1. TARGETS 1. Define and properly use the vocabulary. 2. Describe the three phases (states) of matter. 3. Identify phase and temperature changes as exothermic or endothermic. 4. Convert between the common energy units of Joules and calories. 5. Explain the relationship between temperature, energy, and heat.

2. THERMOCHEMISTRY Definition: Thermochemistry is the study of heat that is released or absorbed during chemical reactions, phase changes or other chemical activitiy.

3. THERMOCHEMISTRY LAW OF CONSERVATION OF ENERGY STATES THAT ENERGY CANNOT BE CREATED OR DESTROYED, BUT RATHER IT CHANGES FORMS. THE STUDY OF HEAT IN CHEMICAL REACTIONS APPLIES THIS LAW TO DEMONSTRATE THE CHANGE IN HEAT BEFORE AND AFTER THE REACTION.

4. THERMOCHEMISTRY ENERGY IN CHEMICAL EQUATIONS

5. SOLID, LIQUID, AND GAS PARTICLE ARRANGEMENT A substance has a particle arrangement based on the kinetic energy contained in the particles. The temperature of the substance is a measure of the kinetic energy of the particles. The particles with the least kinetic energy are in the solid phase, and the most kinetic energy particles are in the gas phase. https://www.youtube.com/watch?v=v12xG80KcZw https://www.youtube.com/watch?v=UnBoQe2rsgo

6. SOLID, LIQUID, AND GAS PARTICLE ARRANGEMENT  Particle arrangement determines state of matter.  State of matter is determined by temperature.  Temperature is a measure of the particles’ kinetic energy.  Kinetic energy determines the particle arrangement. 

7. SPECIFIC HEAT METAL SPOON VS. WOODEN SPOON

8. SPECIFIC HEAT THE AMOUNT OF ENERGY NEEDED TO RAISE THE TEMPERATURE OF 1 GRAM BY 1 DEGREE C UNITS ARE J/g-  C or cal/g-  C

9. SPECIFIC HEAT PROBLEMS Q=mc  T Q= heat energy m = mass of substance in grams c = specific heat constant for the substance  T = T final - T initial How much heat energy is contained in a 100 gram sample of water at 75.0  C? https://www.youtube.com/watch?v=Wf3wCjpmzH4

10. SPECIFIC HEAT PROBLEM c for water = 4.18J/g-  C Q = 100 g x 4.18J/g-  C x 75  C Q = 31,350 J What is the specific heat of a substance containing 300 J of energy at a temperature of 25.5 C with a mass of 131 g? 300 J = 131 g x c x 25.5 0.090 J/g-C

11. TARGETS 6. Describe the motion and arrangement of molecules and their kinetic and potential energy on the heating/cooling curve. 7. Identify the location of each phase, phase changes and the temperature changes on a heating/cooling curve. 8. Calculate the energy requirements for the temperature changes and phase changes. 9. Identify phase and temperature changes as exothermic or endothermic.

12. Liquid Sublimation Melting Vaporization Condensation Solid Freezing Gas PHASE CHANGES

13. HEATING CURVE FOR WATER HEAT ENERGY http://www.youtube.com/watch?v=fpHdPn0vW2s http://www.youtube.com/watch?v=IVc9Uz6zE1A&NR=1 http://www.youtube.com/watch?v=guoU_cuR8EE

14. Water and Ice Ice Water and Steam Steam -20 0 20 40 60 80 100 120 0 40120 220760800 Heating Curve for Water ENERGY kJ TEMPERATURECTEMPERATUREC Change 100 g of ice at -20 C to 100 g of steam at 120 C Step 1 Q=mcT 100g x 2.087 J/gC x 20 Q = 4174 J c=2.087 J/g-C

15. Water and Ice Ice Water and Steam Steam -20 0 20 40 60 80 100 120 0 40120 220760800 Heating Curve for Water 100 g 0.333 kJ/g=Heat of Fusion Heat of fusion is the number of J per g needed to melt ice Step 2 Q = Hf x m 334 J/g x 100 = 33300 J Step 3 Q=mcT 100 x 4.18 x 100 = 41800 J

16. Water and Ice Ice Water and Steam Steam -20 0 20 40 60 80 100 120 0 40120 220760800 Heating Curve for Water 100 g Heat of Vaporization 2.260 kJ/g c = 2.0 J/g-C Heat of vaporization is the amount of J of heat energy needed to change 1 g of water to steam. Step 5 Q=mcT 100 x 2.0J/g-C x 20= 4000J Step 4 Q= ∆ H v x mass 2260J/g x 100g = 226000J

17. Water and Ice Ice Water and Steam Steam -20 0 20 40 60 80 100 120 0 40120 220760800 Heating Curve for Water Slope = Specific Heat Q=mc ∆ T Steam Water Ice

18. Water and Ice Ice Water and Steam Steam -20 0 20 40 60 80 100 120 0 40120 220760800 Heating Curve for Water Both Water and Steam BOTH Ice and Water http://www.youtube.com/watch?v=EZHmUTmJtF8

19. Water and Ice Ice Water and Steam Steam -20 0 20 40 60 80 100 120 0 40120 220760800 Heating Curve for Water AT THE PHASE CHANGE, ENERGY IS GOING IN OR OUT, EVEN THOUGH TEMPERATURE IS CONSTANT USE CONSTANTS ∆ Hf or ∆ Hv

20. Water and Ice Ice Water and Steam Steam -20 0 20 40 60 80 100 120 0 40120 220760800 Heating Curve for Water HEAT ENERGY IN = ENDOTHERMIC HEAT ENERGY OUT= EXOTHERMIC http://www.youtube.com/watch?v=0cUK4jcAEaU

21. Energy and Phase Change Heat of vaporization energy required to change one gram of a substance from liquid to gas. For water 540 cal/g OR 2.260 kJ/g, 2260 J/g Heat of fusion energy required to change one gram of a substance from solid to liquid. For water 80 cal/g or 334 J/g

22. How to do it  The total heat = the sum of all the heats you have to use to go from first temperature to last temperature. Heat Ice Below 0  C + Melt Ice At 0  C + Heat Water 0  C - 100  C + Boil Water At 100  C + Heat Steam Above 100  C

23. Calculating Energy  Three equations  Heat = mass x specific heat x  T Q= mc  T  Heat = heat of fusion x mass Q= H fus x mass  Heat = heat of vaporization x mass Q = H vap x mass

24. CONSTANTS AND SYMBOLS CALORIESJOULES  For ice c. = 0.50 cal/g  C 2.09 J /g x ºC.  For water c = 1 cal/g  C4.18 J/g  For steam c = 0.50 cal/g  C2.0 J /g x ºC.  Heat of vaporization= 540 cal/g2260 J/g  Heat of fusion = 80 cal/g334 J /g c = specific heat Q = heat energy m = mass in grams cal= calories J= Joules ◦ C= degree Celcius △ T = T f -T i (Final Tem – Initial Temp)

25. CHANGE IN HEAT ENERGY  EXOTHERMIC:HEAT OUT, - △ H = heat out of the substance  http://www.youtube.com/watch?v=i3mYWB2fNp4 http://www.youtube.com/watch?v=i3mYWB2fNp4  ENDOTHERMIC : HEAT IN + △H= heat into the substance  http://www.youtube.com/watch?v=cBy4Q6A8Hfw http://www.youtube.com/watch?v=cBy4Q6A8Hfw

26. Example I  I. How much heat does it take to heat 12 g of ice at -6  C to 25  C water?  1. solve for Q for ice changing from -6 ◦ C to 0 ◦ C Q= mc △ T 12g x 2.09 J/g-C x (0- (-6)=150.48J  2. solve for Q = H fus x mass (this is melting at 0) 334 J/g x 12 g = 4008 J  3. solve for Q =mc △ T from 0 ◦ C to 25 ◦ C 12 g x 4.184 J/g-C x (25-0) = 1255.2 J  4. Add all three answers to determine the total amount of heat energy needed.  150.48J + 4008 J + 1255.2 J = 5413.68J

27. EXAMPLE II II How much heat does it take to heat 35 g of ice at -10  C to steam at 100  C? 1. solve for Q for ice changing from -10 ◦ C to 0 ◦ C Q= mc △ T 2. solve for Q = H fus x mass (this is melting at 0) 3. solve for Q =mc △ T from 0 ◦ C to 100 ◦ C 4. Solve for Q= H vap x mass (this is vaporization) 5. Add all four answers to determine the total amount of heat energy needed.

28. Problem Steps 1.Q=mc Δ T Q = 35.0 g x 2.09 J/g-C x (0- -10) = 731.5 J 2. Q = Δ H x m Q = 334 J/g x 35 = 11690 J 3. Q=mc Δ T Q = 35.0 g x 4.18 J/g-C x (100-0) = 14630 J 4 Q = △ H x m Q = 35 g x 2260 J/g = 79100.03 731.5 J + 11,690 J + 14,630 J + 79,100.03 J Total = 106151.5J

29. https://www.youtube.com/watch?v=JuWtBR-rDQk  https://www.youtube.com/watch?v=TDOjELi-m8w https://www.youtube.com/watch?v=TDOjELi-m8w

30. HEAT OF FORMATION  Calculate ∆ H for the following reaction:  8 Al(s) + 3 Fe 3 O 4 (s) --> 4 Al 2 O 3 (s) + 9 Fe(s)  Solution  ∆ H for a reaction is equal to the sum of the heats of formation of the product compounds minus the sum of the heats of formation of the reactant compounds:  ∆ H = ∑ ∆ H f products - ∑ ∆ H f reactants  Elements are removed because you cannot form an element.  ∆ H = 4 ∆ H f Al 2 O 3 (s) - 3 ∆ H f Fe 3 O 4 (s)  The values for ∆ H f may be found in the Heats of Formation of Compounds table. Plugging in these numbers: Al 2 O 3 =-1669.8 kJ/mol Al 2 O 3 = -1120.9 kJ  ∆ H = 4(-1669.8 kJ) - 3(-1120.9 kJ)  ∆ H = -3316.5 kJ

31. HEAT OF FORMATION EQUATION ∆ H = ∑∆ H p - ∑∆ H r Hess’ Law: Total heat of reaction is equal to the sum of the products minus the sum of the reactants.

32. HEAT OF REACTIONS C 3 H 8 (g) +5 O 2 (g)  3 CO 2 (g) + 4 H 2 O (g) + 2044.0 kJ The heat of combustion of propane is –2044.0 kJ/mol. HOW MUCH ENERGY IS RELEASED WHEN 350.0 GRAMS OF PROPANE IS BURNED? Identify the givens: -2044 kJ, 350 g C 3 H 8 (g) Understand that 1 mole gives off 2044 kJ of energy. 350 g x 1mole = 7.95 mole 44 g Q = mass x ∆ H c Q = mole x ∆ H c 7.95 mol x -2044 kJ/mol = -16249.8 kJ

33. HEATS OF REACTION PRACTICE PROBLEM CH 4 + 2O 2  CO 2 + 2H 2 O + 890 kJ How much heat energy is given off when 425 grams of CH 4 are burned? The equation tells us that 890 kJ of energy are give off when 1 mole of CH 4 are burned. 1.Change grams to moles: 425g x 1mole/16 = 26.56 2.Multiply moles times heat: 26.56 x -890kJ = -2.364 x 10 4 kJ

34. HEATS OF REACTION PRACTICE PROBLEM CH 4 + 2O 2  CO 2 + 2H 2 O + 890 kJ How much heat energy is given off when 2, 500 grams of CH 4 are burned? 2,500g x 1 mol/16 = 156.25 mol 156.25 mol x -890 kJ = -1.39063 x 10 5 kJ

35. HEATS OF REACTION 3CO(g) + Fe 2 O 3 (s)  2Fe(s) + 3CO 2 (g) + 24.7 kJ, How much heat is released when 235.0 g of CO react? First: change Grams to moles of CO Look at the equation: 3 mol of CO= 24.7 kJ (You need to divide 24.7 by 3 mol) Second: Multiply mol CO by the kJ per mole 235 g x 1mol/28= 8.393mol (-24.7 kJ/3 mol)= -8.233 kJ 8.393 X -8.233 = -69.10

36. PRACTICE PROBLEMS Q=m ∆ H Quantityper gramPer mole Heat of fusion334 J/g 6009 J/mole Heat of vaporization 2260 J/g 40700 J/mole Specific heat of solid H 2 O (ice) 2.087 J/(g·°C) * Specific heat of liquid H 2 O (water) 4.184 J/(g·°C) * Specific heat of gaseous H 2 O (steam) 2.000 J/(g·°C) * How many moles of water were frozen if 1.334 x 10 6 J of energy were used? Divide J/J-mol for fusion 1.334 x 10 6 J/6009J-mol = 222 How many moles of water were changed to steam if 5.0 x 10 5 J were used? Divide J/J-mol for vaporization 5.0 x 10 5 J/40700 J-mol = 12.29 mol If 2950 J were used to change liquid to solid ice, how many grams froze? Divide J/J-g 2950 J/ 334 J-g =8.832

37. WHAT TO KNOW FOR TEST  VOCAB WORDS  HOW TO SOLVE FOR Q=mc ∆ T (any variable)  INTERPRET A PHASE CHANGE DIAGRAM  KNOW THAT DURING A PHASE CHANGE, THERE IS NO TEMPERATURE CHANGE ONLY A CHANGE IN ENERGY.  HOW TO SOLVE FOR THE TOTAL Q WHEN ICE AT ANY TEMP CHANGES TO STEAM AT ANY TEMPERATURE.

38. WHAT TO KNOW FOR TEST  IN AN EXOTHERMIC REACTION HEAT IS GIVEN OFF, CH 4 + 2O 2  CO 2 + 2H 2 O + 890 kJ, ∆H= -890 kJ  IN AN ENDO THERMIC REACTION HEAT IS TAKEN IN, N 2 + O 2 +180.5 kJ  2NO, ∆H = + 180.5 kJ  Solve for ∆ H given the heat of reaction using stoichiometry

39. WHAT TO KNOW FOR TEST  SOLVE CALORIMETRY PROBLEMS AND IDENTIFY THE METAL.  Particle arrangement and relative energy in a solid, liquid and gas.  LAW OF CONSERVATION OF ENERGY  Freezing point and melting point are the same temp.  The amount of heat energy transferred to a substance depends on: mass, specific heat of substance, and change in temp.

40. PROBLEMS Q=m ∆ H  How many kJ of energy were produced if 200 g of CH4 were burned? CH 4 + 2O 2  CO 2 + 2H 2 O + 890 kJ, ∆H= -890 kJ How many grams CH4 were burned is the total energy output was 9.9 x 10 4 kJ? If 15.0 moles of water were produced, how many kJ were also produced? CHANGE 200 g TO MOLES 200 X 1/16 =12.50 mole 12.5 m x -890 kJ = - 11,125 kJ Q=m x ∆ H 9.9 x 10 4 kJ = m x -890 kJ/mol = 111.235 mol 111.325 x 16/1 = 1781.2 g Divide ∆ H by 2 Q = 15 mol x -890 kJ/2 mol =6675 kJ

41. PROBLEMS  HOW MUCH ENERGY IS CHANGED IF 614.0 g OF NO are produced?  EXIT SLIP: SHOW WORK AND ANSWER. N 2 + O 2 +180.5 kJ  2NO, ∆H = + 180.5 kJ