Presentation is loading. Please wait.

Presentation is loading. Please wait.

PHY1039 Properties of Matter van der Waals Gas 16 February, 2012 Lecture 4.

Published byBarbara Nash Modified over 9 years ago

Similar presentations

Presentation on theme: "PHY1039 Properties of Matter van der Waals Gas 16 February, 2012 Lecture 4."— Presentation transcript:

1 PHY1039 Properties of Matter van der Waals Gas 16 February, 2012 Lecture 4

2 Boltzmann Distribution of Molecular Speeds in a Gas Figure from “Understanding Properties of Matter” by M. de Podesta

3 Boltzmann Distribution of Speeds in a Gas Figure from “Understanding Properties of Matter” by M. de Podesta Average speed increases as a function of T 1/2 At a given T, lighter molecules have a higher average speed.

4 Types of Thermodynamic Wall P 1 V 1 T 1 P 2 V 2 T 2 P 1 V 1 T 1 Time P 2 V 2 T 2 No change in the state variables. P 1 V 1 T 1 P 2 V 2 T 2 P 1 eq V 1 T eq Time P 2 eq V 2 T eq State variables change over time. The temperature on either side of the wall is at an equilibrium value, T eq. System 1 System 2

5 No Gas Is Ideal ! Constant P Constant TConstant V V P P V TT V T High P Low P P Low V High V

6 Potential Energy for Non-Charged Atoms/Molecules r  r  Potential Energy There is also kinetic energy, which is the energy of motion. Figure from “Understanding Properties of Matter” by M. de Podesta ~ r -6 Relevant to gases, liquids and solids (e.g. Ar, Xe, CO 2 ) Potential energy: Force between molecules:

7 van der Waals Parameters of Selected Gases Gas a (L 2 atm. mol -2 ) b (L mol -1 ) Air1.40.039 Ammonia4.170.037 Argon1.350.032 Carbon Dioxide3.590.043 Ethane5.490.064 Helium0.0340.024 Hydrogen0.2440.027 Nitrogen1.390.039 Oxygen1.360.032 Xenon4.190.051

8 it.wikipedia.org/wiki/Legge_di_Van_der_Waals PV diagram for CO 2 n = 1 V (dm 3 ) P (kPa) 1 atm.  101 kPa

9 Phase Diagram of CO 2 Gas condenses when attractive intermolecular bond energies are comparable to or greater than thermal (i.e. kinetic) energy, 3/2 kT. Image: http://wps.prenhall.com/wps/media/objects/602/616516/Chapter_10.html

Download ppt "PHY1039 Properties of Matter van der Waals Gas 16 February, 2012 Lecture 4."

Similar presentations

KMT, Graham’s Law & Real Gases

KMT, Graham’s Law & Real Gases
Chapter 11 Liquids and Intermolecular Forces

Chapter 11 Liquids and Intermolecular Forces
GASES Question 1: 1994 B Free Response

GASES Question 1: 1994 B Free Response
Unit 6 – Some Review Questions

Unit 6 – Some Review Questions
Chemical Thermodynamics 2013/2014 2 nd Lecture: Zeroth Law, Gases and Equations of State Valentim M B Nunes, UD de Engenharia.

Chemical Thermodynamics 2013/ nd Lecture: Zeroth Law, Gases and Equations of State Valentim M B Nunes, UD de Engenharia.
I. Kinetic Molecular Theory KMT. Assumptions of KMT All matter is composed of tiny particles These particles are in constant, random motion. Some particles.

I. Kinetic Molecular Theory KMT. Assumptions of KMT All matter is composed of tiny particles These particles are in constant, random motion. Some particles.
Unit 10 States of Matter and Gases. Phase Changes A phase change is a change in the state of matter During a phase change there is no change in temperature.

Unit 10 States of Matter and Gases. Phase Changes A phase change is a change in the state of matter During a phase change there is no change in temperature.
Ideal Gases and the Compressibility Factor 1 mol, 300K for various gases A high pressure, molecules are more influenced by repulsive forces. V real.

Ideal Gases and the Compressibility Factor 1 mol, 300K for various gases A high pressure, molecules are more influenced by repulsive forces. V real.
Chapter 13: States of Matter Kinetic-Molecular Theory: Explains the motions and behavior of a gas. The theory has three components: 1. Particle Size: Gas.

Chapter 13: States of Matter Kinetic-Molecular Theory: Explains the motions and behavior of a gas. The theory has three components: 1. Particle Size: Gas.
Boltzmann Distribution of Speeds in a Gas As a result of momentum transfer during collisions between gas molecules and between molecules and the container.

Boltzmann Distribution of Speeds in a Gas As a result of momentum transfer during collisions between gas molecules and between molecules and the container.
PHY 231 1 PHYSICS 231 Lecture 26: Ideal gases Remco Zegers Walk-in hour: Thursday 11:30-13:30 am Helproom.

PHY PHYSICS 231 Lecture 26: Ideal gases Remco Zegers Walk-in hour: Thursday 11:30-13:30 am Helproom.
PHY 231 1 PHYSICS 231 Lecture 24: Ideal gases Remco Zegers Walk-in hour:Tue 4-5 pm Helproom.

PHY PHYSICS 231 Lecture 24: Ideal gases Remco Zegers Walk-in hour:Tue 4-5 pm Helproom.
Thermal Properties of Matter

Thermal Properties of Matter
Chapter 10 PHYSICAL CHARACTERISTICS OF GASES

Chapter 10 PHYSICAL CHARACTERISTICS OF GASES
Gases Chapter 5 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Gases Chapter 5 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Real gases 1.4 Molecular interactions 1.5 The van de Waals equation 1.6 The principle of corresponding states Real gases do not obey the perfect gas law.

Real gases 1.4 Molecular interactions 1.5 The van de Waals equation 1.6 The principle of corresponding states Real gases do not obey the perfect gas law.
 Describe the image  ◦ What is it? ◦ What does it measure? ◦ How does it work?

 Describe the image  ◦ What is it? ◦ What does it measure? ◦ How does it work?
Intermolecular Forces © 2009, Prentice-Hall, Inc. Evaporation, Vapor Pressure, and Intermolecular Forces John D. Bookstaver St. Charles Community College.

Intermolecular Forces © 2009, Prentice-Hall, Inc. Evaporation, Vapor Pressure, and Intermolecular Forces John D. Bookstaver St. Charles Community College.
Chemistry AP/IB Dr. Cortes

Chemistry AP/IB Dr. Cortes
 The average kinetic energy (energy of motion ) is directly proportional to absolute temperature (Kelvin temperature) of a gas  Example  Average energy.

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

Similar presentations

Ads by Google