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Reversible Reactions
• Reactions can be reversed depending on energy flow.
• For example if the battery in a car is dead, you can jump start it.
We’ve already used the phrase “equilibrium” when talking about reactions.
In principle, every chemical reaction is reversible ... capable of moving in the forward or backward direction.
2 H2 + O2 2 H2O
Some reactions are easily reversible ...Some not so easy ...
Equilibrium: the extent of a reactionIn stoichiometry we talk about theoretical
yields, and the many reasons actual yields may be lower.
Another critical reason actual yields may be lower is the reversibility of chemical reactions: some reactions may produce only 70% of the product you may calculate they ought to produce.
Equilibrium looks at the extent of a chemical
reaction.
Equilibrium• There is no net change in the amount of reactants and
products from a chemical reaction. • Products and reactants form at the same rate.• Reactions can be pushed in either direction by adding or
removing heat, reactants or products.
The Concept of Equilibrium
• As a system approaches equilibrium, both the forward and reverse reactions are occurring.
• At equilibrium, the forward and reverse reactions are proceeding at the same rate.
The Concept of EquilibriumAs the reaction progresses
– [A] decreases to a constant,– [B] increases from zero to a constant.–When [A] and [B] are constant, equilibrium
is achieved.
A B
A System at Equilibrium
Once equilibrium is achieved, the amount of each reactant and product remains constant.
Dynamic EquilibriumThe reaction can go both ways. You make
something with two reactants and a product and you can reverse it to get what you started with.
• O2 bonds with a free Oxygen to produce O3 or ozone, O3 breaks down to O2 and a free O
• If the reaction can only go one way such as burning paper it is not dynamic.
Equilibrium is a case where the reaction does not go to completion, but wavers back and forth.
Imagine a system like that to the left…people want to move where there is lots of land and food. Once there is an even number of people in each area they will move in and out of the areas at the same rate.
The Equilibrium Constant• No matter the starting composition of reactants and
products, the same ratio of concentrations is achieved at equilibrium.
• For a general reaction
the equilibrium constant expression is
where Keq is the equilibrium constant.
aA + bB(g) pP + qQ
ba
qp
eqKBA
QP
In an equilibrium reaction, the concentration of the products goes on the top and the concentrations of the reactants go on the bottom. Remember to include the coefficients.
The Equilibrium Expression• Write the equilibrium expression for the
following reaction:
N2(g) + 3H2(g) 2NH3(g)
The Equilibrium ConstantThe Equilibrium Constant in Terms of Pressure• If KP is the equilibrium constant for reactions
involving gases, we can write:
• KP is based on partial pressures measured in atmospheres.
ba
qp
PPP
PPK
BA
QP
The Equilibrium Constant
CaCO3(s) CaO(s) + CO2(g)
Heterogeneous Equilibria• When all reactants and products are in
one phase, the equilibrium is homogeneous.
• If one or more reactants or products are in a different phase, the equilibrium is heterogeneous.
• Consider:
– experimentally, the amount of CO2 does not seem to depend on the amounts of CaO and CaCO3. Why?
The Equilibrium ConstantHeterogeneous Equilibria• Neither density nor molar mass is a variable, the
concentrations of solids and pure liquids are constant. (You can’t find the concentration of something that isn’t a solution!)
• We ignore the concentrations of pure liquids and pure solids in equilibrium constant expressions.
• The amount of CO2 formed will not depend greatly on the amounts of CaO and CaCO3 present.
Keq = [CO2]
CaCO3(s) CaO(s) + CO2(g)
Calculating Equilibrium Constants• Steps to Solving Problems:
1. Write an equilibrium expression for the balanced reaction.
2. Write an ICE table. Fill in the given amounts.
3. Use stoichiometry (mole ratios) on the change in concentration line.
4. Deduce the equilibrium concentrations of all species.
• Usually, the initial concentration of products is zero. (This is not always the case.)
Applications of Equilibrium ConstantsPredicting the Direction of Reaction• We define Q, the reaction quotient, for a reaction at
conditions NOT at equilibrium
as
where [A], [B], [P], and [Q] are molarities at any time.• Q = K only at equilibrium.
aA + bB(g) pP + qQ
ba
qpQ
BA
QP
The Reaction Quotient (Q)
• To calculate Q, one substitutes the initial concentrations on reactants and products into the equilibrium expression.
• Q gives the same ratio the equilibrium expression gives, but for a system that is not at equilibrium.
Applications of Equilibrium ConstantsPredicting the Direction of Reaction• If Q > K then the reverse reaction must occur
to reach equilibrium (go left)• If Q < K then the forward reaction must occur
to reach equilibrium (go right)
Example Problem: Calculate Concentration
Note the moles into a 10.32 L vessel stuff ... calculate molarity.Starting concentration of HI: 2.5 mol/10.32 L = 0.242 M
2 HI H2 + I2
222
][
]][[
HI
IHKeq
Initial:Change:Equil:
0.242 M 0 0 -2x +x +x0.242-2x x x
32
2
21026.1
]2242.0[]2242.0[
]][[
xx
x
x
xxKeq
What we are asked for here is the equilibrium concentration of H2 ... ... otherwise known as x. So, we need to solve this beast for x.
Example Problem: Calculate Concentration
32
2
1026.1]2242.0[
xx
x
232 ]2242.0[1026.1 xxx
]4968.00586.0[1026.1 23 xxx
2335 1004.51022.11038.7 xxxxx
01038.71022.1995.0 532 xxxx
And yes, it’s a quadratic equation. Doing a bit of rearranging:
a
acbbx
2
42
x = 0.00802 or –0.00925Since we are using this to model a real, physical system,we reject the negative root.The [H2] at equil. is 0.00802 M.
Example
Initial Concentration of I2: 0.50 mol/2.5L = 0.20 MI2 2 I
Initialchangeequil:
0.20 0-x +2x0.20-x 2x 10
2
10
2
2
1094.2]20.0[
]2[
1094.2][
][
xx
x
xI
IKeq
With an equilibrium constant that small, whatever x is, it’s nearzero, and 0.20 minus zero is 0.20 (like a million dollars minus a nickel is still a million dollars).
0.20 – x is the same as 0.20
102
1094.220.0
]2[ xx
x = 3.83 x 10-6 M
More than 3orders of mag.between thesenumbers. The simplification willwork here.
Example
Initial Concentration of I2: 0.50 mol/2.5L = 0.20 MI2 2 I
Initialchangeequil:
0.20 0-x +2x0.20-x 2x 209.0
]20.0[
]2[
209.0][
][
2
2
2
x
x
I
IKeq These are too close to
each other ... 0.20-x will not betrivially close to 0.20here.
Looks like this one has to proceed through the quadratic ...
Le Chatlier’s Principle:
Changing the environment of the reaction will shift the reaction in the direction favored by the environment.
There are 3 ways to shift an equilibrium reaction:
1. Change the concentration of the reactants or products,
2. Change the temperature of the system.
3. Change the pressure of the system.
• Disturbing an equilibrium will make the reaction start up again to regain its equilibrium. Reactants, products, or heat can be added or removed to disturb and equilibrium.
• CaCO3 CaO + CO2
• If you remove CO2, more CaCO3 will break down to restore the equilibrium.
• Chemical engineers use this principle to produce huge amounts of different product.
Adding products to the system will cause the products to change back into the reactants.
Changing the concentration of the products will shift the reaction to the left, making more reactants.
Adding reactants will cause the reaction to continue and make more products.
Changing the concentration of the reactants will shift the reaction to the right (make more products).
Adding pressure will cause the reaction to go to the side with fewer molecules.
• In the case below, 4 reactant molecules make up 2 product molecules. Adding pressure to this system will cause the reaction to continue making products.
• In the case of sugar (C6H12O6) and 6 O2 reacting and changing into 6 CO2 and 6 H2O, there are only 7 reactant molecules and 12 product molecules. Adding pressure to this system would cause the reactants to be formed, not the products.
This happens cuz there is more space for fewer molecules. Rarely does the size of the molecule really matter.
As pressure is lessened, the reaction will reverse because there is more space. The 4 reactant molecules will be favored over the 2
product molecules, because the container wants to be full.
In the case of sugar (C6H12O6) and 6 O2 reacting and changing into 6 CO2 and 6 H2O, as pressure is released, the reaction will make more products, because there is enough space for them.
Temperature can change the direction of the reaction.
If the reaction is exothermic, as in the case above, and heat is added to the system, the reaction will make more reactants than products.
If the reaction is exothermic and heat is removed (the system is made cooler) as below, the reaction will continue to make products.
Solubility Product Principle
• Another equilibrium situation is slightly soluble products
• Ksp is the solubility product constant
• Ksp can be found on a chart at a specific temperature
• Since the product is solid on the left side, only the products (ions) are involved in the Ksp expression
Solubility Product (Ksp) = [products]x/[reactants]y but.....
reactants are in solid form, so Ksp=[products]x
i.e. A2B3(s) 2A3+ + 3B2– Ksp=[A3+]2 [B2–]3
Given: AgBr(s) Ag+ + Br–
In a saturated solution @25oC, the [Ag+] = [Br– ]= 5.7 x 10–7 M. Determine the Ksp value.
-132-7sp 10x 3.3 10x 7.5Br AgK
Problem: A saturated solution of silver chromate was to found contain 0.022 g/L of Ag2CrO4. Find Ksp
Eq. Expression: Ag2CrO4 (s) 2Ag+ + CrO42–
Ksp = [Ag+]2[CrO42–]
So we must find theconcentrations of each
ion and then solvefor Ksp.
Problem: A saturated solution of silver chromate was to contain 0.022 g/L of Ag2CrO4. Find Ksp
Eq. Expression: Ag2CrO4 (s) 2Ag+ + CrO42–
Ksp = [Ag+]2[CrO42–]
Ag+: L
Agmol
0.022 g Ag2CrO4
L g332
mol
42CrO Ag1
Ag2
1.33 x 10–4
CrO4–2: 0.022g Ag2CrO4
L L
CrO mol
-24
g 332
mol4
-24
AgCrO1
CrO 16.63 x 10–5
-12-52-4sp 10x 1.16 10x 63.610x 33.1K
Problems working from Ksp values.
Given: Ksp for MgF2 is 6.4 x 10–9 @ 25 oC
Find: solubility in mol/L and in g/L
MgF2(s) Mg2+ + 2F– Ksp = [Mg2+][F–]2
I.C.E.
N/A 0 0N/A +x +2xN/A +x +2x
Ksp= [x][2x]2 = 4x3
6.4 x 10–9 = 4x3
223-3
-9
MgF Mg 10x 1.2 4
10x 4.6 x
now for g/L:L
MgF mol10x 2.1 2-3
L
MgF g 2
mol
g 62.3 7.3 x 10–2
Solubility Product Principle• Example: Find the concentration of ions present in calcium
fluoride (in water) and the molar solubility.CaF2(s) --> Ca+2 + 2 F-
Ksp = [Ca+2] [F-]2 = 2 X 10 -10
If x = [Ca+2 ], then [F-] = 2x [x] [2x]2 = 2 X 10 -10
4x3 = 2 X 10 -10
x3 = 5 X 10 -11
x = 3.68 X 10 -4
[Ca+2 ] = x = 3.68 X 10 -4 [F-] = 2x = 7.37 X 10 -4
Solubility of CaF2 = 3.68 X 10 -4
Practice: Write the equilibrium expression and calculate the equilibrium constant for each of the following reactions.
1. Zn + 2HCl ZnCl2 + H2 Concentrations: Zn = 4M, HCl = 8M, ZnCl2 = 3M, H2 = 10M
2. C3H8 + 5O2 3CO2 + 4H2O Concentrations: H2O = 7M, O2 = 5M, C3H8 = 1.5M, CO2 = 2.6M
3. HCl + NaOH NaCl + H2O Concentrations: H2O = 4.5M, HCl = 10.10M, NaCl = 0.5M, NaOH = 0.99M
4. 2NO2 + 2H2 N2 + 2H2O Concentrations: NO2 = 0.56M, H2 = 1.01M, N2 = 0.05M, H2O = 0.9M.
Practice: Given the information below, write the chemical equilibrium reaction and figure out the chemical equilibrium constant. Will each reaction favor the reactants or products?
1. 5M of Co reacts with 3M of Cl2 to form 8M of CoCl2.
2. 0.5M H2O and 0.5M NaCl are formed when 8M HCl and 4M of Na2O are reacted.
3. 3M of K2Cr2O7 and 4M of HCl react to form 1M KCl, 2M CrCl2, 3M H2O, and 4M Cl2.