Case Study Questions Class 11 Chemistry Chapter 7 Equilibrium
CBSE Class 11 Case Study Questions Chemistry Equilibrium. Important Case Study Questions for Class 11 Board Exam Students. Here we have arranged some Important Case Base Questions for students who are searching for Paragraph Based Questions Equilibrium.
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CBSE Case Study Questions Class 11 Chemistry Equilibrium
Case Study – 1
When a liquid evaporates in a closed container, molecules with relatively higher kinetic energy escape the liquid surface into the vapour phase and number of liquid molecules from the vapour phase strike the liquid surface and are retained in the liquid phase. It gives rise to a constant vapour pressure because of an equilibrium in which the number of molecules leaving the liquid equals the number returning to liquid from the vapour. We say that the system has reached equilibrium state at this stage. However, this is not static equilibrium and there is a lot of activity at the boundary between the liquid and the vapour. Thus, at equilibrium, the rate of evaporation is equal to the rate of condensation. It may be represented by
H2O(l) ⇌ H2O(vap)
The double half arrows indicate that the processes in both the directions are going on simultaneously. The mixture of reactants and products in the equilibrium state is called an equilibrium mixture.
Equilibrium can be established for both physical processes and chemical reactions. The reaction may be fast or slow depending on the experimental conditions and the nature of the reactants. When the reactants in a closed vessel at a particular temperature react to give products, the concentrations of the reactants keep on decreasing, while those of products keep on increasing for some time after which there is no change in the concentrations of either of the reactants or products. This stage of the system is the dynamic equilibrium
The chemical equilibrium may be classified in three groups.
i) The reactions that proceed nearly to completion and only negligible concentrations of the reactants are left. In some cases, it may not be even possible to detect these experimentally.
ii) The reactions in which only small amounts of products are formed and most of the reactants remain unchanged at equilibrium stage.
(iii) The reactions in which the concentrations of the reactants and products are comparable, when the system is in equilibrium.
The equilibrium involving ions in aqueous solutions which is called as ionic equilibrium.
Solid-Liquid Equilibrium Ice and water kept in a perfectly insulated thermos flask (no exchange of heat between its contents and the surroundings) at 273K and the atmospheric pressure are in equilibrium state and the system shows interesting characteristic features. We observe that the mass of ice and water do not change with time and the temperature remains constant. However, the equilibrium is not static. The intense activity can be noticed at the boundary between ice and water. Molecules from the liquid water collide against ice and adhere to it and some molecules of ice escape into liquid phase. There is no change of mass of ice and water, as the rates of transfer of molecules from ice into water and of reverse transfer from water into ice are equal at atmospheric pressure and 273 K. It is obvious that ice and water are in equilibrium only at particular temperature and pressure. For any pure substance at atmospheric pressure, the temperature at which the solid and liquid phases are at equilibrium is called the normal melting point or normal freezing point of the substance. The system here is in dynamic equilibrium and we can infer the following: (i) Both the opposing processes occur simultaneously.
(ii) Both the processes occur at the same rate so that the amount of ice and water remains constant.
Solid – Vapour Equilibrium Let us now consider the systems where solids sublime to vapour phase. If we place solid iodine in a closed vessel, after sometime the vessel gets filled up with violet vapour and the intensity of colour increases with time. After certain time the intensity of colour becomes constant and at this stage equilibrium is attained. Hence solid iodine sublimes to give iodine vapour and the iodine vapour condenses to give solid iodine. The equilibrium can be represented as,
I2(solid) ⇌ I2(vapour)
Other examples showing this kind of equilibrium are,
Camphor(solid) ⇌ Camphor(vapour)
NH4Cl(solid) ⇌ NH4Cl(vapour)
The equilibrium Involving Dissolution of Solid in Liquids Only a limited amount of salt or sugar can dissolves in a given amount of water at room temperature. If we make a thick sugar syrup solution by dissolving sugar at a higher temperature, sugar crystals separate out if we cool the syrup to the room temperature. We call it a saturated solution when no more of solute can be dissolved in it at a given temperature. The concentration of the solute in a saturated solution depends upon the temperature. In a saturated solution, a dynamic equilibrium exits between the solute molecules in the solid state and in the solution: Sugar (solution) Sugar (solid), and the rate of dissolution of sugar = rate of crystallisation of sugar. Equality of the two rates and dynamic nature of equilibrium has been confirmed with the help of radioactive sugar. If we drop some radioactive sugar into saturated solution of non-radioactive sugar, then after some time radioactivity is observed both in the solution and in the solid sugar. Initially there were no radioactive sugar molecules in the solution but due to dynamic nature of equilibrium, there is exchange between the radioactive and non-radioactive sugar molecules between the two phases. The ratio of the radioactive to non- radioactive molecules in the solution increases till it attains a constant value.
[A] MCQ
1) Which of the following symbol represents equilibrium .
a) ⇌
b) ⇆
c) ⇎
d) ⇅
Ans- a) ⇌
2) When there is no change in the concentrations of either of the reactants or products, this stage of the system is the …
a) static equilibrium
b) dynamic equilibrium
c) physical equilibrium
d) chemical equilibrium
Ans- b) dynamic equilibrium
3) A … solution means no more of solute can be dissolved in it at a given temperature.
a) unsaturated
b) supersaturated
c) saturated
d) None of these.
Ans- c) saturated
4) The equilibrium involving ions in aqueous solutions which is called as …
a) static equilibrium
b) dynamic equilibrium
c) physical equilibrium
d) ionic equilibrium
Ans- d) ionic
5) The concentration of the solute in a saturated solution depends upon the …
a) solvent
b) pressure
c) temperature
d) system
Ans- c) temperature
[B]Short Answers
1) Explain equilibrium state with suitable example .
Ans- When a liquid evaporates in a closed container, molecules with relatively higher kinetic energy escape the liquid surface into the vapour phase and number of liquid molecules from the vapour phase strike the liquid surface and are retained in the liquid phase. It gives rise to a constant vapour pressure because of an equilibrium in which the number of molecules leaving the liquid equals the number returning to liquid from the vapour. We say that the system has reached equilibrium state at this stage. However, this is not static equilibrium and there is a lot of activity at the boundary between the liquid and the vapour. Thus, at equilibrium, the rate of evaporation is equal to the rate of condensation. It may be represented by
H2O(l) ⇌ H2O(vap)
The double half arrows indicate that the processes in both the directions are going on simultaneously. The mixture of reactants and products in the equilibrium state is called an equilibrium mixture.
2) How chemical equilibrium classified ?
Ans- The chemical equilibrium may be classified in three groups.
i) The reactions that proceed nearly to completion and only negligible concentrations of the reactants are left. In some cases, it may not be even possible to detect these experimentally.
ii) The reactions in which only small amounts of products are formed and most of the reactants remain unchanged at equilibrium stage.
(iii) The reactions in which the concentrations of the reactants and products are comparable, when the system is in equilibrium.
3) Explain Solid- Vapour equilibrium with help of suitable example.
Ans- Consider the systems where solids sublime to vapour phase. If we place solid iodine in a closed vessel, after sometime the vessel gets filled up with violet vapour and the intensity of colour increases with time. After certain time the intensity of colour becomes constant and at this stage equilibrium is attained. Hence solid iodine sublimes to give iodine vapour and the iodine vapour condenses to give solid iodine. The equilibrium can be represented as,
I2(solid) ⇌ I2(vapour)
Other examples showing this kind of equilibrium are,
Camphor(solid) ⇌ Camphor(vapour)
NH4Cl(solid) ⇌ NH4Cl(vapour)
4) What is dynamic equilibrium?
Ans- Equilibrium can be established for both physical processes and chemical reactions. The reaction may be fast or slow depending on the experimental conditions and the nature of the reactants. When the reactants in a closed vessel at a particular temperature react to give products, the concentrations of the reactants keep on decreasing, while those of products keep on increasing for some time after which there is no change in the concentrations of either of the reactants or products. This stage of the system is the dynamic equilibrium .
[C]Long Answers
1) Explain solid liquid equilibrium.
Ans- Ice and water kept in a perfectly insulated thermos flask (no exchange of heat between its contents and the surroundings) at 273K and the atmospheric pressure are in equilibrium state and the system shows interesting characteristic features. We observe that the mass of ice and water do not change with time and the temperature remains constant. However, the equilibrium is not static. The intense activity can be noticed at the boundary between ice and water. Molecules from the liquid water collide against ice and adhere to it and some molecules of ice escape into liquid phase. There is no change of mass of ice and water, as the rates of transfer of molecules from ice into water and of reverse transfer from water into ice are equal at atmospheric pressure and 273 K. It is obvious that ice and water are in equilibrium only at particular temperature and pressure. For any pure substance at atmospheric pressure, the temperature at which the solid and liquid phases are at equilibrium is called the normal melting point or normal freezing point of the substance. The system here is in dynamic equilibrium and we can infer the following: (i) Both the opposing processes occur simultaneously.
(ii) Both the processes occur at the same rate so that the amount of ice and water remains constant.
2) Explain the equilibrium Involving Dissolution of Solid in Liquids with suitable example.
Ans- Only a limited amount of salt or sugar can dissolves in a given amount of water at room temperature. If we make a thick sugar syrup solution by dissolving sugar at a higher temperature, sugar crystals separate out if we cool the syrup to the room temperature. We call it a saturated solution when no more of solute can be dissolved in it at a given temperature. The concentration of the solute in a saturated solution depends upon the temperature. In a saturated solution, a dynamic equilibrium exits between the solute molecules in the solid state and in the solution: Sugar (solution) Sugar (solid), and the rate of dissolution of sugar = rate of crystallisation of sugar. Equality of the two rates and dynamic nature of equilibrium has been confirmed with the help of radioactive sugar. If we drop some radioactive sugar into saturated solution of non-radioactive sugar, then after some time radioactivity is observed both in the solution and in the solid sugar. Initially there were no radioactive sugar molecules in the solution but due to dynamic nature of equilibrium, there is exchange between the radioactive and non-radioactive sugar molecules between the two phases. The ratio of the radioactive to non- radioactive molecules in the solution increases till it attains a constant value.
Case Study – 2
Equilibrium Involving Dissolution of Gases in Liquids- When a soda water bottle is opened, some of The carbon dioxide gas dissolved in it fizzes Out rapidly. The phenomenon arises due to Difference in solubility of carbon dioxide at Different pressures. There is equilibrium Between the molecules in the gaseous state And the molecules dissolved in the liquid Under pressure i.e., CO2 (gas) CO2 (in solution) This equilibrium is governed by Henry’s Law, which states that the mass of a gas Dissolved in a given mass of a solvent at Any temperature is proportional to the Pressure of the gas above the solvent. This Amount decreases with increase of Temperature. The soda water bottle is sealed Under pressure of gas when its solubility in Water is high. As soon as the bottle is opened, Some of the dissolved carbon dioxide gas Escapes to reach a new equilibrium condition Required for the lower pressure, namely its Partial pressure in the atmosphere. This is how The soda water in bottle when left open to the Air for some time, turns ‘flat’. It can be Generalised that: For solid liquid equilibrium, there is Only one temperature (melting point) at 1 atm (1.013 bar) at which the two phases Can coexist. If there is no exchange of heat With the surroundings, the mass of the two Phases remains constant. For liquid vapour equilibrium, the Vapour pressure is constant at a given Temperature. For dissolution of solids in liquids, the Solubility is constant at a given Temperature. For dissolution of gases in liquids, the Concentration of a gas in liquid is Proportional to the pressure (concentration) of the gas over the liquid.
General Characteristics of Equilibria Involving Physical Processes For the physical processes , following characteristics are common to the system at equilibrium:
i) Equilibrium is possible only in a closed system at a given temperature.
ii) Both the opposing processes occur at the same rate and there is a dynamic but stable condition.
(iii) All measurable properties of the system remain constant.
(iv) When equilibrium is attained for a physical process, it is characterised by constant value of one of its parameters at a given temperature.
(v) The magnitude of such quantities at any stage indicates the extent to which the physical process has proceeded before reaching equilibrium.
Chemical reactions reach a state of dynamic equilibrium in which the rates of forward and reverse reactions are equal and there is no net change in composition.
let us consider a general reversible reaction:
A + B ⇌ C + D
where A and B are the reactants, C and D are the products in the balanced chemical equation. On the basis of experimental studies of many reversible reactions, the Norwegian chemists Cato Maximillian Guldberg and Peter Waage proposed in 1864 that the concentrations in an equilibrium mixture are related by the following equilibrium equation, Kc = [C ][ D ]
[A ][ B ]
where Kc is the equilibrium constant and the expression on the right side is called the equilibrium constant expression. The equilibrium equation is also known as the law of mass action because in the early days of chemistry, concentration was called “active mass”.
At a given temperature, the product of Concentrations of the reaction products Raised to the respective stoichiometric Coefficient in the balanced chemical Equation divided by the product of Concentrations of the reactants raised to Their individual stoichiometric coefficients Has a constant value. This is known as The Equilibrium Law or Law of Chemical Equilibrium.
Equilibrium Constant in Gaseous Systems– So far we have expressed equilibrium constant Of the reactions in terms of molar Concentration of the reactants and products, And used symbol, Kc For it. For reactions Involving gases, however, it is usually more Convenient to express the equilibrium Constant in terms of partial pressure. The ideal gas equation is written as,
pV = nRT ⇒ p = n RT
V
Here, p is the pressure in Pa, n is the number Of moles of the gas, V is the volume in m3 And T is the temperature in Kelvin Therefore, n/V is concentration expressed in mol/m3 If concentration c, is in mol/L or mol/dm3 , and p is in bar then p = cRT, We can also write p = [gas]RT. Here, R= 0.0831 bar litre/mol K At constant temperature, the pressure of the gas is proportional to its concentration i.e., p ∝ [gas]
For reaction in equilibrium H2 (g) + I2 (g) → 2HI(g) We can write either
where ∆n = (number of moles of gaseous products) – (number of moles of gaseous reactants) in the balanced chemical equation.
The important features of equilibrium constants as follows:
1) Expression for equilibrium constant is applicable only when concentrations of the reactants and products have attained constant value at equilibrium state.
2) The value of equilibrium constant is independent of initial concentrations of the reactants and products.
3) Equilibrium constant is temperature dependent having one unique value for a particular reaction represented by a balanced equation at a given temperature.
4) The equilibrium constant for the reverse reaction is equal to the inverse of the equilibrium constant for the forward reaction.
5) The equilibrium constant K for a reaction is related to the equilibrium constant of the corresponding reaction, whose equation is obtained by multiplying or dividing the equation for the original reaction by a small integer.
[A] MCQ
1) …. states that the mass of a gas dissolved in a given mass of a solvent at any temperature is proportional to the Pressure of the gas above the solvent.
a) Henry’s Law
b) Charles’s law
c) Boyle’s law
d) Arrhenius law
Ans- a) Henry’s Law
2) For solid liquid equilibrium, there is only one temperature (melting point) at …. at which the two phases can coexist.
a) 1 pascal
b) 1 atm
c) 1 Torr
d) 1 bar
Ans- b) 1 atm
3) Equilibrium is possible only in a …
at a given temperature.
a) open system
b) isolated system
c) closed system
d) None of above
Ans- c) closed system
4) The value of R= …
a) 0138 bar litre/mol K
b) 0381 bar litre/mol K
c) 0318 bar litre/mol K
d) 0831 bar litre/mol K
Ans- d) 0.0831 bar litre/mol K
5) The equilibrium constant K for a reaction is related to the equilibrium constant of the corresponding reaction, whose equation is obtained by …. the equation for the original reaction by a small integer.
a) Adding
b) Multiplying
c) Dividing
d) option b) or c)
Ans- d) option b) or c)
[B]Short Answers
1) Give the General Characteristics of Equilibria Involving Physical Processes.
Ans- For the physical processes , following characteristics are common to the system at equilibrium:
i) Equilibrium is possible only in a closed system at a given temperature.
ii) Both the opposing processes occur at the same rate and there is a dynamic but stable condition.
(iii) All measurable properties of the system remain constant.
(iv) When equilibrium is attained for a physical process, it is characterised by constant value of one of its parameters at a given temperature.
(v) The magnitude of such quantities at any stage indicates the extent to which the physical process has proceeded before reaching equilibrium.
2) Explain the equilibrium constant expression .
Ans- Consider a general reversible reaction:
A + B ⇌ C + D
where A and B are the reactants, C and D are the products in the balanced chemical equation. On the basis of experimental studies of many reversible reactions, the Norwegian chemists Cato Maximillian Guldberg and Peter Waage proposed in 1864 that the concentrations in an equilibrium mixture are related by the following equilibrium equation, Kc = [C ][ D ]
[A ][ B ]
where Kc is the equilibrium constant and the expression on the right side is called the equilibrium constant expression. The equilibrium equation is also known as the law of mass action because in the early days of chemistry, concentration was called “active mass”.
3) Write the important features of equilibrium constants .
Ans- The important features of equilibrium constants as follows:
1) Expression for equilibrium constant is applicable only when concentrations of the reactants and products have attained constant value at equilibrium state.
2) The value of equilibrium constant is independent of initial concentrations of the reactants and products.
3) Equilibrium constant is temperature dependent having one unique value for a particular reaction represented by a balanced equation at a given temperature.
4) The equilibrium constant for the reverse reaction is equal to the inverse of the equilibrium constant for the forward reaction.
5) The equilibrium constant K for a reaction is related to the equilibrium constant of the corresponding reaction, whose equation is obtained by multiplying or dividing the equation for the original reaction by a small integer.
4) What is Law of Chemical Equilibrium ?
Ans- At a given temperature, the product of Concentrations of the reaction products Raised to the respective stoichiometric Coefficient in the balanced chemical Equation divided by the product of Concentrations of the reactants raised to Their individual stoichiometric coefficients Has a constant value. This is known as The Equilibrium Law or Law of Chemical Equilibrium.
[C]Long Answers
1) Explain the equilibrium involving dissolution of gases in liquids.
Ans- When a soda water bottle is opened, some of The carbon dioxide gas dissolved in it fizzes Out rapidly. The phenomenon arises due to Difference in solubility of carbon dioxide at Different pressures. There is equilibrium Between the molecules in the gaseous state And the molecules dissolved in the liquid Under pressure i.e., CO2 (gas) CO2 (in solution) This equilibrium is governed by Henry’s Law, which states that the mass of a gas Dissolved in a given mass of a solvent at Any temperature is proportional to the Pressure of the gas above the solvent. This Amount decreases with increase of Temperature. The soda water bottle is sealed Under pressure of gas when its solubility in Water is high. As soon as the bottle is opened, Some of the dissolved carbon dioxide gas Escapes to reach a new equilibrium condition Required for the lower pressure, namely its Partial pressure in the atmosphere. This is how The soda water in bottle when left open to the Air for some time, turns ‘flat’. It can be Generalised that: For solid liquid equilibrium, there is Only one temperature (melting point) at 1 atm (1.013 bar) at which the two phases Can coexist. If there is no exchange of heat With the surroundings, the mass of the two Phases remains constant. For liquid vapour equilibrium, the Vapour pressure is constant at a given Temperature. For dissolution of solids in liquids, the Solubility is constant at a given Temperature. For dissolution of gases in liquids, the Concentration of a gas in liquid is Proportional to the pressure (concentration) of the gas over the liquid.
2) Explain the equilibrium constant in gaseous systems.
Ans- we have expressed equilibrium constant Of the reactions in terms of molar Concentration of the reactants and products, And used symbol, Kc For it. For reactions Involving gases, however, it is usually more Convenient to express the equilibrium Constant in terms of partial pressure. The ideal gas equation is written as,
pV = nRT ⇒ p = n RT
V
Here, p is the pressure in Pa, n is the number Of moles of the gas, V is the volume in m3 And T is the temperature in Kelvin Therefore, n/V is concentration expressed in mol/m3 If concentration c, is in mol/L or mol/dm3 , and p is in bar then p = cRT, We can also write p = [gas]RT. Here, R= 0.0831 bar litre/mol K At constant temperature, the pressure of the gas is proportional to its concentration i.e., p ∝ [gas]
For reaction in equilibrium H2 (g) + I2 (g) → 2HI(g) We can write either
where ∆n = (number of moles of gaseous products) – (number of moles of gaseous reactants) in the balanced chemical equation.
Case Study – 3
Predicting the Direction of the Reaction- The equilibrium constant helps in predicting the direction in which a given reaction will proceed at any stage. For this purpose, we calculate the reaction quotient Q. The reaction quotient, Q (Qc with molar concentrations and QP with partial pressures) is defined in the same way as the equilibrium constant Kc except that the concentrations in Qc are not necessarily equilibrium values. For a general reaction:
a A + b B ⇌ c C + d D
Qc = [C]c [D]d / [A]a [B]b
Then,
If Qc > Kc , the reaction will proceed in the direction of reactants (reverse reaction).
If Qc < Kc , the reaction will proceed in the direction of the products (forward reaction). If Qc = Kc , the reaction mixture is already at equilibrium. Consider the gaseous reaction of H2 with I2 ,
H2 (g) + I2 (g) ⇌ 2HI(g); Kc = 57.0 at 700 K.
Suppose we have molar concentrations [H2 ]t =0.10M, [I2 ]t = 0.20 M and [HI]t = 0.40 M. (the subscript t on the concentration symbols means that the concentrations were measured at some arbitrary time t, not necessarily at equilibrium). Thus, the reaction quotient, Qc at this stage of the reaction is given by,
Qc = [HI]t 2 / [H2 ] t [I2 ] t = (0.40)2/ (0.10)×(0.20) = 8.0
Now, in this case, Qc (8.0) does not equal Kc (57.0), so the mixture of H2 (g), I2 (g) and HI(g) is not at equilibrium; that is, more H2 (g) and I 2 (g) will react to form more HI(g) and their concentrations will decrease till Qc = Kc . The reaction quotient, Qc is useful in predicting the direction of reaction by comparing the values of Qc and Kc .Thus, we can make the following generalisations concerning the direction of the reaction
If Qc < Kc , net reaction goes from left to right
If Qc > Kc , net reaction goes from right to left.
If Qc = Kc , no net reaction occurs.
Calculating Equilibrium Concentrations In case of a problem in which we know the initial concentrations but do not know any of the equilibrium concentrations, the following three steps shall be followed:
Step 1) Write the balanced equation for the reaction.
Step 2) Under the balanced equation, make a table that lists for each substance involved in the reaction: (a) the initial concentration, (b) the change in concentration on going to equilibrium, and (c) the equilibrium concentration. In constructing the table, define x as the concentration (mol/L) of one of the substances that reacts on going to equilibrium, then use the stoichiometry of the reaction to determine the concentrations of the other substances in terms of x.
Step 3) Substitute the equilibrium concentrations into the equilibrium equation for the reaction and solve for x. If you are to solve a quadratic equation choose the mathematical solution that makes chemical sense.
Step 4) Calculate the equilibrium concentrations from the calculated value of x.
Step 5) Check your results by substituting them into the equilibrium equation.
Relationship between equilibrium constant K, reaction quotient Q and gibbs energy G The value of Kc for a reaction does not depend on the rate of the reaction. However, it is directly related to the thermodynamics of the reaction and in particular, to the change in Gibbs energy, ∆G. If,
∆G is negative, then the reaction is spontaneous and proceeds in the forward direction.
∆G is positive, then reaction is considered non-spontaneous. Instead, as reverse reaction would have a negative ∆G, the products of the forward reaction shall be converted to the reactants.
∆G is 0, reaction has achieved equilibrium; at this point, there is no longer any free energy left to drive the reaction. A mathematical expression of this thermodynamic view of equilibrium can be described by the following equation:
∆G = ∆Gø + RT lnQ
where, Gø is standard Gibbs energy. At equilibrium, when ∆G = 0 and Q = Kc , the equation becomes,
∆G = Gø + RTlnK = 0
∆Gø = – RT lnK
lnK = – ∆Gø / RT
Taking antilog of both sides, we get,
K = e–∆G0/RT
Hence, using the equation , the reaction spontaneity can be interpreted in terms of the value of ∆ Gø .
If ∆ Gø < 0, then –∆Gø /RT is positive, and >1, making K >1, which implies a spontaneous reaction or the reaction which proceeds in the forward direction to such an extent that the products are present predominantly.
If ∆Gø > 0, then –∆Gø /RT is negative, and < 1, that is , K < 1, which implies a non-spontaneous reaction or a reaction which proceeds in the forward direction to such a small degree that only a very minute quantity of product is formed.
Factors affecting equilibria One of the principal goals of chemical synthesis is to maximise the conversion of the reactants to products while minimizing the expenditure of energy. This implies maximum yield of products at mild temperature and pressure conditions. If it does not happen, then the experimental conditions need to be adjusted. For example, in the Haber process for the synthesis of ammonia from N2 and H2 , the choice of experimental conditions is of real economic importance. Annual world production of ammonia is about hundred million tones, primarily for use as fertilizers. Equilibrium constant, Kc is independent of initial concentrations. But if a system at equilibrium is subjected to a change in the concentration of one or more of the reacting substances, then the system is no longer at equilibrium; and net reaction takes place in some direction until the system returns to equilibrium once again. Similarly, a change in temperature or pressure of the system may also alter the equilibrium. In order to decide what course the reaction adopts and make a qualitative prediction about the effect of a change in conditions on equilibrium we use Le Chatelier’s principle. It states that a change in any of the factors that determine the equilibrium conditions of a system will cause the system to change in such a manner so as to reduce or to counteract the effect of the change. This is applicable to all physical and chemical equilibria.
Effect of Concentration Change In general, when equilibrium is disturbed by the addition/removal of any reactant/ products, Le Chatelier’s principle predicts that:
The concentration stress of an added reactant/product is relieved by net reaction in the direction that consumes the added substance.
The concentration stress of a removed reactant/product is relieved by net reaction in the direction that replenishes the removed substance. or in other words, “When the concentration of any of the reactants or products in a reaction at equilibrium is changed, the composition of the equilibrium mixture changes so as to minimize the effect of concentration changes”. Let us take the reaction,
H2 (g) + I2 (g) ⇌ 2HI(g)
If H2 is added to the reaction mixture at equilibrium, then the equilibrium of the reaction is disturbed. In order to restore it, the reaction proceeds in a direction wherein H2 is consumed, i.e., more of H2 and I2 react to form HI and finally the equilibrium shifts in right (forward) direction. This is in accordance with the Le Chatelier’s principle which implies that in case of addition of a reactant/product, a new equilibrium will be set up in which the concentration of the reactant/product should be less than what it was after the addition but more than what it was in the original mixture. The same point can be explained in terms of the reaction quotient, Qc ,
Qc = [HI]2 / [H2 ][I2]
Addition of hydrogen at equilibrium results in value of Qc being less than Kc . Thus, in order to attain equilibrium again reaction moves in the forward direction. Similarly, we can say that removal of a product also boosts the forward reaction and increases the concentration of the products and this has great commercial application in cases of reactions, where the product is a gas or a volatile substance. In case of manufacture of ammonia, ammonia is liquified and removed from the reaction mixture so that reaction keeps moving in forward direction. Similarly, in the large scale production of CaO (used as important building material) from CaCO3 , constant removal of CO2 from the kiln drives the reaction to completion. It should be remembered that continuous removal of a product maintains Qc at a value less than Kc and reaction continues to move in the forward direction.
[A] MCQ
1) If … the reaction will proceed in the direction of reactants (reverse reaction).
a) Qc > Kc
b) Qc < Kc
c) Qc = Kc
d) None of above
Ans- a) Qc > Kc
2) If … the reaction will proceed in the direction of the products (forward reaction).
a) Qc > Kc
b) Qc < Kc
c) Qc = Kc
d) None of above
Ans- b) Qc < Kc
3) If … the reaction mixture is already at equilibrium. Consider the gaseous reaction.
a) Qc > Kc
b) Qc < Kc
c) Qc = Kc
d) All of above
Ans- c) Qc = Kc
4) If ∆G is …. then the reaction is spontaneous and proceeds in the forward direction.
a) zero
b) positive
c) negative
d) None of above
Ans- c) negative
5) ∆G is … reaction has achieved equilibrium; at this point, there is no longer any free energy left to drive the reaction.
a) zero
b) positive
c) negative
d) None of above
Ans- a) zero
[B]Short Answers
1) How equilibrium concentrations can be calculated ?
Ans- In case of a problem in which we know the initial concentrations but do not know any of the equilibrium concentrations, the following three steps shall be followed:
Step 1) Write the balanced equation for the reaction.
Step 2) Under the balanced equation, make a table that lists for each substance involved in the reaction: (a) the initial concentration, (b) the change in concentration on going to equilibrium, and (c) the equilibrium concentration. In constructing the table, define x as the concentration (mol/L) of one of the substances that reacts on going to equilibrium, then use the stoichiometry of the reaction to determine the concentrations of the other substances in terms of x.
Step 3) Substitute the equilibrium concentrations into the equilibrium equation for the reaction and solve for x. If you are to solve a quadratic equation choose the mathematical solution that makes chemical sense.
Step 4) Calculate the equilibrium concentrations from the calculated value of x.
Step 5) Check your results by substituting them into the equilibrium equation.
2) Explain the relationship between equilibrium constant K, reaction quotient Q and gibbs energy G.
Ans- The value of Kc for a reaction does not depend on the rate of the reaction. However, it is directly related to the thermodynamics of the reaction and in particular, to the change in Gibbs energy, ∆G. If,
∆G is negative, then the reaction is spontaneous and proceeds in the forward direction.
∆G is positive, then reaction is considered non-spontaneous. Instead, as reverse reaction would have a negative ∆G, the products of the forward reaction shall be converted to the reactants.
∆G is 0, reaction has achieved equilibrium; at this point, there is no longer any free energy left to drive the reaction. A mathematical expression of this thermodynamic view of equilibrium can be described by the following equation:
∆G = ∆Gø + RT lnQ
where, Gø is standard Gibbs energy. At equilibrium, when ∆G = 0 and Q = Kc , the equation becomes,
∆G = Gø + RTlnK = 0
∆Gø = – RT lnK
lnK = – ∆Gø / RT
Taking antilog of both sides, we get,
K = e–∆G0/RT
Hence, using the equation , the reaction spontaneity can be interpreted in terms of the value of ∆ Gø .
If ∆ Gø < 0, then –∆Gø /RT is positive, and >1, making K >1, which implies a spontaneous reaction or the reaction which proceeds in the forward direction to such an extent that the products are present predominantly.
If ∆Gø > 0, then –∆Gø /RT is negative, and < 1, that is , K < 1, which implies a non-spontaneous reaction or a reaction which proceeds in the forward direction to such a small degree that only a very minute quantity of product is formed.
3)What are the Factors affecting equilibria ?
Ans- One of the principal goals of chemical synthesis is to maximise the conversion of the reactants to products while minimizing the expenditure of energy. This implies maximum yield of products at mild temperature and pressure conditions. If it does not happen, then the experimental conditions need to be adjusted. For example, in the Haber process for the synthesis of ammonia from N2 and H2 , the choice of experimental conditions is of real economic importance. Annual world production of ammonia is about hundred million tones, primarily for use as fertilizers. Equilibrium constant, Kc is independent of initial concentrations. But if a system at equilibrium is subjected to a change in the concentration of one or more of the reacting substances, then the system is no longer at equilibrium; and net reaction takes place in some direction until the system returns to equilibrium once again. Similarly, a change in temperature or pressure of the system may also alter the equilibrium. In order to decide what course the reaction adopts and make a qualitative prediction about the effect of a change in conditions on equilibrium we use Le Chatelier’s principle. It states that a change in any of the factors that determine the equilibrium conditions of a system will cause the system to change in such a manner so as to reduce or to counteract the effect of the change. This is applicable to all physical and chemical equilibria.
[C]Long Answers
1) What is effect of Concentration Change on equilibria ?
Ans- In general, when equilibrium is disturbed by the addition/removal of any reactant/ products, Le Chatelier’s principle predicts that:
The concentration stress of an added reactant/product is relieved by net reaction in the direction that consumes the added substance.
The concentration stress of a removed reactant/product is relieved by net reaction in the direction that replenishes the removed substance. or in other words, “When the concentration of any of the reactants or products in a reaction at equilibrium is changed, the composition of the equilibrium mixture changes so as to minimize the effect of concentration changes”. Let us take the reaction,
H2 (g) + I2 (g) ⇌ 2HI(g)
If H2 is added to the reaction mixture at equilibrium, then the equilibrium of the reaction is disturbed. In order to restore it, the reaction proceeds in a direction wherein H2 is consumed, i.e., more of H2 and I2 react to form HI and finally the equilibrium shifts in right (forward) direction. This is in accordance with the Le Chatelier’s principle which implies that in case of addition of a reactant/product, a new equilibrium will be set up in which the concentration of the reactant/product should be less than what it was after the addition but more than what it was in the original mixture. The same point can be explained in terms of the reaction quotient, Qc ,
Qc = [HI]2 / [H2 ][I2]
Addition of hydrogen at equilibrium results in value of Qc being less than Kc . Thus, in order to attain equilibrium again reaction moves in the forward direction. Similarly, we can say that removal of a product also boosts the forward reaction and increases the concentration of the products and this has great commercial application in cases of reactions, where the product is a gas or a volatile substance. In case of manufacture of ammonia, ammonia is liquified and removed from the reaction mixture so that reaction keeps moving in forward direction. Similarly, in the large scale production of CaO (used as important building material) from CaCO3 , constant removal of CO2 from the kiln drives the reaction to completion. It should be remembered that continuous removal of a product maintains Qc at a value less than Kc and reaction continues to move in the forward direction.
2) How the equilibrium constant helps in predicting the direction of reaction ?
Ans- The equilibrium constant helps in predicting the direction in which a given reaction will proceed at any stage. For this purpose, we calculate the reaction quotient Q. The reaction quotient, Q (Qc with molar concentrations and QP with partial pressures) is defined in the same way as the equilibrium constant Kc except that the concentrations in Qc are not necessarily equilibrium values. For a general reaction:
a A + b B ⇌ c C + d D
Qc = [C]c [D]d / [A]a [B]b
Then,
If Qc > Kc , the reaction will proceed in the direction of reactants (reverse reaction).
If Qc < Kc , the reaction will proceed in the direction of the products (forward reaction). If Qc = Kc , the reaction mixture is already at equilibrium. Consider the gaseous reaction of H2 with I2 ,
H2 (g) + I2 (g) ⇌ 2HI(g); Kc = 57.0 at 700 K.
Suppose we have molar concentrations [H2 ] t =0.10M, [I2 ] t = 0.20 M and [HI]t = 0.40 M. (the subscript t on the concentration symbols means that the concentrations were measured at some arbitrary time t, not necessarily at equilibrium). Thus, the reaction quotient, Qc at this stage of the reaction is given by,
Qc = [HI]t 2 / [H2 ] t [I2 ] t = (0.40)2/ (0.10)×(0.20) = 8.0
Now, in this case, Qc (8.0) does not equal Kc (57.0), so the mixture of H2 (g), I2 (g) and HI(g) is not at equilibrium; that is, more H2 (g) and I 2 (g) will react to form more HI(g) and their concentrations will decrease till Qc = Kc . The reaction quotient, Qc is useful in predicting the direction of reaction by comparing the values of Qc and Kc .Thus, we can make the following generalisations concerning the direction of the reaction
If Qc < Kc , net reaction goes from left to right
If Qc > Kc , net reaction goes from right to left.
If Qc = Kc , no net reaction occurs.
Case Study – 4
Arrhenius Concept of Acids and Bases According to Arrhenius theory, acids are substances that dissociates in water to give hydrogen ions H+ (aq) and bases are substances that produce hydroxyl ions OH– (aq). The ionization of an acid HX (aq) can be represented by the following equations:
HX (aq) → H+ (aq) + X– (aq)
or
HX (aq) + H2O(l) → H3O+ (aq) + X– (aq)
A bare proton, H+ is very reactive and cannot exist freely in aqueous solutions. Thus, it bonds to the oxygen atom of a solvent water molecule to give trigonal pyramidal hydronium ion, H3O+ {[H ( H2O)]+ } (see box). In this chapter we shall use H+ (aq) and H3O+ (aq) interchangeably to mean the same i.e., a hydrated proton. Similarly, a base molecule like MOH ionizes in aqueous solution according to the equation:
MOH (aq) → M+ (aq) + OH– (aq)
The hydroxyl ion also exists in the hydrated form in the aqueous solution. Arrhenius concept of acid and base, however, suffers from the limitation of being applicable only to aqueous solutions and also, does not account for the basicity of substances like, ammonia which do not possess a hydroxyl group.
The Brönsted-Lowry Acids and Bases The Danish chemist, Johannes Brönsted and the English chemist, Thomas M. Lowry gave a more general definition of acids and bases. According to Brönsted-Lowry theory, acid is a substance that is capable of donating a hydrogen ion H+ and bases are substances capable of accepting a hydrogen ion, H+ . In short, acids are proton donors and bases are proton acceptors. Consider the example of dissolution of NH3 in H2O represented by the following equation:
Hydronium and Hydroxyl Ions Hydrogen ion by itself is a bare proton with very small size (~10–15 m radius) and intense electric field, binds itself with the water molecule at one of the two available lone pairs on it giving H3O+ . This species has been detected in many compounds (e.g., H3O+ Cl – ) in the solid state. In aqueous solution the hydronium ion is further hydrated to give species like H5O2+ , H7O3 + and H9O4 + . Similarly the hydroxyl ion is hydrated to give several ionic species like , H5O3 – and H7O4 – etc. The basic solution is formed due to the presence of hydroxyl ions. In this reaction, water molecule acts as proton donor and ammonia molecule acts as proton acceptor and are thus, called Lowry-Brönsted acid and base, respectively. In the reverse reaction, H+ is transferred from NH4+ to OH – . In this case, NH4+ acts as a Bronsted acid while OH– acted as a Brönsted base. The acid-base pair that differs only by one proton is called a conjugate acid-base pair. Therefore, OH – is called the conjugate base of an acid H2O and NH4 + is called conjugate acid of the base NH3 . If Brönsted acid is a strong acid then its conjugate base is a weak base and vice- versa. It may be noted that conjugate acid has one extra proton and each conjugate base has one less proton. Consider the example of ionization of hydrochloric acid in water. HCl (aq) acts as an acid by donating a proton to H2O molecule which acts as a base.
It can be seen in the above equation, that water acts as a base because it accepts the proton. The species H3O+ is produced when water accepts a proton from HCl. Therefore, Cl – is a conjugate base of HCl and HCl is the conjugate acid of base Cl – . Similarly, H2O is a conjugate base of an acid H3O+ and H3O+ is a conjugate acid of base H2O. It is interesting to observe the dual role of water as an acid and a base. In case of reaction with HCl water acts as a base while in case of ammonia it acts as an acid by donating a proton.
Lewis Acids and Bases G.N. Lewis in 1923 defined an acid as a species which accepts electron pair and base which donates an electron pair. As far as bases are concerned, there is not much difference between Brönsted-Lowry and Lewis concepts, as the base provides a lone pair in both the cases. However, in Lewis concept many acids do not have proton. A typical example is reaction of electron deficient species BF3 with NH3 . BF3 does not have a proton but still acts as an acid and reacts with NH3 by accepting its lone pair of electrons. The reaction can be represented by,
BF3 + : NH3 → BF3 : NH3
Electron deficient species like AlCl3 , Co3+ , Mg2+, etc. can act as Lewis acids while species like H2O, NH3 , OH– etc. which can donate a pair of electrons, can act as Lewis bases.
The pH Scale Hydronium ion concentration in molarity is more conveniently expressed on a logarithmic scale known as the pH scale. The pH of a solution is defined as the negative logarithm to base 10 of the activity (aH+ ) of hydrogen ion. In dilute solutions (< 0.01 M), activity of hydrogen ion ( H+ ) is equal in magnitude to molarity represented by [ H+ ]. It should be noted that activity has no units and is defined as:
a = [H+] / mol L–1
From the definition of pH, the following can be written,
pH = – log aH+ = – log {[ H+ ] / mol L–1}
Thus, an acidic solution of HCl (10–2 M) will have a pH = 2. Similarly, a basic solution of NaOH having [OH– ] =10–4 M and [ H3O+ ] = 10–10 M will have a pH = 10. At 25 °C, pure water has a concentration of hydrogen ions, [H+] = 10–7 M. Hence, the pH of pure water is given as:
pH = –log(10–7) = 7
Acidic solutions possess a concentration of hydrogen ions, [H+ ] > 10–7 M, while basic solutions possess a concentration of hydrogen ions, [ H+ ] < 10–7 M. thus, we can summarise that
Acidic solution has pH < 7
Basic solution has pH > 7
Neutral solution has pH = 7
Now again, consider the equation at 298 K
Kw = [H3O+] [OH–] = 10–14
Taking negative logarithm on both sides of equation, we obtain
–log Kw = – log {[ H3O+ ] [OH– ]}
= – log [ H3O+ ] – log [OH– ]
= – log 10 –14
pKw = pH + pOH = 14
. Note that although Kw may change with temperature the variations in pH with temperature are so small that we often ignore it. pKw is a very important quantity for aqueous solutions and controls the relative concentrations of hydrogen and hydroxyl ions as their product is a constant. It should be noted that as the pH scale is logarithmic, a change in pH by just one unit also means change in [ H+ ] by a factor of 10. Similarly, when the hydrogen ion concentration, [ H+ ] changes by a factor of 100, the value of pH changes by 2 units. Now you can realise why the change in pH with temperature is often ignored.
Ionization Constants of Weak Acids Consider a weak acid HX that is partially ionized in the aqueous solution. The equilibrium can be expressed by:
HX (aq) + H2O(l) → H3O+(aq) + X–(aq)
Initial concentration (M)
c 0 0
Let α be the extent of ionization Change (M) -cα +cα +cα Equilibrium concentration (M) c-cα cα cα Here, c = initial concentration of the undissociated acid, HX at time, t = 0. α = extent up to which HX is ionized into ions. Using these notations, we can derive the equilibrium constant for the above discussed acid- dissociation equilibrium:
Ka = c2α2 / c(1-α) = cα2 / 1-α
Ka is called the dissociation or ionization constant of acid HX. It can be represented alternatively in terms of molar concentration as follows,
Ka = [ H+ ][X–] / [HX]
At a given temperature T, Ka is a measure of the strength of the acid HX i.e., larger the value of Ka , the stronger is the acid. Ka is a dimensionless quantity with the understanding that the standard state concentration of all species is 1M.
[A] MCQ
1) … is a substance that is capable of donating a hydrogen ion H+ .
a) Acid
b) Base
c) Neutral substances
d) Alkaline
Ans- a) Acid
2) … are proton acceptors.
a) Acids
b) Bases
c) Neutral substances
d) All the above
Ans- b) Bases
3) According to …bases are substances that produce hydroxyl ions OH–.
a) Johannes Brönsted
b) Thomas M. Lowry
c) Arrhenius
d) N. Lewis
Ans- c) Arrhenius
4) Brönsted acid is a strong acid then its conjugate base is a … base.
a) strong
b) medium
c) non
d) weak
Ans- d) weak
5) According to … an acid as a species which accepts electron pair.
a) Johannes Brönsted
b) Thomas M. Lowry
c) Arrhenius
d) N. Lewis
Ans- d) G.N. Lewis
[B]Short Answers
1) What is Arrhenius Concept of Acids and Bases ?
Ans- According to Arrhenius theory, acids are substances that dissociates in water to give hydrogen ions H+ (aq) and bases are substances that produce hydroxyl ions OH– (aq). The ionization of an acid HX (aq) can be represented by the following equations:
HX (aq) → H+ (aq) + X– (aq)
or
HX (aq) + H2O(l) → H3O+ (aq) + X– (aq)
A bare proton, H+ is very reactive and cannot exist freely in aqueous solutions. Thus, it bonds to the oxygen atom of a solvent water molecule to give trigonal pyramidal hydronium ion, H3O+ {[H ( H2O)]+ } (see box). In this chapter we shall use H+ (aq) and H3O+ (aq) interchangeably to mean the same i.e., a hydrated proton. Similarly, a base molecule like MOH ionizes in aqueous solution according to the equation:
MOH (aq) → M+ (aq) + OH– (aq)
The hydroxyl ion also exists in the hydrated form in the aqueous solution. Arrhenius concept of acid and base, however, suffers from the limitation of being applicable only to aqueous solutions and also, does not account for the basicity of substances like, ammonia which do not possess a hydroxyl group.
2) What are Lewis Acids and Bases ?
Ans- G.N. Lewis in 1923 defined an acid as a species which accepts electron pair and base which donates an electron pair. As far as bases are concerned, there is not much difference between Brönsted-Lowry and Lewis concepts, as the base provides a lone pair in both the cases. However, in Lewis concept many acids do not have proton. A typical example is reaction of electron deficient species BF3 with NH3 . BF3 does not have a proton but still acts as an acid and reacts with NH3 by accepting its lone pair of electrons. The reaction can be represented by,
BF3 + : NH3 → BF3 : NH3
Electron deficient species like AlCl3 , Co3+ , Mg2+, etc. can act as Lewis acids while species like H2O, NH3 , OH– etc. which can donate a pair of electrons, can act as Lewis bases.
3) What is Ionization Constants of Weak Acids ?
Ans- Consider a weak acid HX that is partially ionized in the aqueous solution. The equilibrium can be expressed by:
HX (aq) + H2O(l) → H3O+(aq) + X–(aq)
Initial concentration (M)
c 0 0
Let α be the extent of ionization Change (M) -cα +cα +cα Equilibrium concentration (M) c-cα cα cα Here, c = initial concentration of the undissociated acid, HX at time, t = 0. α = extent up to which HX is ionized into ions. Using these notations, we can derive the equilibrium constant for the above discussed acid- dissociation equilibrium:
Ka = c2α2 / c(1-α) = cα2 / 1-α
Ka is called the dissociation or ionization constant of acid HX. It can be represented alternatively in terms of molar concentration as follows,
Ka = [ H+ ][X–] / [HX]
At a given temperature T, Ka is a measure of the strength of the acid HX i.e., larger the value of Ka , the stronger is the acid. Ka is a dimensionless quantity with the understanding that the standard state concentration of all species is 1M.
[C]Long Answers
1) Explain the theory of Brönsted-Lowry Acids and Bases.
Ans- The Danish chemist, Johannes Brönsted and the English chemist, Thomas M. Lowry gave a more general definition of acids and bases. According to Brönsted-Lowry theory, acid is a substance that is capable of donating a hydrogen ion H+ and bases are substances capable of accepting a hydrogen ion, H+ . In short, acids are proton donors and bases are proton acceptors. Consider the example of dissolution of NH3 in H2O represented by the following equation:
Hydronium and Hydroxyl Ions Hydrogen ion by itself is a bare proton with very small size (~10–15 m radius) and intense electric field, binds itself with the water molecule at one of the two available lone pairs on it giving H3O+ . This species has been detected in many compounds (e.g., H3O+ Cl – ) in the solid state. In aqueous solution the hydronium ion is further hydrated to give species like H5O2+ , H7O3 + and H9O4 + . Similarly the hydroxyl ion is hydrated to give several ionic species like , H5O3 – and H7O4 – etc. The basic solution is formed due to the presence of hydroxyl ions. In this reaction, water molecule acts as proton donor and ammonia molecule acts as proton acceptor and are thus, called Lowry-Brönsted acid and base, respectively. In the reverse reaction, H+ is transferred from NH4+ to OH – . In this case, NH4+ acts as a Bronsted acid while OH– acted as a Brönsted base. The acid-base pair that differs only by one proton is called a conjugate acid-base pair. Therefore, OH – is called the conjugate base of an acid H2O and NH4 + is called conjugate acid of the base NH3 . If Brönsted acid is a strong acid then its conjugate base is a weak base and vice- versa. It may be noted that conjugate acid has one extra proton and each conjugate base has one less proton. Consider the example of ionization of hydrochloric acid in water. HCl (aq) acts as an acid by donating a proton to H2O molecule which acts as a base.
It can be seen in the above equation, that water acts as a base because it accepts the proton. The species H3O+ is produced when water accepts a proton from HCl. Therefore, Cl – is a conjugate base of HCl and HCl is the conjugate acid of base Cl – . Similarly, H2O is a conjugate base of an acid H3O+ and H3O+ is a conjugate acid of base H2O. It is interesting to observe the dual role of water as an acid and a base. In case of reaction with HCl water acts as a base while in case of ammonia it acts as an acid by donating a proton.
2) What is pH scale ?
Ans- Hydronium ion concentration in molarity is more conveniently expressed on a logarithmic scale known as the pH scale. The pH of a solution is defined as the negative logarithm to base 10 of the activity (aH+ ) of hydrogen ion. In dilute solutions (< 0.01 M), activity of hydrogen ion ( H+ ) is equal in magnitude to molarity represented by [ H+ ]. It should be noted that activity has no units and is defined as:
a = [H+] / mol L–1
From the definition of pH, the following can be written,
pH = – log aH+ = – log {[ H+ ] / mol L–1}
Thus, an acidic solution of HCl (10–2 M) will have a pH = 2. Similarly, a basic solution of NaOH having [OH– ] =10–4 M and [ H3O+ ] = 10–10 M will have a pH = 10. At 25 °C, pure water has a concentration of hydrogen ions, [H+] = 10–7 M. Hence, the pH of pure water is given as:
pH = –log(10–7) = 7
Acidic solutions possess a concentration of hydrogen ions, [H+ ] > 10–7 M, while basic solutions possess a concentration of hydrogen ions, [ H+ ] < 10–7 M. thus, we can summarise that
Acidic solution has pH < 7
Basic solution has pH > 7
Neutral solution has pH = 7
Now again, consider the equation at 298 K
Kw = [H3O+] [OH–] = 10–14
Taking negative logarithm on both sides of equation, we obtain
–log Kw = – log {[ H3O+ ] [OH– ]}
= – log [ H3O+ ] – log [OH– ]
= – log 10 –14
pKw = pH + pOH = 14
Note that although Kw may change with temperature the variations in pH with temperature are so small that we often ignore it. pKw is a very important quantity for aqueous solutions and controls the relative concentrations of hydrogen and hydroxyl ions as their product is a constant. It should be noted that as the pH scale is logarithmic, a change in pH by just one unit also means change in [ H+ ] by a factor of 10. Similarly, when the hydrogen ion concentration, [ H+ ] changes by a factor of 100, the value of pH changes by 2 units. Now you can realise why the change in pH with temperature is often ignored.
Case Study – 5
Relation between Ka and Kb – Ka and Kb represent the strength of an acid and a base, respectively. In case of a conjugate acid-base pair, they are related in a simple manner so that if one is known, the other can be deduced. Considering the example of NH4+ and NH3 we see,
NH4 + (aq) + H2O(l) ⇌ H3O+ (aq) + NH3 (aq)
Ka = [H3O+ ][ NH3 ] / [NH4 + ] = 5.6 × 10–10
NH3 (aq) + H2O(l) ⇌ NH4 + (aq) + OH– (aq)
Kb =[ NH4 + ][ OH–] / NH3 = 1.8 × 10–5
Net: 2 H2O(l) ⇌ H3O+ (aq) + OH– (aq)
Kw = [H3O+][OH–] = 1.0 × 10–14 M
Where, Ka represents the strength of NH4+ as an acid and Kb represents the strength of NH3 as a base. It can be seen from the net reaction that the equilibrium constant is equal to the product of equilibrium constants Ka and Kb for the reactions added. Thus,
Ka × Kb = {[H3O+][NH3] / [NH4+]} × {[NH4+] [ OH– ] / [NH3 ]}
= [H3O+ ][ OH– ] = Kw = (5.6×10–10) × (1.8 × 10–5) = 1.0 × 10–14 M
This can be extended to make a generalisation. The equilibrium constant for a net reaction obtained after adding two (or more) reactions equals the product of the equilibrium constants for individual reactions:
KNET = K1 × K2 × ……
Similarly, in case of a conjugate acid-base pair,
Ka × Kb = Kw
Knowing one, the other can be obtained. It should be noted that a strong acid will have a weak conjugate base and vice-versa. Alternatively, the above expression
Kw = Ka × Kb , can also be obtained by considering the base-dissociation equilibrium reaction:
B(aq) + H2O(l) ⇌ BH+ (aq) + OH– (aq)
Kb = [BH+ ][ OH–] / [B]
As the concentration of water remains constant it has been omitted from the denominator and incorporated within the dissociation constant. Then multiplying and dividing the above expression by [H+ ], we get:
Kb = [BH+ ][ OH– ][H+ ] / [B][H+ ]
={[OH–][H+]}{[BH+] / [B][H+ ]}
= Kw / Ka
or Ka × Kb = Kw
It may be noted that if we take negative logarithm of both sides of the equation, then pK values of the conjugate acid and base are related to each other by the equation:
pKa + pKb = pKw = 14 (at 298K)
Factors Affecting Acid Strength Having discussion on quantitatively the strengths of acids and bases, we come to a stage where we can calculate the pH of a given acid solution. But, the curiosity rises about why should some acids be stronger than others? What factors are responsible for making them stronger? The answer lies in its being a complex phenomenon. But, broadly speaking we can say that the extent of dissociation of an acid depends on the strength and polarity of the H-A bond. In general, when strength of H-A bond decreases, that is, the energy required to break the bond decreases, HA becomes a stronger acid. Also, when the H-A bond becomes more polar i.e., the electronegativity difference between the atoms H and A increases and there is marked charge separation, cleavage of the bond becomes easier thereby increasing the acidity. But it should be noted that while comparing elements in the same group of the periodic table, H-A bond strength is a more important factor in determining acidity than its polar nature. As the size of A increases down the group, H-A bond strength decreases and so the acid strength increases. For example,
Size increases
HF << HCl << HBr << HI
Acid strength increases
Similarly, H2S is stronger acid than H2O. But, when we discuss elements in the same row of the periodic table, H-A bond polarity becomes the deciding factor for determining the acid strength. As the electronegativity of A increases, the strength of the acid also increases. For example,
Electronegativity of A increases
CH4 < NH3 < H2O < HF
Acid strength increases
Common Ion Effect in the Ionization of Acids and Bases Consider an example of acetic acid dissociation equilibrium represented as:
CH3COOH(aq) H+ (aq) + CH3COO– (aq)
or HAc(aq) H+ (aq) + Ac– (aq)
Ka = [H+][Ac–] / [HAc]
Addition of acetate ions to an acetic acid solution results in decreasing the concentration of hydrogen ions, [H+ ]. Also, if H+ ions are added from an external source then the equilibrium moves in the direction of undissociated acetic acid i.e., in a direction of reducing the concentration of hydrogen ions, [H+]. This phenomenon is an example of common ion effect. It can be defined as a shift in equilibrium on adding a substance that provides more of an ionic species already present in the dissociation equilibrium. Thus, we can say that common ion effect is a phenomenon based on the Le Chatelier’s principle discussed earlier. In order to evaluate the pH of the solution resulting on addition of 0.05M acetate ion to 0.05M acetic acid solution, we shall consider the acetic acid dissociation equilibrium once again,
HAc(aq) ⇌ H+(aq) + Ac–(aq)
Initial concentration (M)
0.05 0 0.05
Let x be the extent of ionization of acetic acid.
Change in concentration (M)
–x +x +x
Equilibrium concentration (M)
0.05-x. x 0.05+x
Therefore, Ka = [H+ ][Ac– ]/[H Ac] = {(0.05+x)(x)}/(0.05-x)
As Ka is small for a very weak acid, x<<0.05.
Hence, (0.05 + x) ≈ (0.05 – x) ≈ 0.05
Thus, 1.8 × 10–5 = (x) (0.05 + x) / (0.05 – x)
= x(0.05) / (0.05)= x = [H+] = 1.8 × 10–5M
pH = – log(1.8 × 10–5) = 4.74
Buffer Solutions Many body fluids e.g., blood or urine have definite pH and any deviation in their pH indicates malfunctioning of the body. The control of pH is also very important in many chemical and biochemical processes. Many medical and cosmetic formulations require that these be kept and administered at a particular pH. The solutions which resist change in pH on dilution or with the addition of small amounts of acid or alkali are called Buffer Solutions. Buffer solutions.
Common Ion Effect on Solubility of Ionic Salts– It is expected from Le Chatelier’s principle that if we increase the concentration of any one of the ions, it should combine with the ion of its opposite charge and some of the salt will be precipitated till once again Ksp = Qsp . Similarly, if the concentration of one of the ions is decreased, more salt will dissolve to increase the concentration of both the ions till once again Ksp = Qsp . This is applicable even to soluble salts like sodium chloride except that due to higher concentrations of the ions, we use their activities instead of their molarities in the expression for Qsp . Thus if we take a saturated solution of sodium chloride and pass HCl gas through it, then sodium chloride is precipitated due to increased concentration (activity) of chloride ion available from the dissociation of HCl. Sodium chloride thus obtained is of very high purity and we can get rid of impurities like sodium and magnesium sulphates. The common ion effect is also used for almost complete precipitation of a particular ion as its sparingly soluble salt, with very low value of solubility product for gravimetric estimation. Thus we can precipitate silver ion as silver chloride, ferric ion as its hydroxide (or hydrated ferric oxide) and barium ion as its sulphate for quantitative estimations.
[A] MCQ
1) H-A bond strength … and so the acid strength …
a) decreases , increases
b) increases , increases
c) increases , decreases
d) decreases , decreases
Ans- a) decreases , increases
2) As the electronegativity of A … the strength of the acid also …
a) decreases , increases
b) increases , increases
c) increases , decreases
d) decreases , decreases
Ans- b) increases , increases
3) If the concentration of one of the ions is … more salt will dissolve to … the concentration of both the ions till once again Ksp = Qsp .
a) increases , increases
b) increases , decreases
c) decreases , increases
d) decreases , decreases
Ans- c) decreases , increases
4) The solutions which resist change in pH on dilution or with the addition of small amounts of acid or alkali are called …
a) Neutral solution
b) Basic solution
c) Acidic solution
d) Buffer solution
Ans- d) Buffer solution
5)when the H-A bond becomes more polar then the cleavage of the bond becomes easier thereby increasing the …
a) Acidity
b) Basicity
c) Aromaticity
d) Alkalinity
Ans- a) acidity
[B]Short Answers
1) What are the factors affecting Acid Strength?
Ans- Having discussion on quantitatively the strengths of acids and bases, we come to a stage where we can calculate the pH of a given acid solution. But, the curiosity rises about why should some acids be stronger than others? What factors are responsible for making them stronger? The answer lies in its being a complex phenomenon. But, broadly speaking we can say that the extent of dissociation of an acid depends on the strength and polarity of the H-A bond. In general, when strength of H-A bond decreases, that is, the energy required to break the bond decreases, HA becomes a stronger acid. Also, when the H-A bond becomes more polar i.e., the electronegativity difference between the atoms H and A increases and there is marked charge separation, cleavage of the bond becomes easier thereby increasing the acidity. But it should be noted that while comparing elements in the same group of the periodic table, H-A bond strength is a more important factor in determining acidity than its polar nature. As the size of A increases down the group, H-A bond strength decreases and so the acid strength increases. For example,
Size increases
HF << HCl << HBr << HI
Acid strength increases
Similarly, H2S is stronger acid than H2O. But, when we discuss elements in the same row of the periodic table, H-A bond polarity becomes the deciding factor for determining the acid strength. As the electronegativity of A increases, the strength of the acid also increases. For example,
Electronegativity of A increases
CH4 < NH3 < H2O < HF
Acid strength increases
2) What are buffer solution ?
Ans- Many body fluids e.g., blood or urine have definite pH and any deviation in their pH indicates malfunctioning of the body. The control of pH is also very important in many chemical and biochemical processes. Many medical and cosmetic formulations require that these be kept and administered at a particular pH. The solutions which resist change in pH on dilution or with the addition of small amounts of acid or alkali are called Buffer Solutions. Buffer solutions.
3) Explain the common Ion Effect on Solubility of Ionic Salts .
Ans- It is expected from Le Chatelier’s principle that if we increase the concentration of any one of the ions, it should combine with the ion of its opposite charge and some of the salt will be precipitated till once again Ksp = Qsp . Similarly, if the concentration of one of the ions is decreased, more salt will dissolve to increase the concentration of both the ions till once again Ksp = Qsp . This is applicable even to soluble salts like sodium chloride except that due to higher concentrations of the ions, we use their activities instead of their molarities in the expression for Qsp . Thus if we take a saturated solution of sodium chloride and pass HCl gas through it, then sodium chloride is precipitated due to increased concentration (activity) of chloride ion available from the dissociation of HCl. Sodium chloride thus obtained is of very high purity and we can get rid of impurities like sodium and magnesium sulphates. The common ion effect is also used for almost complete precipitation of a particular ion as its sparingly soluble salt, with very low value of solubility product for gravimetric estimation. Thus we can precipitate silver ion as silver chloride, ferric ion as its hydroxide (or hydrated ferric oxide) and barium ion as its sulphate for quantitative estimations.
[C]Long Answers
1) Explain the Common Ion Effect in the Ionization of Acids and Bases.
Ans- Consider an example of acetic acid dissociation equilibrium represented as:
CH3COOH(aq) H+ (aq) + CH3COO– (aq)
or HAc(aq) H+ (aq) + Ac– (aq)
Ka = [H+][Ac–] / [HAc]
Addition of acetate ions to an acetic acid solution results in decreasing the concentration of hydrogen ions, [H+ ]. Also, if H+ ions are added from an external source then the equilibrium moves in the direction of undissociated acetic acid i.e., in a direction of reducing the concentration of hydrogen ions, [H+]. This phenomenon is an example of common ion effect. It can be defined as a shift in equilibrium on adding a substance that provides more of an ionic species already present in the dissociation equilibrium. Thus, we can say that common ion effect is a phenomenon based on the Le Chatelier’s principle discussed earlier. In order to evaluate the pH of the solution resulting on addition of 0.05M acetate ion to 0.05M acetic acid solution, we shall consider the acetic acid dissociation equilibrium once again,
HAc(aq) ⇌ H+(aq) + Ac–(aq)
Initial concentration (M)
0.05 0 0.05
Let x be the extent of ionization of acetic acid.
Change in concentration (M)
–x +x +x
Equilibrium concentration (M)
0.05-x. x 0.05+x
Therefore, Ka = [H+ ][Ac– ]/[H Ac] = {(0.05+x)(x)}/(0.05-x)
As Ka is small for a very weak acid, x<<0.05.
Hence, (0.05 + x) ≈ (0.05 – x) ≈ 0.05
Thus, 1.8 × 10–5 = (x) (0.05 + x) / (0.05 – x)
= x(0.05) / (0.05)= x = [H+] = 1.8 × 10–5M
pH = – log(1.8 × 10–5) = 4.74
2) Explain the relation between Ka and Kb.
Ans- Ka and Kb represent the strength of an acid and a base, respectively. In case of a conjugate acid-base pair, they are related in a simple manner so that if one is known, the other can be deduced. Considering the example of NH4+ and NH3 we see,
NH4 + (aq) + H2O(l) ⇌ H3O+ (aq) + NH3 (aq)
Ka = [H3O+ ][ NH3 ] / [NH4 + ] = 5.6 × 10–10
NH3 (aq) + H2O(l) ⇌ NH4 + (aq) + OH– (aq)
Kb =[ NH4 + ][ OH–] / NH3 = 1.8 × 10–5
Net: 2 H2O(l) ⇌ H3O+ (aq) + OH– (aq)
Kw = [H3O+][OH–] = 1.0 × 10–14 M
Where, Ka represents the strength of NH4+ as an acid and Kb represents the strength of NH3 as a base. It can be seen from the net reaction that the equilibrium constant is equal to the product of equilibrium constants Ka and Kb for the reactions added. Thus,
Ka × Kb = {[H3O+][NH3] / [NH4+]} × {[NH4+] [ OH– ] / [NH3 ]}
= [H3O+ ][ OH– ] = Kw = (5.6×10–10) × (1.8 × 10–5) = 1.0 × 10–14 M
This can be extended to make a generalisation. The equilibrium constant for a net reaction obtained after adding two (or more) reactions equals the product of the equilibrium constants for individual reactions:
KNET = K1 × K2 × ……
Similarly, in case of a conjugate acid-base pair,
Ka × Kb = Kw
Knowing one, the other can be obtained. It should be noted that a strong acid will have a weak conjugate base and vice-versa. Alternatively, the above expression
Kw = Ka × Kb , can also be obtained by considering the base-dissociation equilibrium reaction:
B(aq) + H2O(l) ⇌ BH+ (aq) + OH– (aq)
Kb = [BH+ ][ OH–] / [B]
As the concentration of water remains constant it has been omitted from the denominator and incorporated within the dissociation constant. Then multiplying and dividing the above expression by [H+ ], we get:
Kb = [BH+ ][ OH– ][H+ ] / [B][H+ ]
={[OH–][H+]}{[BH+] / [B][H+ ]}
= Kw / Ka
or Ka × Kb = Kw
It may be noted that if we take negative logarithm of both sides of the equation, then pK values of the conjugate acid and base are related to each other by the equation:
pKa + pKb = pKw = 14 (at 298K)