a measure of the energy chance needed to change the temp of a substance --> think of it as internal energy capacity
Heat Capacity Equation
C: heat capacity
q: heat
T: temp
"Specific Heat" Definition
simply the heat capacity per unit mass
Specific Heat Equation
q = m c ΔT
q: heat
m: mass
c: specific heat
T: change in temp
Coffee Cup Calorimeter
- measures the Δenergy at atmospheric pressure (∴ a constant pressure system)
-used to measure heats of a reaction (@ constant pressure q=ΔH)
i.e. we mix H+ + OH- --> H2O
we can solve for "q" in q=mcΔT and since @ const. P, q=ΔH, we have the heat of the rxn
Bomb Calorimeter
- measures Δenergy at constant volume
- used to measure internal energy change (@ constant volume q=ΔU)
i.e. use known heat capacity (C) of the container and the q=CΔT to deduce the internal energy (U)
Phase Changes
(1) Melting - Freezing
(2) Vaporization - Condensation
(3) Sublimation - Deposition
When does evaporation occur?
when the partial pressure above the liquid is less than (<) the vapour pressure of the liquid
BUT atmospheric P. > vapour P.
*this allows the liquid to evaporate rather than boil
Boiling Point
Atmos. P = Vapour P. of a liquid
Melting Point
Vapour Psolid = Vapour Pliquid
Compare the amount of heat released when moving from liquid --> solid to the amount of heat absorbed when moving from a solid --> liquid
Exactly the same amount of heat that is absorbed when melting is released when freezing
Identify where bonds are broken during phase changes
solid --> liquid (melting)
liquid --> gas (vaporization)
Temp v. Energy Phase Change Graph
Phase Change Diagram: triple pt, critical pt
Critical Point
- critical temp: above which a substance cannot be liquified regardless of the pressure applied
- critical pressure: required to produce liquification while the substance is at the critical temp
critical pressure, critical temp = critical pt
What happens to the temperature of a system during a phase change?
When there is not a phase change?
There is no change in temperature during a phase change.
Otherwise, energy increases molecular movement which increases temperature.
What is the slope of a temp v. energy graph when the phase is not changing?
slope = 1 / mc
m: mass
c: specific heat
Colligative Properties
- properties that depend only on the number of particles and not the type
(1) vapour pressure
(2) boiling point
(3) freezing point
(4) osmotic pressure
Explain Boiling Point Elevation
- with the addition of a nonvolatile solute there is a decrease in vapour pressure
- boiling point occurs when V.P. = Atmos. P.
- ∴ when V.P. decreases the b.p. increases
Boiling Point Elevation Equation
ΔT = kbmi
kb: a constant
m: molality
i: # of ions after dissociation
(i.e. NaCl --> Na + Cl ∴i = 2)
(i.e. MgCl2 --> Mg+2 + 2Cl ∴ i = 2)
Explain Freezing Point Depression
- the addition of a nonvolatile solute can interrupt the crystal lattice
- this will lower the freezing point
*be careful: eventually you get to a point where the solvent becomes the impurity preventing the solute from freezing --> ∴ the freezing point lowers at first and then rises again after it has hit this point
Freezing Point Depression Equation
ΔT = kfmi
kf: a constant
m: molality
i: # of ions after dissociation
(i.e. NaCl --> Na + Cl ∴i = 2)
(i.e. MgCl2 --> Mg+2 + 2Cl ∴ i = 2)
Osmotic Pressure Concept
- only relevant when comparing one solution to another
- think of a selectively permeable membrane
if one side is concentrated, the water will move to wards that side in order to maintain the same dilution factor
Osmotic Pressure Equation
Π = iMRT
Π: osmotic pressure
i: # of ions after dissociation
M: molarity
T: temp
- this gives you the pressure on one side of the membrane (the total pressure is the difference between both sides)
Author
laskiru
ID
57072
Card Set
Chemistry Lect 5
Description
Heat Capacity, Phase Change, and Colligative Properties