm. 760 mm Hg. = atm. d. 767 torr = 767 mm Hg. = 1.01 atm

CHEMISTRY GAS LAW S WORKSHEET

AS1 MOLES. oxygen molecules have the formula O 2 the relative mass will be 2 x 16 = 32 so the molar mass will be 32g mol -1

TEMPERATURE AND PRESSURE OF AN IDEAL GAS: THE EQUATION OF STATE MISN THE EQUATION OF STATE by William C. Lane Michigan State University

13.1 The Nature of Gases. What is Kinetic Theory? Kinetic Theory and a Model for Gases. Chapter 13: States of Matter. Principles of Kinetic Theory

1 Introduction. Taking the logarithm of both sides of Equation 1.1:

Vacuum Technology. Kinetic Theory of Gas. Dr. Philip D. Rack

Gases and Kinetic-Molecular Theory: Chapter 12. Chapter Outline. Chapter Outline

Temperature. Number of moles. Constant Terms. Pressure. Answers Additional Questions 12.1

Episode 603: Kinetic model of an ideal gas

Study the following diagrams of the States of Matter. Label the names of the Changes of State between the different states.

KINETIC MOLECULAR THEORY OF MATTER

Chapter 12 Kinetic Theory of Gases: Equipartition of Energy and Ideal Gas Law

CHEM 120 Online Chapter 7

Chapter 29: Kinetic Theory of Gases: Equipartition of Energy and the Ideal Gas Law

IDEAL AND NON-IDEAL GASES

Kinetic Molecular Theory and Gas Laws

Name Class Date. In the space provided, write the letter of the term or phrase that best completes each statement or best answers each question.

States of Matter CHAPTER 10 REVIEW SECTION 1. Name Date Class. Answer the following questions in the space provided.

A drop forms when liquid is forced out of a small tube. The shape of the drop is determined by a balance of pressure, gravity, and surface tension

Exam 4 Practice Problems false false

= 800 kg/m 3 (note that old units cancel out) J 1000 g = 4184 J/kg o C

Thermodynamics: Lecture 8, Kinetic Theory

atm = 760 torr = 760 mm Hg = kpa = psi. = atm. = atm. = 107 kpa 760 torr 1 atm 760 mm Hg = 790.

1. The Kinetic Theory of Matter states that all matter is composed of atoms and molecules that are in a constant state of constant random motion

_CH06_p qxd 1/20/10 9:44 PM Page 69 GAS PROPERTIES PURPOSE

Gas Laws. vacuum. 760 mm. air pressure. mercury

10.7 Kinetic Molecular Theory Kinetic Molecular Theory. Kinetic Molecular Theory. Kinetic Molecular Theory. Kinetic Molecular Theory

Type: Single Date: Kinetic Theory of Gases. Homework: Read (14.1), Do CONCEPT Q. # (1), Do PROBLEMS # (2, 3, 5) Ch. 14

Properties of Gases. Dr Claire Vallance First year, Hilary term. Suggested Reading

ENERGY CONSERVATION The First Law of Thermodynamics and the Work/Kinetic-Energy Theorem

Indiana's Academic Standards 2010 ICP Indiana's Academic Standards 2016 ICP. map) that describe the relationship acceleration, velocity and distance.

Boyle s law - For calculating changes in pressure or volume: P 1 V 1 = P 2 V 2. Charles law - For calculating temperature or volume changes: V 1 T 1

CHEMISTRY STANDARDS BASED RUBRIC ATOMIC STRUCTURE AND BONDING

SAM Teachers Guide Heat and Temperature

Temperature, Energy and Heat, Ideal Gas Law & Kinetic Theory, Thermodynamics

Lecture 14 Chapter 19 Ideal Gas Law and Kinetic Theory of Gases. Chapter 20 Entropy and the Second Law of Thermodynamics

Chapter 13 - Chemical Equilibrium

AP CHEMISTRY 2009 SCORING GUIDELINES (Form B)

State Newton's second law of motion for a particle, defining carefully each term used.

CHEMISTRY 113 EXAM 4(A)

Chemistry 110 Lecture Unit 5 Chapter 11-GASES

Preview of Period 5: Thermal Energy, the Microscopic Picture

The Mole. Chapter 10. Dimensional Analysis. The Mole. How much mass is in one atom of carbon-12? Molar Mass of Atoms 3/1/2015

CHEM 1211K Test IV. MULTIPLE CHOICE (3 points each)

Gases. Macroscopic Properties. Petrucci, Harwood and Herring: Chapter 6

Chem 1A Exam 2 Review Problems

Unit 3: States of Matter Practice Exam

Molar Mass of Butane

DETERMINING THE MOLAR MASS OF CARBON DIOXIDE

EXPERIMENT 13: THE IDEAL GAS LAW AND THE MOLECULAR WEIGHT OF GASES

KINETIC THEORY AND THERMODYNAMICS

Problem Set 3 Solutions

Phys222 W11 Quiz 1: Chapters Keys. Name:

Chapter 8: Gases and Gas Laws.

Module P7.3 Internal energy, heat and energy transfer

Work and Energy. Work = Force Distance. Work increases the energy of an object. Energy can be converted back to work.

ESSAY. Write your answer in the space provided or on a separate sheet of paper.

Mole Notes.notebook. October 29, 2014

7. Gases, Liquids, and Solids 7.1 Kinetic Molecular Theory of Matter

Temperature Measure of KE At the same temperature, heavier molecules have less speed Absolute Zero -273 o C 0 K

Chapter 13 Gases. Review Skills

Unit 3 Notepack Chapter 7 Chemical Quantities Qualifier for Test

Forms of Energy. Freshman Seminar

HAVE A BLAST FINDING MOLAR MASS An Ideal Gas Experiment. Contents:

Entropy and the Kinetic Theory: the Molecular Picture

Test 5 Review questions. 1. As ice cools from 273 K to 263 K, the average kinetic energy of its molecules will

Thermodynamics. Chapter 13 Phase Diagrams. NC State University

We know from the information given that we have an equal mass of each compound, but no real numbers to plug in and find moles. So what can we do?

PV (0.775 atm)( L) n = = = mol RT -1-1

KINETIC THEORY OF GASES AND THERMODYNAMICS SECTION I Kinetic theory of gases

Transcription:

Thermodynamics: The Kinetic Theory of Gases Resources: Serway The Kinetic Theory of Gases: 10.6 AP Physics B Videos Physics B Lesson 5: Mechanical Equivalent of Heat Physics B Lesson 6: Specific and Latent Heat Physics B Lesson 7: Heat Transfer and Thermal Expansion MIT CourseWare 3: Thermal Expansion 33: Ideal-Gas Law

Kinetic Theory of Gases The ideal gas law provides no insight as to how pressure and temperature are related to properties of the gas molecules themselves (such as their masses or speeds). To understand this, we have to look at the dynamics of the molecular motion.

The Kinetic Molecular Model The IDEAL Gas Law PV = nrt Boyle s Law P 1 V 1 = P V at constant n and T Charles s Law V 1 / T 1 = V / T at constant n and P The General Gas Law P 1 V 1 / T 1 = P V / T at constant n These are all useful law s, they accurately express observable and repeatable behaviors. But they DO NOT EXPLAIN the cause.

The Kinetic Molecular Model Welcome to the Kinetic Molecular Model This model attempts to explain the behavior of gas molecules at the microscopic level. The previous laws were developed at the macroscopic level. Solid carbon dioxide, known as dry ice, passes directly into a gaseous state at room temperature.

The Kinetic Molecular Model -Assumptions This model is built on the following assumptions: 1. The number of molecules is large, and the average separation between them is large. The molecules occupy negligible volume in the container.. The molecules obey Newton s laws of motion, but as a whole they move randomly. 3. The molecules undergo elastic collisions with each other and with the container. 4. The forces between molecules is negligible except during a collision. 5. The gas is a pure substance.

The Kinetic Molecular Model - Derivation Recall, momentum is the product of an object s mass and velocity, p = mv Consider a molecule of gas moving inside a container of length, L colliding with its walls: p x = p f,x p i,x = mv f,x (-mv i,x ) = mv x The wall of the container exerts a force causing p: p x = F t (Impulse-Momentum Theorem) F = p x / t F = mv x / t Remember v x, v x = x / t t = x / v x

Gas Molecules Simulation http://intro.chem.okstate.edu/1314f00/laboratory/glp.htm

The Kinetic Molecular Model - Derivation Substituting t, F = mv x / t = (mv x ) / ( x / v x ) Referring back to the container of length, L: x = L F = (mv x ) / (L / v x ) = mv x / L Restating, F = mv x / L Recall the definition of pressure, P = F / A P = (mv x / L) / L P = mv x / L 3 P = mv x / V

The Kinetic Molecular Model - Derivation Recall, P = mv x / V All N molecules in the container follow this behavior, P = Nmv x / V Expanding to all directions (x, y, z) and true randomness predicts that: v x = v y = v z And v av = v x + v y + v z Therefore, v x = 1/3 v av

The Kinetic Molecular Model - Derivation Recall, P = Nmv x / V Substituting, v x = 1/3 v av P = 1/3 Nmv av / V Recall, KE = 1/ mv av KE = mv av P = 1/3 N(KE) / V P = /3 NKE / V PV = /3 NKE

The Kinetic Molecular Model - Derivation Recall, PV = /3 NKE Recall, PV = Nk B T Combining, Nk B T = /3 NKE Algebraic magic KE = 3/ k B T A direct connection between Temperature and Kinetic Energy!!!

The Kinetic Molecular Model - Derivation Recall, K avg = 3/ k B T Combining, 1/ mv av = 3/ k B T v av = 3 k B T / m Taking the square root of both sides, v av = 3kT / m v av is called the Root Mean Square v av = v RMS v RMS = 3k B T / m = 3RT / M m = µ = mass of molecule M = molar mass

The Kinetic Molecular Model The kinetic molecular model predicts that the temperature of an object is a measurement of its average molecular kinetic energy! The kinetic molecular model also predicts that pressure is a direct result of repeated molecular collisions with a container! Root mean squared speed is used due to the

The Kinetic Molecular Model Important equations: v RMS = 3k B T / m = 3RT / M K avg = 3/ k B T PV = /3 NKE P = mv x / V These equations are the foundation of everything you studied in chemistry. Chemistry observes the behavior, Physics explains the cause! m = µ = mass of molecule M = molar mass

Summary Kinetic Molecular Theory Where, K v avg rms = 3 k T B 3RT 3kBT = = M µ K avg : average kinetic energy of a gas molecule (J) T: temperature (K) v rms : root-mean-square speed of a gas molecule (m/s) M: molar mass µ: mass of molecule k B : Boltzman s constant = 1.38 x 10-3 J/K R: universal gas constant = 8.31 J/(mol K)

Practice Problem What is the average kinetic energy and the average speed of oxygen molecules in a gas sample at 0 o C? Given: T= 0 o C Find: KE =? v =? Solution: To find KE we ll need to apply the kinetic molecular model, KE = 3/ k B T But first we ll have to convert the temperature to kelvins, T = 73 K Recall Boltzman s constant, k B = 1.38 x 10-3 J/K KE = (3/)(1.38 x 10-3 J/K )(73 K) = 5.65 x 10-1 J Solution: To find v, we ll need to apply the rms speed equation v RMS = (3kBT / m) = (3RT / M) We ll need either the molar mass or mass of the oxygen molecule (O ). M = x Atom Weight = x 16 = 3 g/mol = 0.03 kg/mol) v RMS = (3RT / M) = [(3)(8.31)(73)]/(0.03) v RMS = 461. m/s

2024 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information