Presentation is loading. Please wait.

Presentation is loading. Please wait.

21-2-2011. Clausius – Clapeyron Equation This equation is a relation between  H vap and pressure at a certain Temperature.

Published byRosamond Houston Modified over 9 years ago

Similar presentations

Presentation on theme: "21-2-2011. Clausius – Clapeyron Equation This equation is a relation between  H vap and pressure at a certain Temperature."— Presentation transcript:

1 21-2-2011

2 Clausius – Clapeyron Equation This equation is a relation between  H vap and pressure at a certain Temperature.

3

4 Example 1: Water has a vapor pressure of 24 mmHg at 25 o C and a heat of vaporization of 40.7 kJ/mol. What is the vapor pressure of water at 67 o C? Solution: Simply use the Clausius-Clapeyron Equation to figure out the vapor pressure. We have to be a bit careful about the units of R: the units we're using are kJ, so R = 8.31x10 -3 kJ/mol K. ln(P 2 /P 1 ) = -  H vap /R * (1/T 2 - 1/T 1 ) ln(P 2 /24) = - 40.7 kJ/8.31x10 -3 kJ/mol K *(1/340- 1/298) ln(P 2 /24) = 2.03 P 2 /24 = 7.62 P 2 = 182 mmHg

5 Example 2: An unknown liquid has a vapor pressure of 88 mmHg at 45 o C and 39 mm Hg at 25 o C. What is its heat of vaporization? Solution: use the Clausius-Clapeyron Equation. Here, the only thing we don't know is  H vap ln(88/39) = (  H vap /8.31x10 -3 ){(1/318) – (1/298)}  H vap = 32.0 kJ

6 Liquid-solid equilibrium A solid can be transformed into a liquid at a specific temperature called the melting point. Melting occurs as temperature increases the kinetic energy of the molecules and thus make them move around. The melting point (or freezing point) is the temperature at which solid and liquid phases coexist in equilibrium.

7 Normal melting or freezing points The temperature at which both solid and liquid phases coexist at equilibrium at 1 atm is called the normal melting point (normal freezing point). Ice Water

8 Molar heat of fusion (  H fus ) The energy required to melt 1 mole of a solid is called the molar heat of fusion (  H fus ). The molar heat of fusion is definitely smaller than the molar heat of vaporization since vaporization requires complete removal of the molecules from the surface while fusion only requires rearrangement from solid to liquid.

9

10

11 Solid-vapor equilibrium Solids can undergo direct evaporation, and thereby solids are said to have a vapor pressure. Ice vapor Sublimation: is a process in which molecules can go directly from the solid to the vapor phase. The reverse process is called “deposition”. Naphthalene (mothballs) and I 2 are examples.

12 Molar heat of sublimation (  H sub ) The energy required to sublime 1 mole of a solid is called the molar heat of sublimation.  H sub =  H fus +  H vap This is, in fact, a manifestation of Hess’s law, where the amount of energy needed to transform a solid to vapor is the same whether we go directly or in steps by first transforming the solid to a liquid and then transforming the liquid to vapor.

13 Example Find the energy in kJ necessary to melt 1.00 g of ice.  H fus of ice = 5.98 kJ/mol Solution Melting of one mole of ice requires 5.98 kJ, therefore, find moles of ice present in 1.00 g and find energy required. Energy needed =  H fus * Number of moles Energy needed = 5.98 kJ/mol * {1.00 g/(18.0 g/mol)} = 0.332 kJ

14 Heating and Cooling Curves When heat is added to a solid its temperature will rise till the melting point is reached where the temperature stays constants till the entire solid is converted to liquid. When extra heat is added to the system, the temperature of the liquid starts to rise till the boiling point is reached where the temperature stays constant till all the liquid is converted to vapor. This can be represented by a heating curve as below:

15

16 Example Find the energy needed to convert 36.0 g of ice at -23 o C into vapor at 120 o C.  H fus = 5.98 kJ/mol and  H vap = 44.0 kJ/mol, specific heat of water is 4.184 J g -1 o C -1, specific heat of ice is 2.06 J g -1 o C -1, and specific heat of steam is 1.99 J g -1 o C -1. Solution Number of moles = 36.0/18.0 = 2.00 moles

17 Following the heating curve above, ice should first be 1.It will require energy to be converted to ice at 0 o C (heat capacity 1) 2.It will require the heat of fusion to convert to liquid at 0 o C 3.It will need energy to be converted to liquid at 100 o C, boiling temperature for water (heat capacity 2) 4.It will require the heat of vaporization to be converted to water vapor at 100 o C 5.It will require energy to raise the temperature of the vapor to 120 o C (heat capacity 3)

18 Therefore, five energy terms should be summed together. Steps 1, 3, and five can be summed together as heat capacity term: Energy required = (heat capacity term) + number of moles *(  H fus +  H vap ) Energy required = {36.0 g * 0.00206 kJ g -1 o C -1 {0 – (-23)} o C + 36.0 g * 0.004184 kJ g -1 o C -1 {100 – (0)} o C + 36.0 g * 0.00199 kJ g -1 o C -1 {120 – (100)} o C} + 2.00 mol * (5.98 + 44.0)kJ/mol = 118.2 kJ

19 Phase Diagrams A phase diagram is a graph that represents and summarizes conditions under which a substance exist as liquid, solid, or gas. We will only look at the phase diagrams of water and carbon dioxide

20 A phase diagram

21 Triple point The triple point is the point at which all three phases coexist at equilibrium. For water, the triple point occurs at 0.01 o C, and 0.006 atm.

22 Water phase diagram

23

24 Example Describe any changes in the phases present when water is: 1.Kept at 0 o C while pressure is increased from that at point 1 to that at point 5. 2.Kept at 1 atm while the temperature is increased from that at point 6 to that at point 9.

25

26

27 CO 2 Phase diagram

28 Answer the following problems: 1-3, 7, 9, 11-20, 22, 27-29, 31, 54, 56-60, 62, 65, 66, 69, 71-75, 80, 86, 99.

Download ppt "21-2-2011. Clausius – Clapeyron Equation This equation is a relation between  H vap and pressure at a certain Temperature."

Similar presentations

Heating/Cooling Curve and Phase Diagrams

Heating/Cooling Curve and Phase Diagrams
A-B = Solid ice, temperature is increasing. Particles gain kinetic energy, vibration of particles increases. Heating and cooling curve for water heated.

A-B = Solid ice, temperature is increasing. Particles gain kinetic energy, vibration of particles increases. Heating and cooling curve for water heated.
Ch. 16: Energy and Chemical Change

Ch. 16: Energy and Chemical Change
Section 12.4: Phase Changes

Section 12.4: Phase Changes
Water and Its Phase Changes Wednesday, February 20, 2008 Homework: Due Thursday Page 514, #9, 19, 21, 22, 23.

Water and Its Phase Changes Wednesday, February 20, 2008 Homework: Due Thursday Page 514, #9, 19, 21, 22, 23.
What is a Phase? A phase is a homogeneous, physically distinct, and mechanically separable portion of matter. It is uniform throughout, both in chemical.

What is a Phase? A phase is a homogeneous, physically distinct, and mechanically separable portion of matter. It is uniform throughout, both in chemical.
Phase Changes The boiling point is the temperature at which the (equilibrium) vapor pressure of a liquid is equal to the external pressure. The normal.

Phase Changes The boiling point is the temperature at which the (equilibrium) vapor pressure of a liquid is equal to the external pressure. The normal.
Phase Changes Courtesy www.lab-initio.com.

Phase Changes Courtesy
CHANGES OF STATE Design: Metro Color: Office 10.4.

CHANGES OF STATE Design: Metro Color: Office 10.4.
Phase Changes Chp 10. Phase Diagrams Phase diagram = relates physical states of matter (solid, liquid, gas) to temperature and pressure.

Phase Changes Chp 10. Phase Diagrams Phase diagram = relates physical states of matter (solid, liquid, gas) to temperature and pressure.
Chapter 11 1 Ch 11 Page 467. STATES OF MATTER CH 11.4-7 CH 11.1-3 CH 5The internet? Phase Change- The transformation from one phase to another upon the.

Chapter 11 1 Ch 11 Page 467. STATES OF MATTER CH CH CH 5The internet? Phase Change- The transformation from one phase to another upon the.
Figure 16.44: Behavior of a liquid in a closed container.

Figure 16.44: Behavior of a liquid in a closed container.
Figure 16.44: Behavior of a liquid in a closed container.

Figure 16.44: Behavior of a liquid in a closed container.
Phases of Matter.

Phases of Matter.
Phase Changes Melting Vaporization Condensation Freezing Sublimation.

Phase Changes Melting Vaporization Condensation Freezing Sublimation.
Slide 2 of 61 Boiling and Boiling Point Copyright © 2011 Pearson Canada Inc. General Chemistry: Chapter 12 FIGURE 12-21 Boiling water in a paper cup Liquid.

Slide 2 of 61 Boiling and Boiling Point Copyright © 2011 Pearson Canada Inc. General Chemistry: Chapter 12 FIGURE Boiling water in a paper cup Liquid.
Heating and Cooling Curve. Heating Curve Is a graph of heat added versus temperature Is useful in describing the change in temperature and the amount.

Heating and Cooling Curve. Heating Curve Is a graph of heat added versus temperature Is useful in describing the change in temperature and the amount.
Heating and Cooling Curve Definitions: Specific Heat: Amount of energy required to raise the temperature of 1 gram of a substance by 1⁰ Celsius Enthalpy.

Heating and Cooling Curve Definitions: Specific Heat: Amount of energy required to raise the temperature of 1 gram of a substance by 1⁰ Celsius Enthalpy.
Energy Requirements for changing state: In ice the water molecules are held together by strong intermolecular forces. The energy required to melt 1 gram.

Energy Requirements for changing state: In ice the water molecules are held together by strong intermolecular forces. The energy required to melt 1 gram.
Phase Changes Chapter 11. Vaporization An endothermic process in which the intermolecular attractions of a liquid are broken releasing molecules as a.

Phase Changes Chapter 11. Vaporization An endothermic process in which the intermolecular attractions of a liquid are broken releasing molecules as a.

Similar presentations

Ads by Google