Chemical Equilibrium
What is Chemical Equilibrium?
Chemical equilibrium is a state in a chemical reaction where the concentrations of the reactants and products remain constant, with no net change in the amounts of the substances present.
Chemical equilibrium refers to a state in which the concentrations of reactants and products remain constant over time, and the system displays no further change in properties.
Table of Contents
Factors Affecting Chemical Equilibrium
Examples of Chemical Equilibrium
What is the Importance of Chemical Equilibrium?
Problems on Chemical Equilibrium
When the rate of the forward reaction is equal to the rate of the reverse reaction, the system is said to be in a state of chemical equilibrium. No further change in the concentrations of the reactants and the products occurs due to the equal rates of the forward and reverse reactions, and the system is said to be in a state of dynamic equilibrium.
State of Chemical Equilibrium
A graph with the concentration on the y-axis and time on the x-axis can be plotted. Once the concentration of both the reactants and the products stops showing change, chemical equilibrium is achieved.
What is Dynamic Equilibrium in Chemical Equilibrium?
At equilibrium, the rate of the forward reaction is equal to the rate of the backward reaction. This means that the number of reactant molecules converting into products and product molecules into reactants are the same. However, the same equilibrium can be maintained in different conditions, with continuous interchanging of molecules, thus making chemical equilibrium dynamic.
Introduction to Chemical Equilibrium
Chemical Equilibrium
Types of Chemical Equilibrium
There are two types of chemical equilibrium:
- Dynamic equilibrium
- Static equilibrium
Bold Homogeneous Equilibrium
Heterogeneous Equilibrium
Homogeneous Chemical Equilibrium
In this type, the reactants and the products of chemical equilibrium are all in the same phase. Homogenous equilibrium can be further divided into two types: Reactions in which the number of molecules of the products is equal to the number of molecules of the reactants. For example,
2H₂(g) + I₂(g) ⇌ 2HI(g)
2N2(g) + O2(g) ⇌ 2NO2(g)
Reactions in which the number of molecules of the products is not equal to the total number of reactant molecules are known as unequal-molecule reactions. For example,
2SO2 (g) + O2 (g) → 2SO3 (g)
COCl2 (g) <=> CO (g) + Cl2 (g)
Heterogeneous Chemical Equilibrium
Examples of heterogeneous equilibrium include:
- Dissolution of ammonia in water
- Formation of silver chloride
- Formation of Iron (III) hydroxide
2CO (g) ⇌ CO2 (g) + C (s)
CaCO3 (s) <=> CaO (s) + CO2 (g)
Thus, the different types of chemical equilibrium are based on the phase of the reactants and products.
⇒ Check: Ionic Equilibrium
Factors Affecting Chemical Equilibrium
Factors Affecting Chemical Equilibrium
According to Le-Chatelier’s principle, if there is any alteration in the components influencing the equilibrium conditions, the system will attempt to counter or minimize the influence of the overall transformation. This rule is applicable to both chemical and physical equilibrium.
Some of the important factors affecting chemical equilibrium are temperature, pressure, and concentration of the system.
Change in Concentration: denotes italics
This is an example of italicized text.
The concentration of the reactants or products is reduced by the reaction, which consumes the substance that was added.
The reaction proceeds in a direction that replenishes the substance which has been removed, thus relieving the concentration of reactants or products.
When the concentration of the reactant or product is altered, the composition of the mixture in chemical equilibrium is affected.
Impact of Change in Concentration
Change in Pressure:
If the volume changes, then the pressure will also change. This can have an effect on gaseous reactions as the number of gaseous reactants and products will be different. However, according to Le Chatelier’s principle, changes in pressure in both liquids and solids can be ignored as the volume is not affected by pressure.
Impact of Alterations in Volume of Equilibrium Mixture
Increase in Temperature:
Le Chatelier’s Principle states that the effect of temperature on chemical equilibrium depends upon the sign of ΔH of the reaction.
As temperature increases, the equilibrium constant of an exothermic reaction decreases.
In an endothermic reaction, an increase in temperature leads to an increase in the equilibrium constant.
As per Le Chatelier’s principle, the rate of reaction as well as the equilibrium constant are both affected by the change in temperature. In the case of exothermic reactions, the equilibrium shifts towards the reactant side when the temperature increases, whereas for endothermic reactions, the equilibrium shifts towards the product side with an increase in temperature.
Impact of a Catalyst:
A catalyst does not affect the chemical equilibrium; it only speeds up a reaction. In fact, catalyst equally speeds up the forward as well as the reverse reaction. As a result, the reaction reaches its equilibrium faster.
The same amount of reactants and products will be present at equilibrium in a catalysed or a non-catalysed reaction; however, the presence of a catalyst will reduce the energy required to reach equilibrium. The catalyst allows the reaction to proceed through a lower-energy transition state of reactants to products.
Impact of Adding an Inert Gas
When an inert gas like argon is added to a constant volume, it does not take part in the reaction, so the equilibrium remains undisturbed. However, if the gas added is a reactant or product involved in the reaction, then the reaction quotient will change.
Effects of Adding an Inert Gas
Examples of Chemical Equilibrium
- Haber Process
- Ammonia Synthesis
- Nitric Acid Production
- Carbonic Acid-Bicarbonate Buffer System
Reactants and Products are two states in a chemical reaction; the forward reaction converts reactants into products, while the backward reaction converts products back into reactants. These two states are different in composition.
After some time of the start of the reaction, the rate of the forward and the backward reactions may become equal. At this point, the number of reactants converted will be reformed by the reverse reaction such that the concentration of reactants and products remain constant. Therefore, the reactants and products are in chemical equilibrium.
2NO2 ⇌ N2O4
PCl3 + PCl2 ⇌ PCl5
2N_2 + 3H_2 ⇌ 4NH_3
The Significance of Chemical Equilibrium
It is useful in many industrial processes such as
Preparation of Ammonia by Haber’s Process: In this process, nitrogen combines with hydrogen to form ammonia. The yield of ammonia is higher at lower temperatures, higher pressure, and in the presence of iron as a catalyst.
Preparation of Sulphuric Acid by Contact Process: In this process, the fundamental reaction is the oxidation of Sulphur Dioxide (SO2) into Sulphur Trioxide (SO3). This involves a chemical equilibrium.
Equilibrium Solved Questions
Top 7 Questions on Ionic Equilibrium
Problems on Chemical Equilibrium
1. The equilibrium constant KP for the reaction N2 (g) + 3H2 (g) ⇌ 2NH3 (g) at 500oC, given that the heat of the reaction at this temperature range is -25.14 kcal, is estimated to be 1.06 × 10-4atm-2.
Given:
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Solution:
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The equation relating equilibrium constants at different temperatures and the heat of the reaction is:
log KP2 = -25140/2.303 × 2 \[773 - 673 / 773 × 673\] + log 1.64 × 10^{-4}
log_{KP2} = -4.835
KP2 = 1.462 × 10-5 atm-2
Given the equation, N2 (g) + 3H2 (aq) ⇌ 2NH3 (g), Find Q and determine which direction the reaction will shift in order to reach the state of chemical equilibrium:
To find Q, we need to calculate the concentrations of each species at equilibrium. Once we have these values, we can plug them into the equilibrium expression to calculate Q. Once we have Q, we can compare it to K, the equilibrium constant, to determine which direction the reaction will shift in order to reach the state of chemical equilibrium.
Given:
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Solution:
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Given, [N2] = 0.04M, [H2] = 0.09M, and K = 0.040
Since only nitrogen and hydrogen concentrations are given, it can be assumed that they are the reactants and ammonia is the product. Since ammonia concentration is not given, it can be assumed to be zero.
As q is the ratio of the relative concentration of products to reactants, here q = 0.
K > Q, so Nitrogen and Hydrogen will combine to form Ammonia.
Also Read:
Equilibrium By Changing The Concentration
Shift In Equilibrium By Increasing/Decreasing The Concentration Of Ferric Ions And Thiocyanate Ions
Chemical Equilibrium: All Concepts and JEE Questions
Top 15 Most Important and Expected JEE Questions on Equilibrium
Frequently Asked Questions (FAQs)
How does temperature affect the equilibrium constant of an exothermic reaction?
The effect of a catalyst on a chemical equilibrium is to shift the equilibrium in the direction that favors the reaction with the lower activation energy, thus increasing the rate of the reaction and allowing it to reach equilibrium faster.
A catalyst has no effect on the chemical equilibrium.
What is the effect of addition of an inert gas during chemical equilibrium?
There is no effect on chemical equilibrium on addition of inert gas. What is meant by forward reaction?
A backward reaction is a reaction in which the products are converted to reactants.
A reaction in which the reactants are converted back to products is called a backward reaction.
JEE NCERT Solutions (Chemistry)
- Acid And Base
- Actinides
- Alkali Metals
- Alkaline Earth Metals
- Atomic Structure
- Buffer Solutions
- Chemical Equilibrium
- Chemistry In Everyday Life
- Coordination Compounds
- Corrosion
- Covalent Bond
- D Block Elements
- Dynamic Equilibrium
- Equilibrium Constant
- F Block Elements
- Fajans Rule
- Group 13 Elements
- Group 14 Elements
- Hardness Of Water
- Heavy Water
- Hybridization
- Hydrides
- Hydrocarbons
- Hydrogen Bonding
- Hydrogen Peroxide
- Hydrolysis Salts And Types
- Inductive Effect
- Ionic Equilibrium
- Lassaigne Test
- Le Chateliers Principle
- Molecular Orbital Theory
- Organic Chemistry
- Ph And Solutions
- Ph Scale And Acidity
- Physical Equilibrium
- Polymers
- Properties Of Hydrogen
- Purification Of Organic Compounds
- Qualitative Analysis Of Organic Compounds
- Redox Reaction
- S Block Elements
- Solubility And Solubility Product
- Surface Chemistry
- Victor Meyers Method
- Vsepr Theory