Real vs. Ideal Gases (write all of this down)

Slides:

Advertisements

Similar presentations

The Ideal Gas Law PV = nRT.

Advertisements

The Ideal Gas Law. Review Recall the equation of the constant (k) for each law: Boyles Lawk B = PV Gay-Lussacs Lawk G = P/T Charless Lawk C = V/T Avogadros.

The Ideal Gas Law. What is an Ideal Gas? A gas that behaves according to the Kinetic Molecular Theory. It obeys all the postulates of KMT.

PV = nRT Ideal Gas Law P = pressure in atm V = volume in liters

Ch. 11 Molecular Composition of Gases

GASES Question 1: 1994 B Free Response

CHEMISTRY Matter and Change

Gases and the Kinetic Molecular Theory. Speeds of gas molecules. For a single molecule. Kinetic energy is: KE = ½ mv 2 m = mass; v = velocity For a collection.

Molecular Composition of Gases

Ideal Gas Law. Ideal Gases Ideal Gases –are at high temperatures and low pressures. –have no forces of attraction between particles. –Collide elastically.

TOPICS 1.Intermolecular Forces 2.Properties of Gases 3.Pressure 4.Gas Laws – Boyle, Charles, Lussac 5.Ideal Gas Law 6.Gas Stoichiometry 7.Partial Pressure.

III. Ideal Gas Law (p , ) Ch. 10 & 11 - Gases.

1 Chapter 11 Gases 11.8 The Ideal Gas Law Copyright © 2008 by Pearson Education, Inc. Publishing as Benjamin Cummings.

Basic Chemistry Copyright © 2011 Pearson Education, Inc. 1 Chapter 11 Gases 11.8 The Ideal Gas Law Basic Chemistry Copyright © 2011 Pearson Education,

Ideal Gas Law PV = nRT Brings together gas properties. Can be derived from experiment and theory.

Avogadro’s Law.

Gases Chapter – The Gas Laws Kinetic Theory = assumes that gas particles:  do not repel or attract each other  are much smaller than the distances.

= Let’s Build It… = If the temperature of the gases in the soda increase, what happens to the pressure inside the can?

Gases Chapter The Gas Laws: Kinetic Molecular Theory (Chapter 13): gases typically behave in a way that allows us to make assumptions in order.

Gas Laws. Gas Pressure ____________ is defined as force per unit area. Gas particles exert pressure when they ____________ with the walls of their container.

Avogadro’s Principle Gas particles = big, little, heavy, light Doesn’t matter = so far apart Therefore, a 1000 krypton (big) atoms occupy the same space.

Kinetic Molecular Theory

The Combined and Ideal Gas Laws Honors Chemistry.

Ideal Gas Law PV=nRT Kinetic Molecular Theory 1. Gases have low density 2. Gases have elastic collisions 3. Gases have continuous random motion. 4. Gases.

Lesson 4: Ideal Gas Law This lesson combines all the properties of gases into a single equation.

Chapter 13: Gases Sec. 13.2: The Ideal Gas Law. Objectives zRelate the amount of gas present to its pressure, temperature, & volume by using the ideal.

Ideal Gas Law & Gas Stoichiometry

Ideal Gas Law (Equation):

Chapter 13 Section 13.2 The Ideal Gas Law.

Ideal Gas Law & Gas Stoichiometry. Ideal Gas Law P V = n R T P = Pressure (atm) V = Volume (L) T = Temperature (K) n = number of moles R is a constant,

Section 13.2 Using Gas Laws to Solve Problems. Section 13.2 Using Gas Laws to Solve Problems 1.To understand the ideal gas law and use it in calculations.

Objectives To learn about atmospheric pressure and how barometers work

The Gas Laws The density of a gas decreases as its temperature increases.

Kinetic Theory of Gases 1. Gas particles do not attract or repel one another 2. Gas particles are much smaller than the distances between them.

Ideal vs. Real Gases No gas is ideal. As the temperature of a gas increases and the pressure on the gas decreases the gas acts more ideally.

Ideal Gas Law Chapter Ideal Gas Law The ideal gas law combines: –pressure –temperature –volume –# of particles (amount)

Ideal Gases. Ideal Gas vs. Real Gas Gases are “most ideal”… at low P & high T in nonpolar atoms/molecules Gases are “real”… Under low T & high P when.

1.Describe Law with a formula. 1.Describe Avogadro’s Law with a formula. 2.Use Law to determine either moles or volume 2.Use Avogadro’s Law to determine.

Chapter 11 The Behavior of Gases. Kinetic Theory Kinetic Theory – all molecules are in constant motion. –Collisions between gas molecules are perfectly.

Chapter 14 The Gas Laws Pages The Kinetic molecular theory that we talked about in the last is still valid. Gases are in constant random motion.

The Ideal Gas Law. Real Gas Behaviour There are several assumptions in the kinetic molecular theory that describe an ideal gas Gas molecules have zero.

Unit 1 Gases. Ideal Gases Objectives 1. Compute the value of an unknown using the ideal gas law. 2. Compare and contrast real and ideal gases.

Ideal Gases Ideal Gas Law Describes physical behavior of an ideal gas in terms of P, V, T, and n PV = nRT R = ideal gas constant = 8.31 (L∙kPa)/(K∙mol)

Relate number of particles and volume using Avogadro’s principle. mole: an SI base unit used to measure the amount of a substance; the amount of a pure.

Section 14.3 The Ideal Gas Law. Objectives  Relate the amount of gas present to its pressure, temperature, and volume by using ideal gas law  Compare.

IDEAL GAS LAW. Variables of a Gas We have already learned that a sample of gas can be defined by 3 variables:  Pressure  Volume  Temperature.

Ideal vs. Real Gases No gas is ideal. As the temperature of a gas increases and the pressure on the gas decreases the gas acts more ideally.

Chemistry – Chapter 14.  Kinetic Theory assumes the following concepts:  Gas particles don’t attract or repel each other  Gas particles are much smaller.

Ideal Gas Law Gases. C. Characteristics of Gases b Gases expand to fill any container. random motion, no attraction b Gases are fluids (like liquids).

Chapter Menu Gases Section 13.1Section 13.1The Gas Laws Section 13.2Section 13.2 The Ideal Gas Law Section 13.3Section 13.3 Gas Stoichiometry Exit Click.

Ideal Gases Ideal Gas Law Describes physical behavior of an ideal gas in terms of P, V, T, and n PV = nRT R = ideal gas constant = 8.31 (L∙kPa)/(K∙mol)

The Ideal Gas Law Ideal Gas  Follows all gas laws under all conditions of temperature and pressure.  Follows all conditions of the Kinetic Molecular.

Drill – 3/8/11 What are properties of gases? Write what you know about gases!

Gas Laws. Properties of Gases Particles far apart Particles move freely Indefinite shape Indefinite volume Easily compressed Motion of particles is constant.

Due: Gas Laws WS & book problems Today: Ideal Gases Molar Mass of a Gas HW Ideal Gas WS Prep Lab Notebook – Mass of a Volatile Liquid.

The Ideal Gas Law. The ideal gas law Relates pressure, temperature,volume, and the number of moles of a gas.

Ideal Gas Law CONTINUATION OF THE GAS LAWS. What is an ideal gas?  An ideal gas is a gas that behaves and follows the Kinetic Molecular Theory without.

Collisions with gas particles are elastic.

V. Combined and Ideal Gas Law

Happy Friday! Please do the following: pick up the handouts

To understand the Ideal Gas Law and use it in calculations

10.7 – NOTES Ideal Gas Laws.

PV = nRT Ideal Gas Law Ideal Gases Avogadro’s Principle Ideal Gas Law

The Ideal Gas Law.

Chapter 13: Gases.

Ideal Gases 14.3.

Presentation transcript:

Real vs. Ideal Gases (write all of this down) - An ideal gas is one who meets all the assumptions of the Kinetic molecular theory.. However, No gas is truly ideal. 1. All particles have some volume and there is some intermolecular attractions. 2. Despite that, most gases will behave like ideal gases at many temperatures and pressures. 3. Ideal Gas Law is not likely to work at extremely high pressures and low temperatures.. 4. Also polar gases (like water vapor) do not behave ideally because of the large intermolecular attractions.

Ideal Gas Law A. equation: PV = nRT I. The Ideal Gas Law shows the relationship between P, V, T and moles of gas (n) A. equation: PV = nRT 1. where R is the ideal gas constant R = 0.0821 atm L/mol K (this is a given value….it never changes). 2. P= pressure (atm) 3. V= volume (L) 3. n= Number of moles (mol) 4. T = temperature in Kelvin (K)

Example #1 1. Calculate the number of moles of gas contained in a 3.0 L container at 301 K with a pressure of 1.50 atm ?- you are solving for n (# of moles) * If you plug in the numbers given in the problem you will get: (1.50 atm)(3.0L) = n (0.0821 atm L/mol K)(301 K) Divide by 0.0821 atm L/mol K) and 301 K to get “n” by itself so your answer is….. n = 0.018 mol

Ways that I.G.L can be changed…. 1. Recall that moles (n) = m/M (where m = mass and M = molar mass) so substituting that into the Ideal Gas Law: PV = mRT M 2. Also, recall that density (D) = m/V, substituting that into the Ideal Gas Law and solving for the density gives: D = MP (molar mass X pressure) RT (I.G. constant x temperature