Chapter 10 Gases

Lecture Presentation Chapter 10Gases

Gases 10.1 CHARACTERISTICS OF GASES 10.2 PRESSURE 10.3 THE GAS LAWS 10.4 THE IDEAL-GAS EQUATION 10.5 FURTHER APPLICATIONS OF THEIDEAL-GAS EQUATION 10.6 GAS MIXTURES AND PARTIAL PRESSURES 10.7 THE KINETIC-MOLECULAR THEORY OF GASES 10.8 MOLECULAR EFFUSION AND DIFFUSION 10.9 REAL GASES: DEVIATIONS FROM IDEAL BEHAVIOR

10.1: Characteristics of Gases • Unlike liquids and solids, gases • Expand to fill their containers. • Are highly compressible. • Have extremely low densities.

Gases • In the gas state, the particles have complete freedom of motion and are not held together • The particles are constantly flying around, bumping into each other and the container • There is a large amount of space between the particles • compared to the size of the particles • therefore the molar volume of the gas state of a material is much larger than the molar volume of the solid or liquid states

Gases • Because there is a lot of empty space, the particles can be squeezed closer together – therefore gases are compressible • Because the particles are not held in close contact and are moving freely, gases expand to fill and take the shape of their container, and will flow

F A P = 10.2: Pressure • Pressure is the amount of force applied to an area: • Atmospheric pressure is the weight of air per unit of area.

Units of Pressure • Pascals • 1 Pa = 1 N/m2 • Bar • 1 bar = 105 Pa = 100 kPa

The Pressure of a Gas • Gas pressure is a result of the constant movement of the gas molecules and their collisions with the surfaces around them • The pressure of a gas depends on several factors • number of gas particles in a given volume • volume of the container • average speed of the gas particles

gravity Measuring Air Pressure • We measure air pressure with abarometer • Column of mercury supported by air pressure • Force of the air on the surface of the mercury counter balances the force of gravity on the column of mercury

Units of Pressure • mmHg or torr • These units are literally the difference in the heights measured in mm (h) of two connected columns of mercury. • Atmosphere • 1.00 atm = 760 torr

Manometer The manometer is used to measure the difference in pressure between atmospheric pressure and that of a gas in a vessel.

Manometer for this sample, the gas has a larger pressure than the atmosphere, so

Practice – What happens to the height of the column of mercury in a mercury barometer as you climb to the top of a mountain? • The height of the column increases because atmospheric pressure decreases with increasing altitude • The height of the column decreases because atmospheric pressure decreases with increasing altitude • The height of the column decreases because atmospheric pressure increases with increasing altitude • The height of the column increases because atmospheric pressure increases with increasing altitude • The height of the column increases because atmospheric pressure decreases with increasing altitude • The height of the column decreases because atmospheric pressure decreases with increasing altitude • The height of the column decreases because atmospheric pressure increases with increasing altitude • The height of the column increases because atmospheric pressure increases with increasing altitude

Standard Pressure • Normal atmospheric pressure at sea level is referred to as standard pressure. • It is equal to • 1.00 atm • 760 torr (760 mmHg) • 101.325 kPa • 1 atm = 14.7 psi (pounds per square inch

psi atm mmHg Example1: A high-performance bicycle tire has a pressure of 132 psi. What is the pressure in mmHg? Given: Find: 132 psi mmHg Conceptual Plan: Relationships: 1 atm = 14.7 psi, 1 atm = 760 mmHg Solution: Check: because mmHg are smaller than psi, the answer makes sense

psi atm kPa Practice—Convert 45.5 psi into kPa Given: Find: 645.5 psi kPa Conceptual Plan: Relationships: 1 atm = 14.7 psi, 1 atm = 101.325 kPa Solution: Check: because kPa are smaller than psi, the answer makes sense

10.3 :The Gas Laws • Four Variables are need to define state of a gas • temperature (T) • pressure (P) • volume (V) • number of moles(n) • We examine several gas laws, which are empirical relationships among these four variables

Standard Conditions • Because the volume of a gas varies with pressure and temperature, chemists have agreed on a set of conditions to report our measurements so that comparison is easy – we call these standard conditions • STP • Standard pressure = 1 atm • Standard volume 22.4 L • Standard temperature = 273 K • 0 °C

Boyle’s Law Robert Boyle (1627–1691) The volume of a fixed quantity of gas at constant temperature is inversely proportional to the pressure.

Boyle’s Experiment • Added Hg to a J-tube with air trapped inside • Used length of air column as a measure of volume

Since V = k (1/P) This means a plot of V versus 1/P will be a straight line. PV = k P and V are Inversely Proportional • P1V1= P2V2 A plot of V versus P results in a curve.

Boyle’s Law Robert Boyle (1627–1691) • Pressure of a gas is inversely proportional to its volume • constant T and amount of gas • graph P vs V is curve • graph P vs 1/V is straight line • As P increases, V decreases by the same factor • P x V = constant • P1 x V1 = P2 x V2

V1, P1, P2 V2 Example 2: A cylinder with a movable piston has a volume of 7.25 L at 4.52 atm. What is the volume at 1.21 atm? Given: Find: V1 =7.25 L, P1 = 4.52 atm, P2 = 1.21 atm V2, L Conceptual Plan: Relationships: P1∙ V1 = P2∙ V2 Solution: Check: because P and V are inversely proportional, when the pressure decreases ~4x, the volume should increase ~4x, and it does

Practice – A balloon is put in a bell jar and the pressure is reduced from 782 torr to 0.500 atm. If the volume of the balloon is now 2.78 x 103 mL, what was it originally?

V2, P1, P2 V1 A balloon is put in a bell jar and the pressure is reduced from 782 torr to 0.500 atm. If the volume of the balloon is now 2.78x 103 mL, what was it originally? Given: Find: V2 =2780 mL, P1 = 762 torr, P2 = 0.500 atm V1, mL Conceptual Plan: Relationships: P1∙ V1 = P2∙ V2 , 1 atm = 760 torr (exactly) Solution: Check: because P and V are inversely proportional, when the pressure decreases ~2x, the volume should increase ~2x, and it does

Charles’s Law • The volume of a fixed amount of gas at constant pressure is directly proportional to its absolute temperature.

V T = k • So, • A plot of V versus T will be a straight line. Charles’s Law

Charles’s Law Jacques Charles (1746–1823) • Volume is directly proportional to temperature • constant P and amount of gas • graph of V vs. T is straight line • As T increases, V also increases • Kelvin T = Celsius T + 273 • V = constant x T • if T measured in Kelvin

V1, V2, T2 T1 Example 3: A gas has a volume of 2.57 L at 0.00 °C. What was the temperature at 2.80 L? Given: Find: V1 =2.57 L, V2 = 2.80 L, t2 = 0.00 °C t1, K and °C Conceptual Plan: Relationships: Solution: Check: because T and V are directly proportional, when the volume decreases, the temperature should decrease, and it does

Practice – The temperature inside a balloon is raised from 25.0 °C to 250.0 °C. If the volume of cold air was 10.0 L, what is the volume of hot air?

The temperature inside a balloon is raised from 25.0 °C to 250.0 °C. If the volume of cold air was 10.0 L, what is the volume of hot air? V1, T1, T2 V2 Given: Find: V1 =10.0 L, t1 = 25.0 °C L, t2 = 250.0 °C V2, L Conceptual Plan: Relationships: Solution: Check: when the temperature increases, the volume should increase, and it does

V = kn • Mathematically, this means Avogadro’s Law • The volume of a gas at constant temperature and pressure is directly proportional to the number of moles of the gas.

Avogadro’s Law Amedeo Avogadro (1776–1856) • Volume directly proportional to the number of gas molecules • V = constant x n • constant P and T • more gas molecules = larger volume • Count number of gas molecules by moles • Equal volumes of gases contain equal numbers of molecules • the gas doesn’t matter

V1, V2, n1 n2 Example 4:A 0.225 mol sample of He has a volume of 4.65 L. How many moles must be added to give 6.48 L? Given: Find: V1 = 4.65 L, V2 = 6.48 L, n1 = 0.225 mol n2, and added moles Conceptual Plan: Relationships: Solution: Check: because n and V are directly proportional, when the volume increases, the moles should increase, and they do

Practice — If 1.00 mole of a gas occupies 22.4 L at STP, what volume would 0.750 moles occupy?

Practice — If 1.00 mole of a gas occupies 22.4 L at STP, what volume would 0.750 moles occupy? V1, n1, n2 V2 Given: Find: V1 =22.4 L, n1 = 1.00 mol, n2 = 0.750 mol V2 Conceptual Plan: Relationships: Solution: Check: because n and V are directly proportional, when the moles decrease, the volume should decrease, and it does

nT P V 10.4: Ideal-Gas Equation • So far we’ve seen that V 1/P (Boyle’s law) VT (Charles’s law) Vn (Avogadro’s law) • Combining these, we get

Ideal-Gas Equation The constant of proportionality is known as R, the gas constant. • The value of R depends on the units of P and V • we will use 0.08206 L-atm/mol-K and convert P to atm and V to L

nT P V nT P V= R Ideal-Gas Equation The relationship We replace the proportionality sign with by inserting the R constant  = PV = nRT then becomes or The value of R depends on the units of P and V. However we usually will use 0.08206 and convert P to atm and V to L

P, V, T, R n Example 6: How many moles of gas are in a basketball with total pressure 24.3 psi, volume of 3.24 L at 25°C? Given: Find: V = 3.24 L, P = 24.3 psi, t = 25 °C n, mol Conceptual Plan: Relationships: Solution: 1 mole at STP occupies 22.4 L, because there is a much smaller volume than 22.4 L, we expect less than 1 mole of gas Check:

Practice – A gas occupies 10.0 L at 44.1 psi and 27 °C. What volume will it occupy at standard conditions?

P1, V1, T1, R n P2, n, T2, R V2 A gas occupies 10.0 L at 44.1 psi and 27 °C. What volume will it occupy at standard conditions? Given: Find: V1 = 10.0L, P1 = 44.1 psi, t1 = 27 °C, P2 = 1.00 atm, t2 = 0 °C V2, L Conceptual Plan: Relationships: Solution: Check: 1 mole at STP occupies 22.4 L, because there is more than 1 mole, we expect more than 22.4 L of gas

Practice — Calculate the volume occupied by 637 g of SO2 (MM 64.07) at 6.08 x 104 mmHg and –23 °C

Practice—Calculate the volume occupied by 637 g of SO2 (MM 64.07) at 6.08 x 104 mmHg and –23 °C. P, n, T, R g V n Given: Find: mSO2 = 637 g, P = 6.08 x 104 mmHg, t= −23 °C, V, L Conceptual Plan: Relationships: Solution:

10.5: Further application of the Ideal-Gas Equation • We use ideal-gas equation to • define The relationship between the density of a gas and its molar mass • calculate the volume of gasses formed or consumed in chemical reactions

n V P RT = Densities of Gases If we divide both sides of the ideal-gas equation by V and by RT, we get → PV = nRT

n V n V P RT P RT m n = = = m V P RT = Densities of Gases • We know that • Moles  molecular mass = mass  n  = m • So multiplying both sides by the molecular mass () or m/n gives )  *( )* (

m V P RT d = = Densities of Gases • Mass  volume = density • So, Note: One needs to know only the molecular mass (M), the pressure(P), and the temperature (T) to calculate the density of a gas.

P RT d = dRT P  = Molecular Mass We can manipulate the density equation to enable us to find the molecular mass of a gas: becomes • Density is directly proportional to molar mass

Practice – Calculate the density of N2(g) at STP

Chapter 10 Gases

Chapter 10 Gases

Presentation Transcript

Chapter 10 Gases

Gases CHAPTER 10

Chapter 10 Gases

Chapter 10 Gases

Chapter 10 Gases

Chapter 10 Gases

Chapter 10 Gases

Chapter 10 Gases

Chapter 10 Gases

Chapter 10; Gases

Chapter 10 - Gases

Chapter 10 “Gases”

Chapter 10 Gases

Chapter 10 Gases

Chapter 10 Gases

Chapter 10 Gases

Chapter 10 Gases

Chapter 10; Gases

Gases CHAPTER 10