Thermochemistry

1. Thermochemistry Chapter 5 Regular Chem book = Ch 11

2. Hmmmmmm… • When we eat calories • where is the HEAT in food? • What do we do with it (what do we convert it into) when we “burn” calories? • Food’s heat is in its bonds- it’s energy is being used to hold the particles together • We break the bonds and release that energy- then we convert it to movement and heat

3. Try this… • Place a PEA-SIZED piece of anhydrous (aka dried out) CuSO4 in your hand • Add a few drops of water • What do you feel? • Wash your hands

4. Put the THERMO in Chemistry Mg + HCl  MgCl2 + H2 But, that’s only part of the story because this reaction gives off lots of heat! + heat That turns a chemical equation into a thermochemical equation

5. 2 types: • Endothermic • Reaction or process that __________ heat • ΔH is • Reactants have _____ heat than products absorbs positive less

6. 2 types: • Exothermic • Reaction or process that __________ heat • ΔH is • Reactants have _____ heat than products releases negative more

7. Exo and Endo (cont.) • For every exothermic process, there’s an endothermic partner • What’s exo/endo in… • Freezing ice? • Boiling water? • BBQing sausages? • You outside on a super cold day?

8. Thermo Equations There are 3 different ways to write a thermo equation: • H2O(l) + heat  H2O(g) • H2O(l) H2O(g) ΔH= -285kJ • H2O(g) H2O(l)

9. Try it! 1 mole of ice needs to absorb 285kJ of heat in order to melt. Write the thermo equation 3 ways.

10. Try it! The combustion of methane releases 890kJ of heat. Write the equation for this reaction 3 ways. Wait, combustion releases heat but you have to add heat to make it happen. What’s up with that?

11. Heat? • Measured in • Calories • 1 Cal = 1 kilocal or kcal = 1000 cal • Joules • 4.184 J = 1 calorie • 1000 J = 1 kJ

12. Thermo Stoich Calcs Interesting little tidbit… this is the reaction when you make cement. You add little rocks and stuff to CaO and then add water. CaO + H2O  Ca(OH)2 + 65.2kJ Which means that 1 mole of CaO produces 65.2kJ of heat …and that adds another arrow to the molar conversion map • How much heat will 4 moles produce? • How much will 100g produce? • What mass of CaO is needed to make 1000kJ? 4 x 65.2 = 260.8 kJ 100/56 x 65.2 = 116.4 kJ 1000/65.2 x 56 = 858.9g

13. Calculations Practice Fe2O3 + 3CO  2Fe + 3CO2 + 26.3kJ • Is this exo or endothermic? • How much heat would be produced from 1.2 moles of CO? • How about from 100L of CO (at STP) Exothermic 1.2/3 x 26.3 = 78.9 100 / 22.4 / 3 x 26.3 = 39.1kJ

14. Specific Heat So… you’re out walking barefoot on a 90o day and you have the choice to step on (a) the sidewalk (b) a manhole cover (c) a puddle What would you do?

15. Specific Heat II (Specific) Heat capacity = the amount of heat it takes to raise 1g of a substance by 1oC -- Water is high, metal is low -- What else is high & low? (p. 296) -- What’s up with the oranges on p. 297?

16. Specific Heat III q = mCΔT q is the heat in cal or J m is the mass in g C is the specific heat in J/goC or cal/goC ΔT is the temp change in oC Try #1-3, 8-10 on page 299

17. Calorimetry • Method of measuring temperature change in order to calculate heat change • Measure temp change of water* • Use q=mCDT to find q… • q absorbed by water= q released by reaction

18. q=mCΔT Example #1: 94.6g of Cu heats up 2540oC by absorbing 849J, what’s its specific heat? 0.387 J/goC Example #2: 100g of an unknown metal cools 6020oC by absorbing 132 cal of heat. What metal is it? 0.03 J/goC, Mercury