The Behavior of Gases Chapter 12. The Nature of Gases Kinetic energy – the energy of motion. Kinetic theory states that tiny particles in all forms of.

Slides:



Advertisements
Similar presentations
GASES! AP Chapter 10. Characteristics of Gases Substances that are gases at room temperature tend to be molecular substances with low molecular masses.
Advertisements

Not so long ago, in a chemistry lab far far away… May the FORCE/area be with you.
The Gaseous State Chapter 5.
Chemistry I Unit 9: The Gas Laws Text Questions from Wilbraham, et. al
Ch Gases Properties: Gases are highly compressible and expand to occupy the full volume of their containers. Gases always form homogeneous mixtures.
Chapter 10 Gases No…not that kind of gas. Kinetic Molecular Theory of Gases Kinetic Molecular Theory of Gases – Based on the assumption that gas molecules.
1 Chapter 12 The Behavior of Gases. 2 Section 12.1 The Properties of Gases u OBJECTIVES: Describe the properties of gas particles.
Energy and Gases Kinetic energy: is the energy of motion. Potential Energy: energy of Position or stored energy Exothermic –energy is released by the substance.
1 Chapter 12 The Behavior of Gases Milbank High School.
Gases.  Define pressure, give units of pressure, and describe how pressure is measured.  State the standard conditions of temperature and pressure and.
Chapter 13: Gases. What Are Gases? Gases have mass Gases have mass.
1 Gases Chapter Properties of Gases Expand to completely fill their container Take the Shape of their container Low Density –much less than solid.
Gas Laws. Properties of Gases 1. Fluids 2. Low density 3. Highly compressible 4. Completely fill a container and exert pressure in all directions.
Chapter 13 Gases. Chapter 13 Table of Contents Copyright © Cengage Learning. All rights reserved Pressure 13.2 Pressure and Volume: Boyle’s Law.
 The average kinetic energy (energy of motion ) is directly proportional to absolute temperature (Kelvin temperature) of a gas  Example  Average energy.
Gases Notes A. Physical Properties: 1.Gases have mass. The density is much smaller than solids or liquids, but they have mass. (A full balloon weighs.
GAS LAWS. Behavior of Gases Gases can expand to fill their container Gases can be compressed –Because of the space between gas particles Compressibility:
1 Gases Chapter Properties of Gases Expand to completely fill their container Take the Shape of their container Low Density –much less than solid.
Chapter 11 Gases.
The Behavior of Gases Chapter 12. The Nature of Gases Kinetic energy – the energy of motion. Kinetic theory states that tiny particles in all forms of.
Characteristic of Gases
1 Chapter 14 Gases Pioneer High School Ms. Julia V. Bermudez.
1 Physical Characteristics of Gases Chapter Kinetic-molecular theory Particles of matter are always in motion.
We NEED Air to Breathe!!! Gases form homogeneous mixtures with each other regardless of the identities or relative proportions of the component gases Air.
Zumdahl Zumdahl DeCoste
Gas Laws.
Gas Laws Chapter 5. Pressure Force per unit area Measured in Atmospheres (atm) Mm of Hg = Torr Pascals or kiloPascals (Pa or kPa)
13.1 Pressure- force exerted over an area
The Behavior of Gases AW Chapter 10, section 1 and Chapter 12.
GAS LAWS. Properties of Gases  Composed of randomly scattered particles  No definite _________ or ___________  Spread out to fill the space of their.
Unit 5: Gases and Gas Laws. Kinetic Molecular Theory  Particles of matter are ALWAYS in motion  Volume of individual particles is  zero.  Collisions.
Molecules in Motion A.the kinetic theory all matter is composed of small particles (atoms, ions, molecules) these small particles are in constant motion.
The Behavior of Gases Ch. 12.
Copyright©2004 by Houghton Mifflin Company. All rights reserved. 1 Introductory Chemistry: A Foundation FIFTH EDITION by Steven S. Zumdahl University of.
Gases.  State the kinetic-molecular theory of matter, and describe how it explains certain properties of matter.  List the five assumptions of the kinetic-
You can predict how pressure, volume, temperature, and number of gas particles are related to each other based on the molecular model of a gas.
Chapter 5: Gases 5.1 Pressure. Gaseous State of Matter  has no distinct or __________ so fills any container  is easily compressed  completely with.
Chapter 12: States Of Matter
Prentice Hall © 2003Chapter 10 Chapter 10 Gases CHEMISTRY The Central Science 9th Edition David P. White.
Chapters 10 and 11: Gases Chemistry Mrs. Herrmann.
Chapter 14: The Behavior of Gases
Starter S-146 List five properties of gases.. The Behavior of Gases Chapter 14.
Gases Unit 6. Kinetic Molecular Theory  Kinetic energy is the energy an object has due to its motion.  Faster object moves = higher kinetic energy 
Chapter 10- Gases What are the characteristics of gases? Variable shape Variable volume The atmosphere is composed of gases. The two major components.
Chapter 101 Gases. 2 Homework: 10.12, 10.28, 10.42, 10.48, 10.54, 10.66,
KINETIC MOLECULAR THEORY Physical Properties of Gases: Gases have mass Gases are easily compressed Gases completely fill their containers (expandability)
Gases. Ê A Gas is composed of particles ä usually molecules or atoms ä Considered to be hard spheres far enough apart that we can ignore their volume.
States of Matter and Gases Unit 9. The States of Matter Solid: material has a definite shape and definite volume Solid: material has a definite shape.
Gases. Kinetic Theory of Gases Explains Gas behavior: 4 parts: 1) Gas particles do not attract or repel each other (no I.M. forces).
States of Matter and Gases Unit 8. The States of Matter Solid: material has a definite shape and definite volume Solid: material has a definite shape.
Chapter 13 Calculating Gases 1 Section 12.1 Pressure + Temperature conversions, Dalton’s + Graham’s Laws Section 13.1 The Gas Laws Section 13.2 The Ideal.
GASES Chapters 13 and 14. Nature of Gases  Kinetic Molecular Theory (KMT)  Kinetic energy- the energy an object has because of its motion  According.
Gas Laws Wasilla High School Kinetic Molecular Theory and Gas Behavior  The word kinetic refers to motion.  The energy an object has because.
The Property of Gases – Kinetic Molecular Theory explains why gases behave as they do
Properties of Gases Kinetic Molecular Theory: 1.Small particles (atoms or molecules) move quickly and randomly 2.Negligible attractive forces between particles.
 Gas particles are much smaller than the distance between them We assume the gas particles themselves have virtually no volume  Gas particles do not.
The Properties of Gases Chapter 12. Properties of Gases (not in Notes) Gases are fluids… Fluid: (not just to describe liquids)  can describe substances.
Ch. 12 The Behavior of Gases Ch The Properties of Gases Ch Factors Affecting Gas Pressure Ch The Gas Laws Ch Ideal Gases Ch
Prentice Hall © 2003Chapter 10 Chapter 10 Gases CHEMISTRY The Central Science 9th Edition.
Chemistry Chapter 5 Gases Dr. Daniel Schuerch. Gas Pressure Gas pressure is the result of simultaneous collisions of billions of rapidly moving particles.
Gases Boyle’s Law. As the volume of a gas increases, the pressure decreases. –Temperature remains constant.
Gases Section 1 – Properties of Gases Section 2 – Gas Laws, and Gas Stoichiometry Section 3 – Kinetic Molecular Theory.
1. If you have 4.00 moles of hydrogen gas at 27°C and kPa of pressure, what is the volume? 2. Also, get your notes out on your desk. Day
Chapter 14 Gas Behavior.
Chapter 14: The Behavior of Gases
Gases Ideal Gas Law.
Chapter Eleven Gases.
#1. Gas is composed of particles- usually molecules or atoms
Gases Chapter 13-1.
The Behavior of Gases The word kinetic refers to motion
Presentation transcript:

The Behavior of Gases Chapter 12

The Nature of Gases Kinetic energy – the energy of motion. Kinetic theory states that tiny particles in all forms of matter are in constant motion.

The Properties of Gases The kinetic molecular theory of gases explains why gases act and behave in particular ways. Kinetic Molecular Theory 1. A gas is composed of particles, usually molecules or atoms. These particles are small, hard spheres that have an insignificant volume and are relatively far apart from one another. There are no attractive or repulsive forces that exist between gas particles.

The Properties of Gases 2.Particles in a gas move in constant, rapid motion. They travel in straight paths, and move independently of one another. Gas particles change direction only when they rebound from a collision with one another or with other objects. The uninterrupted path of a gas in a straight line is very short. The aimless path of gas molecules is called a random walk.

The Properties of Gases 3.All collisions are perfectly elastic. This means that energy is transferred without loss from one particle to another and the total kinetic energy remains constant. Gas pressure – force exerted by a gas per unit surface area of an object. If no gas particles are present, then there is no pressure, and it is considered to be a vacuum.

The Nature of Gases Kinetic Energy and Kelvin Temperature When a substance is heated the particles of the substance absorb energy, which is stored as potential energy. The temperature of the substance does not change as a result of the potential energy, but the average kinetic energy increases, which results in an increase in temperature.

The Nature of Gases When particles collide they have a wide range of kinetic energies, from very low to very high. Most particles kinetic energy is somewhere in the middle. Average kinetic energy – used to describe the kinetic energy of a group of gas particles.

The Nature of Gases At high temperature there is a wider range of kinetic energies. When the temperature is low, the range of kinetic energies of molecules is very small or short. Increasing average kinetic energy makes temperature increase and molecules move faster and have more collisions. Decreasing average kinetic energy makes temperature decrease and molecules move slower and have fewer collisions.

Distribution of Molecular Speeds

The Nature of Gases Absolute zero (0 K, -273 o C, -454 o F) – particles will have no kinetic energy and therefore no motion at all. Kelvin temperature of a substance is directly proportional to the average kinetic energy of that substance. At a given temperature, the particles of all substances, not just gases, have the same average kinetic energy.

The Nature of Gases Atmospheric pressure – results from the collision of air molecules with objects. Atmospheric pressure decreases as you climb mountains because the air layer around the Earth thins out as elevation increases. Barometers – devices used to measure atmospheric pressure.

Figure 12.2: When a glass tube is filled with mercury and inverted in a dish of mercury at sea level, the mercury flows out of the tube until a column approximately 760 mm high remains.

A device (called a manometer) for measuring the pressure of a gas in a container.

The Nature of Gases Pascal (Pa) – SI unit from pressure, but more commonly the kilopascal (kPa) is used. At sea level, the atmospheric pressure is kPa. Other commonly used pressure units are millimeters of Mercury (mm Hg) and atmospheres. Standard atmospheric pressure (1 atm) = 760 mm Hg=101.3 kPa=760 torr=29.92 in Hg

1 atm = 760 mm Hg 1 atm = kPa 1 atm = 760 torr 1 atm = inches Hg 1 kPa = 1000 Pa

The Nature of Gases Convert 825 mm Hg to atm Convert 1.07 atm to kPa Convert 125 kPa to torr Convert 8.20 x 10 6 Pa to inches of Hg

Factors Effecting Gas Pressure Amount of Gas By adding a gas to a container, you increase the number of collisions of gas particles, and therefore increase the pressure, as long as the temperature stays the same. Letting air out of a container at constant temperature decreases the pressure, because there are fewer gas particles, creating fewer collisions.

Factors Effecting Gas Pressure Volume Gas pressure can be increased by decreasing the volume of a container. Gas pressure can be decreased by increasing the volume of a container.

Factors Effecting Gas Pressure Temperature Raising the temperature of an enclosed container increases pressure because particles move around at a faster rate and produce more collisions, which increases the pressure. Lowering the temperature decreases pressure because particles are not moving as fast and not producing as many collisions, which decreases the pressure.

The Gas Laws Boyle’s Law (Pressure-Volume Relationship) If temperature and the amount of gas are held constant, then pressure and volume are inversely proportional. If one goes up, the other one goes down by the same proportion from their starting points, and vice versa. Boyle’s Law equation: P 1 V 1 = P 2 V 2

Boyle's Experiment

Figure 12.5: A plot of P versus V from Boyle’s data in Table 12.1.

Figure 12.6: Illustration of Boyle’s law.

The Gas Laws A gas initially has a volume of 10.5 L at 1.64 atm. What will the volume be when the pressure doubles, at constant temperature? Calculate the final pressure of a gas (in kPa) when the volume of the container increases from 250 mL to 1.0 L. The gas is initially at 3.75 atm. Assume constant temperature.

The Gas Laws Charles’s Law (Volume-Temperature Relationship) If pressure and the amount of gas are held constant, then volume and Kelvin temperature are directly proportional. If one goes up, the other goes up by the same proportion. The ratio of the two quantities is constant. Charles’s Law equation: V 1 /T 1 = V 2 /T 2

Effect of temperature on volume of gas. A balloon immersed in liquid nitrogen shrinks. Source: Photo by James Scherer. © Houghton Mifflin Company. All rights reserved.

Effect of temperature on volume of gas. Balloon removed from liquid nitrogen, it expands to its original size. Source: Photo by James Scherer. © Houghton Mifflin Company. All rights reserved.

Figure 12.7: Plots of V (L) versus T (°C) for several gases.

Linear Relationship of Gas Volume & Temperature at Constant Pressure

The Gas Laws A gas with a volume of 400 mL at 150. o C is heated until its volume is 6.0 L. What is the new temperature, in K, of the gas if the pressure remains constant? A balloon is inflated to a volume of 1.25 L in a room at 298 K. What is final volume, in mL, if the temperature decreases to -20 o C while the pressure remains constant?

Model of the Temperature-volume Relationship for a Gas at a Fixed Pressure

The Gas Laws Gay-Lussac’s Law (Pressure-Temperature Relationship) If volume and the amount of gas are held constant, then pressure and Kelvin temperature are directly proportional. If one goes up, the other goes up by the same proportion. The ratio of the two quantities is constant. Gay-Lussac’s Law equation: P 1 /T 1 = P 2 /T 2

The Gas Laws A mass of air has a pressure of 0.25 atm at 101 o C. What will the temperature be if the pressure is increased to 750 mm Hg while the volume remains constant? A sealed cylinder of gas contains nitrogen gas at 1.00 x 10 3 kPa pressure and 20 o C. What is the new pressure if the gas temperature increases to 55 o C? Assume the volume of the container is held constant.

Avogadro’s Law Volume directly proportional to the number of gas molecules –V = constant x n (moles) –Constant P and T –More gas molecules = larger volume Count number of gas molecules by moles One mole of any ideal gas occupies 22.4 L at standard conditions - molar volume Equal volumes of gases contain equal numbers of molecules –It doesn’t matter what the gas is!

Avogadro’s Law Examples A mol sample of chlorine gas (Cl 2 ) has a volume of 9.4L. What is the volume of the gas when the amount of gas changes to 125 grams of Cl 2 at constant temperature and pressure? If moles of N 2 gas is in a 100. mL container, how many moles of N2 could be in the container at the same temperature and pressure if the volume of the container expanded to 2.5 L?

The Gas Laws Combined Gas Law The combined gas law combines Boyle’s, Charles’s and Gay-Lussac’s laws into one statement, where the amount of gas is the only thing that is held constant. Combined Gas Law equation: P 1 V 1 = P 2 V 2 T 1 T 2

The Gas Laws Remember that you must have all temperatures in Kelvin and the volume and pressure units must be the same. STP means pressure is equal to 1 atm and temperature is 0 o C or 273 K.

The Gas Laws Calculate the volume (in liters) of a gas present at STP, if the gas starts off with a volume of 225 mL at 123 kPa and 25 o C. A container of O 2 gas has a volume of 2.4 L at 25 o C and 1.13 atm. What is o C when the volume is 850 mL and pressure is 92 kPa?

The Gas Laws Ideal Gas Law (PV = nRT) P = pressure, in atm V = volume, in L or dm 3 n = number of moles, in moles R = ideal gas constant, L atm/K mol or L kPa/K mol T = temperature, in K

The Gas Laws You can solve this equation for any of the variables, when given the other three, not including R. The units must be the same as the R to put it into the ideal gas law equation. If not then you must convert each unit first before putting it into the equation.

The Gas Laws What is the volume, in mL, of moles of a gas that is at 940 mm Hg and 25 o C? How many grams of N 2 O gas are present in a 750 mL container at 12 o C and 115 kPa?

Gas Molecules: Mixtures and Movements Particles of different gases are different sizes because they differ in their number of protons, electrons and neutrons. Avogadro’s hypothesis – equal volumes of gases at the same temperature and pressure contain equal numbers of particles.

Gas Molecules: Mixtures and Movements At STP, 1 mol of any gas particles, regardless of the size of the particles, occupies a volume of 22.4 L. Equal numbers of particles of different gases in equal volume at the same temperature should exert the same pressure because the particles have the same average kinetic energy and are contained with equal volumes.

Gas Molecules: Mixtures and Movements Dalton’s Law Gas pressure only depends on the number of gas particles in a given volume and on their average kinetic energy. If you know the pressure exerted by each gas in a mixture, you can determine the total pressure of the gas.

Gas Molecules: Mixtures and Movements Dalton’s law of partial pressures – at constant volume and temperature, the total pressure exerted by a mixture of gas is equal to the sum of the partial pressures of the component gases. P total = P 1 + P 2 + P 3 + … Partial pressure of a gas is the pressure that the gas would exert if it were alone in the container.

An illustration of Dalton’s law of partial pressures.

When two gases are present, the total pressure is the sum of the partial pressures of the gases.

Gas Molecules: Mixtures and Movements Calculate the total pressure of a mixture of gases where the partial pressures are: 425 mm Hg of O 2, 215 mm Hg of N 2 and 240 mm Hg of CO 2. Calculate the partial pressure of N 2 gas in a mixture of N 2, CO 2 (P CO2 = 350 mm Hg) and O 2 (P O2 = 185 mm Hg). The total pressure of the mixture is 825 mm Hg.

Gas Molecules: Mixtures and Movements Gases Collected Over Water A mixture of gases occurs when a gas is collected by displacement of water. You must take into account the water vapor pressure in the mixture. The partial pressure of water depends on the water temperature.

Collection of gas over water

Gas Molecules: Mixtures and Movements The total pressure of a mixture of oxygen gas and water vapor is 784 mm Hg. What is the partial pressure of oxygen gas if the gas was collected over water at 25 o C?

The total pressure of a mixture of gases depends on the number of moles of gas particles (atoms or molecules) present, not on the identities of the particles.

Gas Molecules: Mixtures & Movements A mixture of gases contains 4.25 g H 2, 16.0 g O 2, and 17.5 g of CO 2. What is the total pressure of the gases if they are in a 5.85 L container at 20.0 o C?

Gas Molecules: Mixtures & Movements A sample of hydrogen gas is collected over at 35 o C. The wet gas occupies a volume of 2.6 L at a total pressure of 792 mm Hg. If all the water is removed, what will the volume of the dry hydrogen occupy at a pressure of 760 mm Hg and a temperature of 20. o C?

Gas Molecules: Mixtures and Movements Graham’s Law of Effusion Diffusion – tendency of molecules to move toward areas of lower concentration until the concentration is uniform throughout. Effusion – process in which a gas escapes through a tiny hole in a container.

Gaseous Effusion

Gas Molecules: Mixtures and Movements Graham’s law of effusion – rate of effusion of a gas is inversely proportional to the square root of the gas’s molar mass. Rate 2 = √Molar mass #1 Rate 1 √ Molar mass #2 This relationship is also true for the diffusion of a gas. Could also be written as: Rate 1 x √ Molar mass #1 = Rate 2 x √ Molar Mass #2

Gas Molecules: Mixtures and Movements A gas with a smaller molar mass diffuses and effuses at a faster rate than a gas with a high molar mass. If gases have the same kinetic energy, the lighter gas moves faster. Rates must be an amount of gas (1 mol for example) divided by a period of time (1 minute for example), not just an amount of time

Gas Molecules: Mixtures and Movements The rate of effusion of a certain number of moles of SO 2 gas was 75 seconds. Under the same conditions, it took an unknown gas 52 seconds for the same number of moles of gas to effuse. Determine the molar mass of the unknown gas.

Gas Molecules: Mixtures and Movements The rate of effusion of a certain number of moles of N 2 O gas was 3 times faster than that of an unknown gas. Determine the molar mass of the unknown gas.

Gas Molecules: Mixtures and Movements 0.50 moles of O 2 gas effuses through a small opening in 37 seconds. How long will it take the same number of moles of methane, CH 4, to effuse through the same opening?

Gas Stoichiometry Hydrogen gas is produced when zinc reacts with hydrochloric acid: Zn (s) + 2 HCl (aq)  ZnCl 2(aq) + H 2(g) If 358 mL of wet H 2 is collected over water at 22 o C and a total pressure of 738 mm Hg, how many grams of Zn have been consumed?

Gas Stoichiometry Nitric acid is produced from nitric oxide, NO, which in turn is prepared from ammonia by the Ostwald process: 4 NH 3(g) + 5O 2(g)  4NO (g) + 6H 2 O (l) What volume of oxygen at 35 o C and 2.15 atm is needed to produce 50.0 grams of nitric oxide?