Quantitative Changes in Equilibrium Systems. Quick review of concepts so far… Chemical equilibria...
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Transcript of Quantitative Changes in Equilibrium Systems. Quick review of concepts so far… Chemical equilibria...
Quantitative Changes in Equilibrium Systems
Quick review of concepts so far…
• Chemical equilibria are dynamic equilibria
- Forward and reverse reaction rates are equal- Concentrations of reactants and products
remain constant over time
Review cont’d…..
Dynamic equilibrium- Reaction appears stopped at the macroscopic
scale (e.g. no more change in colour, T, ph, etc.)- Reaction is continuing at the atomic
(microscopic) scale but at equal reverse and forward rates
Review cont’d
Conditions for equilibrium- Closed system- Reaction must be directly reversible- Identical reaction conditions
• Equilibrium positionThe relative concentrations of reactants and
products in a system in dynamic equilibrium
Calculating [ ] in equilibria
Use the ICE table given initial and at least one equilibrium [ ]
2NOCl(g) ----> 2NO(g) + Cl2(g)I 2.0 0 0C -2x + 2x xE 2.0 - 2x 2x x
The math of equilibria
Equilibrium Law (or Law of Mass Action)- Mathematical description of chemical system
at equilibrium
Equilibrium constant – the value that defines the equilibrium law for a given system (unitless)
Calculating K
• Does not change regardless of initial [ ] at given T• Does change with T change• Only true for elementary processes
Quick review of concepts so far…
• Magnitude of K
K>1 favours K=1 K< 1Products same [ ] favours
reactants
Review….
Homogeneous vs. heterogeneous equilibria
Homogeneous – same state of matter
Heterogeneous – reactants and products are present in more than one state
K in heterogeneous systems only depends on the [ ] of the gases since the [ ] of liquids and solids does not change
Review of Le Chatelier’s Principle
When a system in equilibrium is disturbed, it responds in the opposite manner (equilibrium shift)
1.Concentration changes2.Energy changes (exothermic and endothermic)3.Gas volume/pressure changesWhat about catalysts and addition of inert gases?
Applications of chemical equilibria
Hemoglobin and oxygen exist in equilibrium in the blood:
Hb(aq) + 4O2(g) Hb(O⇋ 2)4(aq)
At high altitudes, there is a lack of oxygen, equilibrium shifts where?
As a result , a person tends to feel light-headed.
What would an oxygen tank do to the equilibrium? What about someone who is born at high altitude? climbers
CO poisoningCO forms stronger bonds with Hb than O2
Hb(aq) + 4CO(g) Hb(CO)⇋ 4(aq) (new equilibrium)
No longer available to carry O2, can be fatalIntroducing O2 shifts the equilibrium
Hb(CO)4(aq) + 4O2(g) Hb(O⇋ 2)4(aq) + 4CO(g)
Equilibrium shift to ? CO is exhaled…..
Methanol production
Methanol is an important alcohol used in industrial processes
CO(g) + 2H2(g) CH3OH(g) (ΔH = -90 kJ mol-1)
What conditions would provide the highest yields? -
Quantitative changesWhat if a system is not @ equilibrium?
The reaction quotient, Q, can be used to analyze a chemical reaction that is not at equilibrium.
Q can determine:If the system is at equilibrium or notIf not at equilibrium, which way will the system shifte.g. if only reactants are present, then reactions will
shift to the rightBut if both reactants and products are present,
which way?
Reaction quotient
Q is the ratio of the product of the concentrations of the products to the product of the concentrations of the reactants
It is calculated using instantaneous concentrations – [ ] that correspond to a particular point in time.
Q
For the general reaction aA(g) + bB(g) < = > cC(g) + dD(g)
the reaction quotient is expressed as Q = [C]c[D]d/ [A]a[B]b
Just like K but system may not be at equilibrium
Can use concentrations or partial pressures to get Q
Relationship of Q to K
If Q = K, the system is at equilibrium
If Q> K, the system must shift to the left ([products] must decrease, [reactants] increase)
If Q< K, the system must shift to the right
Calculating Q
In order to determine Q we need to know: • the equation for the reaction, including the physical
states, • the quantities of each species (molarities and/or
pressures), all measured at the same moment in time.To calculate Q: • Write the expression for the reaction quotient. • Find the molar concentrations or partial pressures of
each species involved. • Substitute values into the expression and solve.
Example: 0.035 moles of SO2, 0.500 moles of SO2Cl2, and 0.080 moles of Cl2 are combined in an evacuated 5.00 L flask and heated to 100oC. What is Q before the reaction begins? Which direction will the reaction proceed in order to establish equilibrium? SO2Cl2(g) SO2(g) + Cl2(g) K = 0.078 at 100oC
• Write the expression to find the reaction quotient, Q. • Since K is given, the amounts must be expressed as moles
per liter. The amounts are in moles so a conversion is required.
• 0.500 mole SO2Cl2/5.00 L = 0.100 M SO2Cl2 0.035 mole SO2/5.00 L = 0.070 M SO2 0.080 mole Cl2/5.00 L = 0.016 M Cl2
• Substitute the values in to the expression and solve for Q. • Compare the answer to the value for the equilibrium
constant and predict the shift.
• Write the expression to find the reaction quotient, Q.
• Since K is given, the amounts must be expressed as moles per liter. The amounts are in moles so a conversion is required.
• 0.500 mole SO2Cl2/5.00 L = 0.100 M SO2Cl2 0.035 mole SO2/5.00 L = 0.070 M SO2 0.080 mole Cl2/5.00 L = 0.016 M Cl2
Substitute the values in to the expression and solve for Q.
Compare the answer to the value for the equilibrium constant and predict the shift.
• 0.078 (K) > 0.011 (Q) Since K >Q, the reaction will proceed in the forward direction in order to increase the concentrations of both SO2 and Cl2 and decrease that of SO2Cl2 until Q = K.