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1 Thermochemistry 2 Chemical reactions are accompanied by changes in energy.

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Presentation on theme: "1 Thermochemistry 2 Chemical reactions are accompanied by changes in energy."— Presentation transcript:

1

2 1 Thermochemistry

3 2 Chemical reactions are accompanied by changes in energy.

4 3 Definitions: Energy: The ability to do work, w = f x d K.E. =1/2mv 2 energy in motion What are some forms of kinetic energy? P.E. potential energy What are some forms of potential energy? Chemical Positional Mechanical, electrical, thermal, sound, etc (Motion)

5 4 Energy Units: Joule = J 1 J = kg ·m/s 2 Since a J is very small we usually use kJ’s calorie = cal 1 cal = 4.184 J (exact by definition) 1 cal is the amount of heat necessary to heat 1 g of water 1 o C (from 14.5 to 15.5 o C) 1 cal 4.184 J A conversion factor!

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7 6 Food Calories: 1 Cal (note capital for food) = 1000 cal = 1 kcal So... That donut with only 500 Calories is really.... 500,000 calories... (eat 2 to make it an even million).

8 7 1st Law of Thermodynamics: Energy cannot be created nor destroyed. System  Surroundings System: whatever we are interested in. Surroundings: the rest of the universe

9 8 Internal Energy (E): The sum of all K.E. and P.E. of a system. Internal energy is too complex to be measured exactly, so we look at the change in internal energy:  E system = E final - E initial Sign of  E: (+) means: system has gained energy (-) means: system has lost energy From the 1st Law of Thermodynamics:  E system = -  E surroundings

10 9 Sign of  E: (+) means: system has gained energy (-) means: system has lost energy 2H 2 O(g)  2H 2 (g) + O 2 (g)2H 2 (g) + O 2 (g)  2H 2 O(g)

11 10 Sign of  E: (+) means: system has gained energy (-) means: system has lost energy 2H 2 O(g)  2H 2 (g) + O 2 (g)2H 2 (g) + O 2 (g)  2H 2 O(g) + energy (given off) + energy (added to system)

12 11 Heat and Work: energy exchange  E = q + w Work done on (+) or by (-) the sys. Heat gained (+) or lost (-) by the sys. Internal energy of the sys. (both K.E. and P.E.)

13 12 Reactions are Energy Driven: Energy given off  Exothermic (-) sign “Exit” Energy absorbed  Endothermic (+) sign “Enter” Remember: 1st Law of Thermo.:  E system = -  E surroundings So for every endothermic process there is an exothermic process.

14 13 Decide if each of the following are Endo or Exothermic processes: Ice melting? Water freezing? A candle burning? Dynamite exploding? A plant growing?

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17 16 Misconception: Energy vs Temperature Both containers are at the same temperature, which one contains the most energy? Temperature is an intensive property (amount independent) Energy is an extensive property (amount dependent)

18 17 Enthalpy (H): heat content per amount Extensive property Enthalpy Change (  H) In a reaction:  H = H Products - H reactants  H (+) endo  H (-) exo

19 18 Enthalpy Change (  H) In a reaction:  H = H Products - H reactants  H (+) endo  H (-) exo Enthalpy is a state function. “Net Change” “Path indepedent” A B Both accomplished the same net result!

20 19 Problem: Given the reaction, which occurs in the presence of the catalyst MnO 2 ): 2KClO 3 (s)  2KCl(s) + 3O 2 (g)  H = -89.7 kJ a. What would be the value of  H for the reverse RXN? +89.7 kJ

21 20 Problem: Given the reaction (which occurs in the presence of the catalyst MnO 2 ): 2KClO 3 (s)  2KCl(s) + 3O 2 (g)  H = -89.7 kJ The  H value listed is really a conversion factor! -89.7 kJ -89.7 kJ -89.7 kJ 2 mol KClO 3 2 mol KCl 3 mol O 2

22 21 Problem: Given the MnO 2 catalyzed reaction: 2KClO 3 (s)  2KCl(s) + 3O 2 (g)  H = -89.7 kJ -89.7 kJ -89.7 kJ -89.7 kJ 2 mol KClO 3 2 mol KCl 3 mol O 2 Calculate the value of  H for the decomposition 9 moles of KClO 3 ? 2KClO 3 (s)  2KCl(s) + 3O 2 (s)  H = -89.7 kJ 9 moles KClO 3 -------------------------------------------------- = kJ -403.7

23 22 Problem: Given the MnO 2 catalyzed reaction: 2KClO 3 (s)  2KCl(s) + 3O 2 (g)  H = -89.7 kJ -89.7 kJ -89.7 kJ -89.7 kJ 2 mol KClO 3 2 mol KCl 3 mol O 2 Calculate the value of  H for the formation 25.0 grams of KCl. 2KClO 3 (s)  2KCl(s) + 3O 2 (s)  H = -89.7 kJ 25.0 g KCl -------------------------------------------------- = kJ 2 mol KCl -89.7 kJ -15.0 74.6 g KCl mol KCl

24 23 Look at overhead

25 24 CS 2 (l) + 3O 2 (g)  CO 2 (g) + 2SO 2 (g) From tables: 87.9kJ/mol 0 kJ/mol -393.5 kJ/mol -296.8 kJ/mol  H = H(products) - H(reactants) Each value must be multiplied by the number of moles in the equation/

26 25 CS 2 (l) + 3O 2 (g)  CO 2 (g) + 2SO 2 (g) From tables: 87.9kJ/mol 0 kJ/mol -393.5 kJ/mol -296.8k J/mol  H = H(products) - H(reactants)  H = H(products) - H(reactants) = [-393.5 + 2(-296.8)] - [87.9 + 3(0)]  H = -1073.4 kJ

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