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Chemistry 1011 Slot 51 Chemistry 1011 TOPIC Thermochemistry TEXT REFERENCE Masterton and Hurley Chapter 8.

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Presentation on theme: "Chemistry 1011 Slot 51 Chemistry 1011 TOPIC Thermochemistry TEXT REFERENCE Masterton and Hurley Chapter 8."— Presentation transcript:

1 Chemistry 1011 Slot 51 Chemistry 1011 TOPIC Thermochemistry TEXT REFERENCE Masterton and Hurley Chapter 8

2 Chemistry 1011 Slot 52 8.4 Thermochemical Equations YOU ARE EXPECTED TO BE ABLE TO: –Define molar enthalpy of reaction, molar heat of fusion and molar heat of vaporization. –Carry out calculations relating heat absorbed or released in a chemical reaction, the quantity of a reactant or product involved, and  H for the reaction. –Use Hess's Law to determine the heat of reaction given appropriate equations and thermochemical data.

3 Chemistry 1011 Slot 53 Molar Heat of Fusion and of Vaporization The latent heat of fusion (vaporization) of a substance is the heat absorbed or released when 1 gram of the substance changes phase. The molar heat of fusion (vaporization) of a substance is the heat absorbed or released when 1mole of the substance changes phase.

4 Chemistry 1011 Slot 54 Thermochemical Equations Balanced chemical equations that show the enthalpy relation between products and reactants H 2 (g) + Cl 2 (g)  2HCl(g);  H= -185 kJ Exothermic reaction: 185 kJ of heat is evolved when 2 moles of HCl are formed. 2HgO(s)  2Hg(l) + O 2 (g);  H= +182 kJ Endothermic reaction: 182 kJ of heat must be absorbed to decompose 2 moles HgO.

5 Chemistry 1011 Slot 55 Thermochemical Equations The sign of  H indicates whether the reaction is endothermic (+) or exothermic ( – ) Coefficients in the equations represent the numbers of moles of reactants and products Phases must be specified (s), (l), (g), (aq) The value quoted for  H applies when products and reactants are at the same temperature, usually 25 o C

6 Chemistry 1011 Slot 56 Thermochemical Equations Rule #1  H is directly proportional to the amount of reactants and products. When one mole of ice melts,  H = +6.00 kJ. When one gram of ice melts,  H = +0.333 kJ.g -1 H 2(g) + Cl 2(g)  2HCl (g) ;  H = -185kJ 1 / 2 H 2(g) + 1 / 2 Cl 2(g)  HCl (g) ;  H = -92.5kJ

7 Chemistry 1011 Slot 57 Thermochemical Equations Rule #2  H for a reaction is equal in magnitude but opposite in sign to  H for the reverse reaction. 2HgO(s)  2Hg(l) + O 2 (g);  H= +182 kJ 2Hg(l) + O 2 (g)  2HgO(s) ;  H= -182 kJ

8 Chemistry 1011 Slot 58 Thermochemical Equations Rule #3  H is independent of the path of the reaction – it depends only on the initial and final states

9 Chemistry 1011 Slot 59 Hess’ law  H =  H1 +  H2

10 Chemistry 1011 Slot 510 Using Hess’ Law Hess’ Law is used to calculate  H for reactions that are difficult to carry out directly. In order to apply Hess’ Law we need to know  H for other related reactions. For example, we can calculate  H for 1.C(s) + 1 / 2 O 2 (g)  CO(g);  H 1 = ? If we know  H for 2.CO(g) + 1 / 2 O 2 (g)  CO 2 (g);  H 2 = -283.0 kJ 3.C(s) + O 2 (g)  CO 2 (g);  H 3 = -393.5 kJ

11 Chemistry 1011 Slot 511 Calculating the Unknown  H Write equation #3 C(s) + O 2 (g)  CO 2 (g);  H 3 = -393.5 kJ Reverse equation #2 CO 2 (g)  CO(g) + 1 / 2 O 2 (g); -  H 2 = +283.0 kJ Add the two equations C(s) + 1 / 2 O 2 (g)  CO(g);  H 1 = -393.5kJ + 283.0kJ = -110.5kJ

12 Chemistry 1011 Slot 512 Enthalpy Diagram C(s) + O 2 (g) CO 2 (g) CO(g) + 1 / 2 O 2 (g)  H 3 -393.5kJ  H 2 +283.0kJ  H 1 -110.5kJ

13 Chemistry 1011 Slot 513 Some Other Examples Given 1. 1 / 2 N 2(g) + 3 / 2 H 2(g)  NH 3(g) ;  H = -46.1kJ 2.C(s) + 2H 2(g)  CH 4(g) ;  H = -74.7kJ 3.C(s) + 1 / 2 H 2(g) + 1 / 2 N 2(g)  HCN(g);  H = +135.2kJ Find  H for the reaction: 4.CH 4(g) + NH 3(g)  HCN(g) + 3H 2(g)

14 Chemistry 1011 Slot 514 Some Other Examples Given 1 / 2 N 2(g) + 3 / 2 H 2(g)  NH 3(g) ;  H = -46.1kJ C(s) + 2H 2(g)  CH 4(g) ;  H = -74.7kJ C(s) + 1 / 2 H 2(g) + 1 / 2 N 2(g)  HCN(g);  H = +135.2kJ Find  H for the reaction: CH 4(g) + NH 3(g)  HCN(g) + 3H 2(g)

15 Chemistry 1011 Slot 515 Find  H for the reaction: CH 4(g) + NH 3(g)  HCN(g) + 3H 2(g Add Reverse Eq #2 to Reverse Eq #1 CH 4(g)  C(s) + 2H 2(g) ;  H = +74.7kJ NH 3(g)  1 / 2 N 2(g) + 3 / 2 H 2(g) ;  H = +46.1kJ CH 4(g) + NH 3(g)  C(s) + 2H 2(g) + 1 / 2 N 2(g) + 3 / 2 H 2(g) ;  H = +120.8kJ Add Eq #3 C(s) + 1 / 2 H 2(g) + 1 / 2 N 2(g)  HCN(g);  H = +135.2kJ CH 4(g) + NH 3(g)  HCN(g) + 3H 2(g;  H = +256.0kJ

16 Chemistry 1011 Slot 516 Some Other Examples A 1.00g sample of table sugar (sucrose), C 12 H 22 O 11, is burned in a bomb calorimeter containing 1.50 x 10 3 g water. –The temperature of the calorimeter and water rises from 25.00 o C to 27.32 o C. –The heat capacity of the metal components of the bomb is 837J.K -1. –The specific heat of water is 4.184J.g -1.K -1. Calculate –(a) the heat evolved by the 1.00g of sucrose, and –(b) the heat evolved per mole of sucrose.

17 Chemistry 1011 Slot 517 Solution Heat absorbed by the water = m.c.  t = 1.50 x 10 3 g x 4.184 J.g -1.K -1 x 2.32K = 14.6 kJ Heat absorbed by the calorimeter = C.  t = 837 J.K -1 x 2.32K = 2.03 kJ Total heat absorbed by the calorimeter and contents =  total heat released by 1.00g sucrose =  16.6kJ Heat evolved per mole of sucrose =  16.6 kJ x 342 g.mol -1 =  5680 kJ

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