Presentation is loading. Please wait.

Presentation is loading. Please wait.

Predicting Equilibrium QCQC. Determine the reaction quotient for a system. Determine if a system is at equilibrium and, if not, which reaction is favoured.

Published byCandice George Modified over 9 years ago

Similar presentations

Presentation on theme: "Predicting Equilibrium QCQC. Determine the reaction quotient for a system. Determine if a system is at equilibrium and, if not, which reaction is favoured."— Presentation transcript:

1 Predicting Equilibrium QCQC

2 Determine the reaction quotient for a system. Determine if a system is at equilibrium and, if not, which reaction is favoured.

3 The reaction quotient, Q enables us to determine if a reaction has reached equilibrium - trial K C Q is compared to the know K c for the reaction. It also indicates which reaction, forward or reverse, must continue (favoured) in order for equilibrium to be achieved. Q is calculated exactly like K c - using the concentrations at that moment.

4 Q = K c The system is at equilibrium. Forward rate = Reverse rate Concentrations remain constant Q = 5.0 K c = 5.0 Q Reactants Products

5 Q > K C The system is NOT at equilibrium. Reverse reaction is favoured. Must increase reactant concentration. Q = 10 K c = 1.0 Q Reactants Products

6 Q < K C The system is NOT at equilibrium. The forward reaction is favoured. Must increase product concentrations. Q = 0.1 K c = 1.0 Q Reactants Products

7 K c = 3.9 x 10 -2 Is the system at equilibrium with: [HI] = 0.75 M[H 2 ] = 0.14 M[I 2 ] = 0.10 M If not, which reaction must continue for equilibrium to be established? 2 HI (g) ↔ H 2 (g) + I 2 (g) Q c = [H 2 ][I 2 ] [HI] 2

8 Q C = 2.5 x 10 -2 K C = 3.9 x 10 -2 Q < K This means the system is NOT at equilibrium. The forward reaction is favoured – must continue [HI] is decreasing, [H 2 ] and [I 2 ] are increasing. Q c = [0.14][0.10]= 2.5 x 10 -2 [0.75] 2 [H 2 ][I 2 ] [HI] 2 QcQc =

9 After 2 hrs the reaction was checked - 8.50 moles N 2, 11.0 moles O 2 and 2.20 moles NO, in a 5.00 L container. If K c = 0.035, is the system at equilibrium? Which reaction is favoured? Which concentrations are increasing/decreasing? N 2(g) + O 2(g) 2 NO (g)

10

11 Q = 0.0518 K = 0.035 Q >K This means the system is NOT at equilibrium. The reverse reaction is favoured. [NO] is decreasing, [O 2 ] and [N 2 ] are increasing.

Download ppt "Predicting Equilibrium QCQC. Determine the reaction quotient for a system. Determine if a system is at equilibrium and, if not, which reaction is favoured."

Similar presentations

The Reaction Quotient, “Q”

The Reaction Quotient, “Q”
When do you use this? You use Keq to find the concentration of a reversible reaction at equilibrium. You use Q to find the concentration of a reversible.

When do you use this? You use Keq to find the concentration of a reversible reaction at equilibrium. You use Q to find the concentration of a reversible.
Equilibrium and Le Chatelier’s Principle

Equilibrium and Le Chatelier’s Principle
Chemical Equilibrium Unit 2.

Chemical Equilibrium Unit 2.
Chapter 12 Gaseous Chemical Equilibrium. The Concept of Equilibrium Chemical equilibrium occurs when a reaction and its reverse reaction proceed at the.

Chapter 12 Gaseous Chemical Equilibrium. The Concept of Equilibrium Chemical equilibrium occurs when a reaction and its reverse reaction proceed at the.
Chapter 15 Chemical Equilibrium. The Concept of Equilibrium Chemical equilibrium occurs when a reaction and its reverse reaction proceed at the same rate.

Chapter 15 Chemical Equilibrium. The Concept of Equilibrium Chemical equilibrium occurs when a reaction and its reverse reaction proceed at the same rate.
Equilibrium Chapter 15 Chemical Equilibrium. Equilibrium What is a chemical equilibrium? The reaction of hemoglobin with oxygen is a reversible reaction.

Equilibrium Chapter 15 Chemical Equilibrium. Equilibrium What is a chemical equilibrium? The reaction of hemoglobin with oxygen is a reversible reaction.
Applications of Equilibrium Constants. Example For the reaction below 2A + 3B  2C A 1.5L container is initially charged with 2.3 mole of A and 3.0 mole.

Applications of Equilibrium Constants. Example For the reaction below 2A + 3B  2C A 1.5L container is initially charged with 2.3 mole of A and 3.0 mole.
Chemical Equilibrium Chapter 18 Consider a glass of water… Evaporation.

Chemical Equilibrium Chapter 18 Consider a glass of water… Evaporation.
CHEMISTRY DEPARTMENT WAID ACADEMY EQUILIBRIUM. Which description shows the effect of a catalyst on the reaction rate and position of equilibrium in a.

CHEMISTRY DEPARTMENT WAID ACADEMY EQUILIBRIUM. Which description shows the effect of a catalyst on the reaction rate and position of equilibrium in a.
Equilibrium Calculations Chapter 15. Equilibrium Constant Review consider the reaction, The equilibrium expression for this reaction would be K c = [C]

Equilibrium Calculations Chapter 15. Equilibrium Constant Review consider the reaction, The equilibrium expression for this reaction would be K c = [C]
Chemical Equilibrium Unit 11. My Chemistry Presentation Chemical Reactions We usually think of chemical reactions as having a beginning and an end. reactants.

Chemical Equilibrium Unit 11. My Chemistry Presentation Chemical Reactions We usually think of chemical reactions as having a beginning and an end. reactants.
Factors that Affect Equilibrium Concentrations!. 2 Le Chatalier’s Principle The first person to study and comment on factors that change equilibrium concentrations.

Factors that Affect Equilibrium Concentrations!. 2 Le Chatalier’s Principle The first person to study and comment on factors that change equilibrium concentrations.
Graph Interpretation Mr. Chapman Chemistry 30. Graph Reading is an Important Skill Particularly in chemistry, it is important for us to be able to look.

Graph Interpretation Mr. Chapman Chemistry 30. Graph Reading is an Important Skill Particularly in chemistry, it is important for us to be able to look.
2 Equilibria 2.1 Chemical Equilibrium (and Equilibrium Constant) 2.2 Calculations using Kc expressions 2.3 Effect of changing conditions on equilibria.

2 Equilibria 2.1 Chemical Equilibrium (and Equilibrium Constant) 2.2 Calculations using Kc expressions 2.3 Effect of changing conditions on equilibria.
General, Organic, and Biological Chemistry Copyright © 2010 Pearson Education, Inc. 1 Chapter 9 Chemical Equilibrium 9.5 Changing Equilibrium Conditions:

General, Organic, and Biological Chemistry Copyright © 2010 Pearson Education, Inc. 1 Chapter 9 Chemical Equilibrium 9.5 Changing Equilibrium Conditions:
Section 8.3—Reaction Quotient

Section 8.3—Reaction Quotient
Chemical Equilibrium K p (gases) and heterogeneous equilibria Chapter 13: Sections 3 & 4 AP.

Chemical Equilibrium K p (gases) and heterogeneous equilibria Chapter 13: Sections 3 & 4 AP.
Equilibrium Calculations. How can we describe an equilibrium system mathematically? reactants products ⇌ reactants The Keq is the equilibrium constant-

Equilibrium Calculations. How can we describe an equilibrium system mathematically? reactants products ⇌ reactants The Keq is the equilibrium constant-
Some reactions go to completion Some reactions go to completion A precipitate forms A precipitate forms A gas forms A gas forms CH 4 (g) + O 2 (g)  CO.

Some reactions go to completion Some reactions go to completion A precipitate forms A precipitate forms A gas forms A gas forms CH 4 (g) + O 2 (g)  CO.

Similar presentations

Ads by Google