Difference between revisions of "Ch6 lec 3"
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:::q = mass of water * spec heat * ΔT | :::q = mass of water * spec heat * ΔT | ||
::::- where the spec heat for water is 4.184 J/(g<sup>o</sup>C). | ::::- where the spec heat for water is 4.184 J/(g<sup>o</sup>C). | ||
+ | |||
+ | :- Unfortunately, we introduced "calorimetry" in the first lab period...where we introduced heat (q), ΔH, specific heat, ΔT...all at once...sorry. Now that you know a little bit more about how to calculate the heat involved, we can now understand better how this heat generated or consumed can result in water heating up or cooling down. | ||
+ | |||
+ | The types of calorimetry problems that are asked involve: | ||
+ | :::Q1: Given the ΔH for a reaction and/or how much heat is generated when X moles/grams of a reactant is converted to products, what is the change in temperature of water in which the rxn occurred? |
Revision as of 18:26, 14 April 2020
(4/14/20, bes)
Greetings Gen Chem folks!
- This week we are going to continue our discussions of thermochemistry (Ch 6). In previous lecture notes we have covered the critical content associated with Sections 6.1-6.5. There is a lot more in these section then i have discussed, so focus on these lecture notes and not so much on the extended textbook material. As noted, all chemistry and biochemistry majors will be required to take Chem 312: Thermodynamics in their junior and senior year where we will get into more of the details.
Review of Section 6.4: Enthalpy
- - Nearly all chemical reactions generate (exothermic) or consume (endothermic) energy/heat.
- - We tabulate the amount of heat involved in an rxn using the enthalpy (ΔH) which most often has units of J or kJ per mol, kJ/mol of something.
- Remember, some of this can be confusing because the ΔH units can be displayed as just kJ or kJ/rxn <--as written. Depending on the stoichiometric coefficients, this is per X mole of reactant or product.
- - The types of problems that are asked involve:
- Q1: Given the ΔH for a reaction, determine how much heat is generated (implying exothermic reaction) when X moles of a reactant is converted to products.
- Q:2 Given the ΔH for a reaction, determine how much heat is generated (implying exothermic reaction) when Y grams of a reactant is converted to products.
- Q3: Given the amount of heat from a rxn and the amount (grams or moles) of a reactant or product, calculate the ΔH for the reaction.
See WA Ch6.1...
Review of Section 6.5: Calorimetry
- - When an aqueous chemical reaction occurs, the heat (q) generated or consumed goes into the water or comes out of the water.
- If you add heat to water the temperature of the water increases (+ΔT),
- If you remove heat from water the temperature of the water decreases (-ΔT).
- - The equation used to relate the heat to ΔT is:
- q = mass of water * spec heat * ΔT
- - where the spec heat for water is 4.184 J/(goC).
- q = mass of water * spec heat * ΔT
- - Unfortunately, we introduced "calorimetry" in the first lab period...where we introduced heat (q), ΔH, specific heat, ΔT...all at once...sorry. Now that you know a little bit more about how to calculate the heat involved, we can now understand better how this heat generated or consumed can result in water heating up or cooling down.
The types of calorimetry problems that are asked involve:
- Q1: Given the ΔH for a reaction and/or how much heat is generated when X moles/grams of a reactant is converted to products, what is the change in temperature of water in which the rxn occurred?