Equilibrium PDF

Summary

This document covers the topic of equilibrium in chemistry, including the dynamic nature of equilibrium, equilibrium constants, and various factors affecting equilibrium. It also explains diverse aspects of the concept of equilibrium including classification of acids and bases using Arrhenius, Brønsted-Lowry and Lewis theories and their different concepts. It also discusses important concepts like ionic product, and buffer solutions.

Full Transcript

Unit 6

Equilibrium

Chemical equilibria are important in numerous biological
and environmental processes. For example, equilibria
involving O2 molecules and the protein hemoglobin play
After studying this unit you will be
a crucial role in the transport and delivery of O2 from
able to
our lungs to our muscles. Similar equilibria involving CO
identify dynamic nature of molecules and hemoglobin account for the toxicity of CO.
equilibrium involved in physical
and chemical processes; When a liquid evaporates in a closed container,
state the law of equilibrium; molecules with relatively higher kinetic energy escape
explain characteristics of the liquid surface into the vapour phase and number of
equilibria involved in physical liquid molecules from the vapour phase strike the liquid
and chemical processes; surface and are retained in the liquid phase. It gives rise
write expressions for equilibrium to a constant vapour pressure because of an equilibrium in
constants;
which the number of molecules leaving the liquid equals the
establish a relationship between
Kp and Kc; number returning to liquid from the vapour. We say that
explain various factors that the system has reached equilibrium state at this stage.
affect the equilibrium state of a However, this is not static equilibrium and there is a lot of
reaction; activity at the boundary between the liquid and the vapour.
classify substances as acids or Thus, at equilibrium, the rate of evaporation is equal to the
bases according to Arrhenius, rate of condensation. It may be represented by
Bronsted-Lowry and Lewis
concepts; H2O (l) H2O (vap)
classify acids and bases as
The double half arrows indicate that the processes
weak or strong in terms of their
ionization constants; in both the directions are going on simultaneously. The
explain the dependence of degree mixture of reactants and products in the equilibrium state
of ionization on concentration is called an equilibrium mixture.
of the electrolyte and that of the
common ion; Equilibrium can be established for both physical
describe pH scale for representing processes and chemical reactions. The reaction may be
hydrogen ion concentration; fast or slow depending on the experimental conditions and
explain ionisation of water and the nature of the reactants. When the reactants in a closed
its duel role as acid and base; vessel at a particular temperature react to give products,
describe ionic product (Kw ) and the concentrations of the reactants keep on decreasing,
pKw for water;
while those of products keep on increasing for some time
appreciate use of buffer
after which there is no change in the concentrations
solutions;
calculate solubility product
of either of the reactants or products. This stage of the
constant. system is the dynamic equilibrium and the rates of the
forward and reverse reactions become equal. It is due to

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 EQUILIBRIUM 169

this dynamic equilibrium stage that there is characteristic features. We observe that the
no change in the concentrations of various mass of ice and water do not change with
species in the reaction mixture. Based on the time and the temperature remains constant.
extent to which the reactions proceed to reach However, the equilibrium is not static.
the state of chemical equilibrium, these may The intense activity can be noticed at the
be classified in three groups. boundary between ice and water. Molecules
(i) The reactions that proceed nearly from the liquid water collide against ice and
to completion and only negligible adhere to it and some molecules of ice escape
concentrations of the reactants are into liquid phase. There is no change of mass
left. In some cases, it may not be even of ice and water, as the rates of transfer of
possible to detect these experimentally. molecules from ice into water and of reverse
transfer from water into ice are equal at
(ii) The reactions in which only small
atmospheric pressure and 273 K.
amounts of products are formed and
most of the reactants remain unchanged It is obvious that ice and water are in
at equilibrium stage. equilibrium only at particular temperature
and pressure. For any pure substance at
(iii) The reactions in which the concentrations
atmospheric pressure, the temperature at
of the reactants and products are
which the solid and liquid phases are at
comparable, when the system is in
equilibrium is called the normal melting point
equilibrium.
or normal freezing point of the substance. The
The extent of a reaction in equilibrium system here is in dynamic equilibrium and we
varies with the experimental conditions such can infer the following:
as concentrations of reactants, temperature, (i) Both the opposing processes occur
etc. Optimisation of the operational conditions simultaneously.
is very important in industry and laboratory (ii) Both the processes occur at the same
so that equilibrium is favorable in the rate so that the amount of ice and water
direction of the desired product. Some remains constant.
important aspects of equilibrium involving
physical and chemical processes are dealt in 6.1.2 Liquid-Vapour Equilibrium
this unit along with the equilibrium involving This equilibrium can be better understood if
ions in aqueous solutions which is called as we consider the example of a transparent box
ionic equilibrium. carrying a U-tube with mercury (manometer).
Drying agent like anhydrous calcium chloride
6.1 E Q U IL IBRI U M IN P H Y S I C A L
(or phosphorus penta-oxide) is placed for
PROCESSES
a few hours in the box. After removing the
The characteristics of system at equilibrium drying agent by tilting the box on one side, a
are better understood if we examine some watch glass (or petri dish) containing water
physical processes. The most familiar examples is quickly placed inside the box. It will be
are phase transformation processes, e.g., observed that the mercury level in the right
solid liquid limb of the manometer slowly increases and
liquid gas finally attains a constant value, that is, the
solid gas pressure inside the box increases and reaches
a constant value. Also the volume of water in
6.1.1 Solid-Liquid Equilibrium
the watch glass decreases (Fig. 6.1). Initially
Ice and water kept in a perfectly insulated there was no water vapour (or very less) inside
thermos flask (no exchange of heat between its the box. As water evaporated the pressure in
contents and the surroundings) at 273K and the box increased due to addition of water
the atmospheric pressure are in equilibrium molecules into the gaseous phase inside
state and the system shows interesting the box. The rate of evaporation is constant.

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Fig. 6.1 Measuring equilibrium vapour pressure of water at a constant temperature

However, the rate of increase in pressure vapour to liquid state is much less than the
decreases with time due to condensation rate of evaporation. These are open systems
of vapour into water. Finally it leads to an and it is not possible to reach equilibrium in
equilibrium condition when there is no net an open system.
evaporation. This implies that the number
Water and water vapour are in equilibrium
of water molecules from the gaseous state
into the liquid state also increases till the position at atmospheric pressure (1.013 bar)
equilibrium is attained i.e., and at 100°C in a closed vessel. The boiling
point of water is 100°C at 1.013 bar pressure.
rate of evaporation= rate of condensation
For any pure liquid at one atmospheric
H2O(l) H2O (vap)
pressure (1.013 bar), the temperature
At equilibrium the pressure exerted by at which the liquid and vapours are at
the water molecules at a given temperature equilibrium is called normal boiling point of
remains constant and is called the equilibrium the liquid. Boiling point of the liquid depends
vapour pressure of water (or just vapour on the atmospheric pressure. It depends on
pressure of water); vapour pressure of water the altitude of the place; at high altitude the
increases with temperature. If the above boiling point decreases.
experiment is repeated with methyl alcohol,
acetone and ether, it is observed that different 6.1.3 Solid – Vapour Equilibrium
liquids have different equilibrium vapour
Let us now consider the systems where solids
pressures at the same temperature, and the
sublime to vapour phase. If we place solid
liquid which has a higher vapour pressure is
iodine in a closed vessel, after sometime
more volatile and has a lower boiling point.
the vessel gets filled up with violet vapour
If we expose three watch glasses containing and the intensity of colour increases with
separately 1mL each of acetone, ethyl alcohol, time. After certain time the intensity of
and water to atmosphere and repeat the colour becomes constant and at this stage
experiment with different volumes of the
equilibrium is attained. Hence solid iodine
liquids in a warmer room, it is observed
sublimes to give iodine vapour and the iodine
that in all such cases the liquid eventually
vapour condenses to give solid iodine. The
disappears and the time taken for complete
equilibrium can be represented as,
evaporation depends on (i) the nature of the
liquid, (ii) the amount of the liquid and (iii) the I2(solid) I2 (vapour)
temperature. When the watch glass is open Other examples showing this kind of
to the atmosphere, the rate of evaporation equilibrium are,
remains constant but the molecules are
dispersed into large volume of the room. As Camphor (solid) Camphor (vapour)
a consequence the rate of condensation from NH4Cl (solid) NH4Cl (vapour)

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6.1.4 Equilibrium Involving Dissolution pressure of the gas above the solvent.
of Solid or Gases in Liquids This amount decreases with increase of
Solids in liquids temperature. The soda water bottle is sealed
under pressure of gas when its solubility in
We know from our experience that we can
water is high. As soon as the bottle is opened,
dissolve only a limited amount of salt or
some of the dissolved carbon dioxide gas
sugar in a given amount of water at room
escapes to reach a new equilibrium condition
temperature. If we make a thick sugar syrup
required for the lower pressure, namely its
solution by dissolving sugar at a higher
partial pressure in the atmosphere. This is
temperature, sugar crystals separate out if we
how the soda water in bottle when left open
cool the syrup to the room temperature. We call
to the air for some time, turns ‘flat’. It can be
it a saturated solution when no more of solute
generalised that:
can be dissolved in it at a given temperature.
The concentration of the solute in a saturated (i) For solid liquid equilibrium, there is
solution depends upon the temperature. In only one temperature (melting point) at
a saturated solution, a dynamic equilibrium 1 atm (1.013 bar) at which the two
exits between the solute molecules in the solid phases can coexist. If there is no
state and in the solution: exchange of heat with the surroundings,
the mass of the two phases remains
Sugar (solution) Sugar (solid), and
constant.
the rate of dissolution of sugar = rate of
crystallisation of sugar. (ii) For liquid vapour equilibrium, the
vapour pressure is constant at a given
Equality of the two rates and dynamic
temperature.
nature of equilibrium has been confirmed with
the help of radioactive sugar. If we drop some (iii) For dissolution of solids in liquids,
radioactive sugar into saturated solution of the solubility is constant at a given
non-radioactive sugar, then after some time temperature.
radioactivity is observed both in the solution (iv) For dissolution of gases in liquids,
and in the solid sugar. Initially there were no the concentration of a gas in liquid
radioactive sugar molecules in the solution is proportional to the pressure
but due to dynamic nature of equilibrium, (concentration) of the gas over the liquid.
there is exchange between the radioactive These observations are summarised in
and non-radioactive sugar molecules between Table 6.1
the two phases. The ratio of the radioactive Table 6.1 Some Features of Physical Equilibria
to non-radioactive molecules in the solution
increases till it attains a constant value. Process Conclusion
Liquid Vapour p H 2O constant at given
Gases in liquids temperature
H2O (l) H2O (g)
When a soda water bottle is opened, some of
Solid Liquid Melting point is fixed at
the carbon dioxide gas dissolved in it fizzes constant pressure
out rapidly. The phenomenon arises due H2O (s) H2O (l)
to difference in solubility of carbon dioxide Solute(s) Solute Concentration of solute
at different pressures. There is equilibrium (solution) in solution is constant
between the molecules in the gaseous state Sugar(s) Sugar at a given temperature
and the molecules dissolved in the liquid (solution)
under pressure i.e.,
Gas(g) Gas (aq) [gas(aq)]/[gas(g)] is
CO2 (gas) CO2 (in solution) constant at a given
This equilibrium is governed by Henry’s temperature
CO2(g) CO2(aq)
law, which states that the mass of a gas [CO2(aq)]/[CO2(g)] is
dissolved in a given mass of a solvent at constant at a given
any temperature is proportional to the temperature

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6.1.5 General Characteristics of
Equilibria Involving Physical
Processes
For the physical processes discussed above,
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 Fig. 6.2 Attainment of chemical equilibrium.
constant value of one of its parameters
at a given temperature. Table 6.1 lists Eventually, the two reactions occur at the
such quantities. same rate and the system reaches a state of
(v) The magnitude of such quantities at any equilibrium.
stage indicates the extent to which the Similarly, the reaction can reach the state
physical process has proceeded before of equilibrium even if we start with only C and
reaching equilibrium. D; that is, no A and B being present initially,
as the equilibrium can be reached from either
6.2 EQUILIBRIUM IN CHEMICAL direction.
PROCESSES – DYNAMIC
EQUILIBRIUM The dynamic nature of chemical
equilibrium can be demonstrated in the
Analogous to the physical systems chemical synthesis of ammonia by Haber’s process.
reactions also attain a state of equilibrium. In a series of experiments, Haber started
These reactions can occur both in forward with known amounts of dinitrogen and
and backward directions. When the rates of dihydrogen maintained at high temperature
the forward and reverse reactions become and pressure and at regular intervals
equal, the concentrations of the reactants determined the amount of ammonia present.
and the products remain constant. This He was successful in determining also the
is the stage of chemical equilibrium. This concentration of unreacted dihydrogen and
equilibrium is dynamic in nature as it consists dinitrogen. Fig. 6.4 (page 174) shows that after
of a forward reaction in which the reactants a certain time the composition of the mixture
give product(s) and reverse reaction in which remains the same even though some of the
product(s) gives the original reactants. reactants are still present. This constancy in
For a better comprehension, let us consider composition indicates that the reaction has
a general case of a reversible reaction, reached equilibrium. In order to understand
A+B C+D the dynamic nature of the reaction, synthesis
of ammonia is carried out with exactly the
With passage of time, there is same starting conditions (of partial pressure
accumulation of the products C and D and and temperature) but using D2 (deuterium)
depletion of the reactants A and B (Fig. 6.2). in place of H2. The reaction mixtures starting
This leads to a decrease in the rate of either with H2 or D2 reach equilibrium with
forward reaction and an increase in the rate the same composition, except that D2 and
of the reverse reaction, ND3 are present instead of H2 and NH3. After

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 EQUILIBRIUM 173

Dynamic Equilibrium – A Student’s Activity
Equilibrium whether in a physical or in a chemical system, is always of dynamic nature. This can
be demonstrated by the use of radioactive isotopes. This is not feasible in a school laboratory.
However this concept can be easily comprehended by performing the following activity. The activity
can be performed in a group of 5 or 6 students.
Take two 100mL measuring cylinders (marked as 1 and 2) and two glass tubes each of
30 cm length. Diameter of the tubes may be same or different in the range of 3-5mm. Fill
nearly half of the measuring cylinder-1 with coloured water (for this purpose add a crystal
of potassium permanganate to water) and keep second cylinder (number 2) empty.
Put one tube in cylinder 1 and second in cylinder 2. Immerse one tube in cylinder 1,
close its upper tip with a finger and transfer the coloured water contained in its lower portion to
cylinder 2. Using second tube, kept in 2nd cylinder, transfer the coloured water in a similar manner
from cylinder 2 to cylinder 1. In this way keep on transferring coloured water using the two glass
tubes from cylinder 1 to 2 and from 2 to 1 till you notice that the level of coloured water in both
the cylinders becomes constant.
If you continue intertransferring coloured solution between the cylinders, there will not be
any further change in the levels of coloured water in two cylinders. If we take analogy of ‘level’ of
coloured water with ‘concentration’ of reactants and products in the two cylinders, we can say
the process of transfer, which continues even after the constancy of level, is indicative of dynamic
nature of the process. If we repeat the experiment taking two tubes of different diameters we find
that at equilibrium the level of coloured water in two cylinders is different. How far diameters are
responsible for change in levels in two cylinders? Empty cylinder (2) is an indicator of no product
in it at the beginning.

1 2 1 2

(a) (b)
Fig.6.3 Demonstrating dynamic nature of equilibrium. (a) initial stage (b) final stage after the
equilibrium is attained.

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2NH3(g) N2(g) + 3H2(g)
Similarly let us consider the reaction,
H 2 (g) + I 2 (g) 2HI(g). If we start with
equal initial concentration of H2 and I2, the
reaction proceeds in the forward direction
and the concentration of H2 and I2 decreases
while that of HI increases, until all of these
become constant at equilibrium (Fig. 6.5). We
can also start with HI alone and make the
reaction to proceed in the reverse direction;
the concentration of HI will decrease and
concentration of H2 and I2 will increase until
they all become constant when equilibrium is
reached (Fig. 6.5). If total number of H and I
atoms are same in a given volume, the same
equilibrium mixture is obtained whether we
Fig. 6.4 Depiction of equilibrium for the reaction
start it from pure reactants or pure product.
N 2  g   3H 2  g  2NH3  g 

equilibrium is attained, these two mixtures
(H 2, N 2, NH 3 and D 2, N 2, ND 3) are mixed
together and left for a while. Later, when
this mixture is analysed, it is found that the
concentration of ammonia is just the same
as before. However, when this mixture is
analysed by a mass spectrometer, it is found
that ammonia and all deuterium containing
forms of ammonia (NH3, NH2D, NHD2 and
ND3) and dihydrogen and its deutrated forms
(H2, HD and D2) are present. Thus one can
conclude that scrambling of H and D atoms in
the molecules must result from a continuation
of the forward and reverse reactions in the
mixture. If the reaction had simply stopped
Fig. 6.5 Chemical equilibrium in the reaction H2(g)
when they reached equilibrium, then there
+ I2(g) 2HI(g) can be attained from
would have been no mixing of isotopes in either direction
this way.
6.3 LAW OF CHEMICAL EQUILIBRIUM
Use of isotope (deuterium) in the formation AND EQUILIBRIUM CONSTANT
of ammonia clearly indicates that chemical
A mixture of reactants and products in the
reactions reach a state of dynamic
equilibrium state is called an equilibrium
equilibrium in which the rates of forward
mixture. In this section we shall address a
and reverse reactions are equal and there
number of important questions about the
is no net change in composition.
composition of equilibrium mixtures: What is
Equilibrium can be attained from both the relationship between the concentrations
sides, whether we start reaction by taking, of reactants and products in an equilibrium
H2(g) and N2(g) and get NH3(g) or by taking mixture? How can we determine equilibrium
NH3(g) and decomposing it into N2(g) and H2(g). concentrations from initial concentrations?
N2(g) + 3H2(g) 2NH3(g) What factors can be exploited to alter the

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 EQUILIBRIUM 175

composition of an equilibrium mixture? The Six sets of experiments with varying initial
last question in particular is important when conditions were performed, starting with only
choosing conditions for synthesis of industrial gaseous H2 and I2 in a sealed reaction vessel
chemicals such as H2, NH3, CaO etc. in first four experiments (1, 2, 3 and 4) and
To answer these questions, let us consider only HI in other two experiments (5 and 6).
a general reversible reaction: Experiment 1, 2, 3 and 4 were performed
A+B C+D taking different concentrations of H2 and / or
where A and B are the reactants, C and D I2, and with time it was observed that intensity
are the products in the balanced chemical of the purple colour remained constant and
equation. On the basis of experimental studies equilibrium was attained. Similarly, for
of many reversible reactions, the Norwegian experiments 5 and 6, the equilibrium was
chemists Cato Maximillian Guldberg and attained from the opposite direction.
Peter Waage proposed in 1864 that the Data obtained from all six sets of
concentrations in an equilibrium mixture experiments are given in Table 6.2.
are related by the following equilibrium
equation, It is evident from the experiments 1, 2,
3 and 4 that number of moles of dihydrogen
Kc 
CD         (6.1) reacted = number of moles of iodine reacted
 A  B  = ½ (number of moles of HI formed). Also,
(6.1) where Kc is the equilibrium constant and experiments 5 and 6 indicate that,
the expression on the right side is called the [H2(g)]eq = [I2(g)]eq
equilibrium constant expression.
The equilibrium equation is also known as Knowing the above facts, in order
the law of mass action because in the early to establish a relationship between
days of chemistry, concentration was called concentrations of the reactants and products,
“active mass”. In order to appreciate their several combinations can be tried. Let us
work better, let us consider reaction between consider the simple expression,
gaseous H2 and I2 carried out in a sealed vessel [HI(g)]eq / [H2(g)]eq [I2(g)]eq
at 731K.
H2(g) + I2(g)   2HI(g) It can be seen from Table 6.3 that if we
1 mol 1 mol 2 mol put the equilibrium concentrations of the
reactants and products, the above expression

Table 6.2 Initial and Equilibrium Concentrations of H2, I2 and HI

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Table 6.3 Expression Involving the The equilibrium constant for a general
Equilibrium Concentration of reaction,
Reactants
aA + bB cC + dD
H2(g) + I2(g) 2HI(g)
is expressed as,
Kc = [C]c[D]d / [A]a[B]b (6.4)

where [A], [B], [C] and [D] are the equilibrium
concentrations of the reactants and products.
Equilibrium constant for the reaction,
4NH3(g) + 5O2(g) 4NO(g) + 6H2O(g) is written
as
Kc = [NO]4[H2O]6 / [NH3]4 [O2]5
Molar concentration of different species is
is far from constant. However, if we consider indicated by enclosing these in square bracket
the expression, and, as mentioned above, it is implied that
[HI(g)]2eq / [H2(g)]eq [I2(g)]eq these are equilibrium concentrations. While
writing expression for equilibrium constant,
we find that this expression gives constant
symbol for phases (s, l, g) are generally ignored.
value (as shown in Table 6.3) in all the six
cases. It can be seen that in this expression Let us write equilibrium constant for the
the power of the concentration for reactants reaction, H2(g) + I2(g) 2HI(g) (6.5)
and products are actually the stoichiometric
as, Kc = [HI]2 / [H2] [I2] = x (6.6)
coefficients in the equation for the chemical
reaction. Thus, for the reaction H2(g) + I2(g) The equilibrium constant for the reverse
2HI(g), following equation 6.1, the equilibrium reaction, 2HI(g) H2(g) + I2(g), at the same
constant Kc is written as, temperature is,
Kc = [HI(g)]eq2 / [H2(g)]eq [I2(g)]eq (6.2) K′c = [H2] [I2] / [HI]2 = 1/ x = 1 / Kc (6.7)
Generally the subscript ‘eq’ (used for Thus, K′c = 1 / Kc (6.8)
equilibrium) is omitted from the concentration Equilibrium constant for the reverse
terms. It is taken for granted that the reaction is the inverse of the equilibrium
concentrations in the expression for Kc are constant for the reaction in the forward
equilibrium values. We, therefore, write, direction.
Kc = [HI(g)]2 / [H2(g)] [I2(g)] (6.3) If we change the stoichiometric coefficients
in a chemical equation by multiplying
The subscript ‘c’ indicates that K c is
throughout by a factor then we must make
expressed in concentrations of mol L–1.
sure that the expression for equilibrium
At a given temperature, the product of constant also reflects that change. For
concentrations of the reaction products example, if the reaction (6.5) is written as,
raised to the respective stoichiometric
coefficient in the balanced chemical ½ H2(g) + ½ I2(g) HI(g) (6.9)
equation divided by the product of the equilibrium constant for the above
concentrations of the reactants raised to reaction is given by
their individual stoichiometric coefficients K″c = [HI] / [H2]1/2[I2]1/2 = {[HI]2 / [H2][I2]}1/2
has a constant value. This is known as
the Equilibrium Law or Law of Chemical = x1/2 = Kc1/2 (6.10)
Equilibrium. On multiplying the equation (6.5) by n, we get

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EQUILIBRIUM 177

nH2(g) + nI2(g) D 2nHI(g) (6.11)
Therefore, equilibrium constant for the N2(g) + O2(g) 2NO(g)
reaction is equal to Kc n. These findings are Solution
summarised in Table 6.4. It should be noted
that because the equilibrium constants Kc For the reaction equilibrium constant, Kc
and K ′c have different numerical values, it is can be written as,
2
important to specify the form of the balanced NO
Kc =
chemical equation when quoting the value of N 2 O2
an equilibrium constant. 2
2.8 10–3M
Table 6.4 Relations between Equilibrium =
Constants for a General Reaction 3.0 10 3 M 4.2 10 3 M
and its Multiples.
= 0.622
Chemical equation Equilibrium
constant
aA+bB c C + dD Kc
6.4 HOMOGENEOUS EQUILIBRIA
cC+dD aA+bB K′c =(1/Kc ) In a homogeneous system, all the reactants
and products are in the same phase.
na A + nb B ncC + ndD K′″c = (Kcn )
For example, in the gaseous reaction,
N 2(g) + 3H 2(g) 2NH 3(g), reactants and
products are in the homogeneous phase.
Problem 6.1
Similarly, for the reactions,
The following concentrations were CH3COOC2H5 (aq) + H2O (l) CH3COOH (aq)
obtained for the formation of NH3 from + C2H5OH (aq)
N 2 and H 2 at equilibrium at 500K.
[N2] = 1.5 × 10–2M. [H2] = 3.0 ×10–2 M and and, Fe3+ (aq) + SCN–(aq) Fe(SCN)2+ (aq)
[NH3] = 1.2 ×10–2M. Calculate equilibrium all the reactants and products are in
constant. homogeneous solution phase. We shall now
consider equilibrium constant for some
Solution
homogeneous reactions.
The equilibrium constant for the reaction,
N2(g) + 3H2(g) 2NH3(g) can be written as, 6.4.1 Equilibrium Constant in Gaseous
Systems
 NH3  g 
2
So far we have expressed equilibrium
Kc = constant of the reactions in terms of molar
 N 2  g  H2  g 
3
concentration of the reactants and products,
and used symbol, Kc for it. For reactions
=
1.2  10  2 2
involving gases, however, it is usually more
1.5  10  3.0  10 
2 2 3
convenient to express the equilibrium
constant in terms of partial pressure.
= 0.355 × 103 = 3.55 × 102 The ideal gas equation is written as,
pV = nRT
Problem 6.2
n
At equilibrium, the concentrations of ⇒ p = RT
N 2=3.0 × 10 –3M, O 2 = 4.2 × 10 –3M and V
NO= 2.8 × 10–3M in a sealed vessel at 800K. Here, p is the pressure in Pa, n is the number
What will be Kc for the reaction of moles of the gas, V is the volume in m3 and
T is the temperature in Kelvin

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 178 chemistry

Therefore,
n/V is concentration expressed in mol/m3  NH3 ( g ) [RT ]
2 −2

=  = K c ( RT )
−2
If concentration c, is in mol/L or mol/dm3,
 N 2 ( g ) H 2 ( g )
3
and p is in bar then
p = cRT,
or K p = K c ( RT ) (6.14)
−2
We can also write p = [gas]RT.
Here, R= 0.0831 bar litre/mol K Similarly, for a general reaction
At constant temperature, the pressure of aA + bB cC + dD
the gas is proportional to its concentration i.e.,
p ∝ [gas]
Kp =
( p )( p ) [C] [D] ( RT )(
C
c

=
d
D
c d c +d )

For reaction in equilibrium ( p )( p ) [ A ] [B] (RT )(
a
A
b
B
a b a +b )

H2(g) + I2(g) 2HI(g)
We can write either [ C ] [D]
c d

RT )
(c + d ) −(a +b )
b (
=
HI ( g )
2
[ A ] [B ]
a

Kc =
H2 ( g ) I2 ( g )
[ C ] [D]
c d

RT )
∆n
= K c ( RT )
∆n
b (
= (6.15)
or K c =
( p HI ) 2

(6.12)
[ A ] [B ]
a

( p )( p )
H2 I2
where ∆n = (number of moles of gaseous
products) – (number of moles of gaseous
Further, since p HI = HI ( g ) RT reactants) in the balanced chemical equation.
It is necessary that while calculating the value
pI2 = I2 ( g ) RT of Kp, pressure should be expressed in bar
p H2 = H2 ( g ) RT because standard state for pressure is 1 bar.
We know from Unit 1 that :
Therefore, 1pascal, Pa=1Nm–2, and 1bar = 105 Pa
HI ( g ) [RT ] Kp values for a few selected reactions at
( pHI )2
2 2

Kp = = different temperatures are given in Table 6.5
( p )( p )
H2 I2
H2 ( g ) RT. I2 ( g ) RT
Table 6.5 Equilibrium Constants, Kp for
HI ( g )
2
a Few Selected Reactions
= = Kc (6.13)
H2 ( g ) I2 ( g )
In this example, K p = K c i.e., both
equilibrium constants are equal. However,
this is not always the case. For example in
reaction
N2(g) + 3H2(g) 2NH3(g)

(p )
2
NH 3
Kp =
( p )( p )
3
N2 H2

Problem 6.3
 NH3 ( g ) [RT ]
2 2

= PCl5, PCl3 and Cl2 are at equilibrium at 500
 N 2 ( g ) RT. H 2 ( g ) (RT )
3 3
K and having concentration 1.59M PCl3,
1.59M Cl2 and 1.41 M PCl5.

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 EQUILIBRIUM 179

Calculate Kc for the reaction, the value 0.194 should be neglected because
PCl5 PCl3 + Cl2 it will give concentration of the reactant
Solution which is more than initial concentration.
The equilibrium constant Kc for the above Hence the equilibrium concentrations are,
reaction can be written as, [CO2] = [H2-] = x = 0.067 M

Kc 
PCl  Cl   1.59
3 2
2

 1.79
[CO] = [H2O] = 0.1 – 0.067 = 0.033 M
PCl 5 1.41 Problem 6.5
Problem 6.4 For the equilibrium,
The value of K c = 4.24 at 800K for the 2NOCl(g) 2NO(g) + Cl2(g)
reaction, the value of the equilibrium constant, Kc is
CO (g) + H2O (g) CO2 (g) + H2 (g) 3.75 × 10 –6 at 1069 K. Calculate the Kp for
Calculate equilibrium concentrations of CO2, the reaction at this temperature?
H2, CO and H2O at 800 K, if only CO and
H2O are present initially at concentrations Solution
of 0.10M each.
We know that,
Solution Kp = Kc(RT)∆n
For the reaction, For the above reaction,
CO (g) + H2O (g) CO2 (g) + H2 (g) ∆n = (2+1) – 2 = 1
Kp = 3.75 ×10–6 (0.0831 × 1069)
Initial concentration:
Kp = 0.033
0.1M 0.1M 0 0
Let x mole per litre of each of the product
be formed. 6.5 HETEROGENEOUS EQUILIBRIA
At equilibrium: Equilibrium in a system having more than one
(0.1-x) M (0.1-x) M xM xM phase is called heterogeneous equilibrium.
The equilibrium between water vapour and
where x is the amount of CO2 and H2 at
equilibrium. liquid water in a closed container is an
example of heterogeneous equilibrium.
Hence, equilibrium constant can be written
as, H2O(l) H2O(g)
Kc = x2/(0.1-x)2 = 4.24 In this example, there is a gas phase and
x2 = 4.24(0.01 + x2-0.2x) a liquid phase. In the same way, equilibrium
x2 = 0.0424 + 4.24x2-0.848x between a solid and its saturated solution,
3.24x2 – 0.848x + 0.0424 = 0 Ca(OH)2 (s) + (aq) Ca2+ (aq) + 2OH–(aq)
a = 3.24, b = – 0.848, c = 0.0424 is a heterogeneous equilibrium.
(for quadratic equation ax2 + bx + c = 0, Heterogeneous equilibria often involve

x
 b  b2  4ac  pure solids or liquids. We can simplify
equilibrium expressions for the heterogeneous
2a equilibria involving a pure liquid or a pure
x = 0.848±√(0.848)2– 4(3.24)(0.0424)/ solid, as the molar concentration of a pure
solid or liquid is constant (i.e., independent
(3.24×2)
of the amount present). In other words if a
x = (0.848 ± 0.4118)/ 6.48
substance ‘X’ is involved, then [X(s)] and [X(l)]
x1 = (0.848 – 0.4118)/6.48 = 0.067 are constant, whatever the amount of ‘X’ is
x2 = (0.848 + 0.4118)/6.48 = 0.194 taken. Contrary to this, [X(g)] and [X(aq)] will

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 180 chemistry

vary as the amount of X in a given volume This shows that at a particular
varies. Let us take thermal dissociation of temperature, there is a constant concentration
calcium carbonate which is an interesting and or pressure of CO2 in equilibrium with CaO(s)
important example of heterogeneous chemical and CaCO3(s). Experimentally it has been
equilibrium. found that at 1100 K, the pressure of CO2
in equilibrium with CaCO3(s) and CaO(s), is
CaCO3 (s) CaO (s) + CO2 (g) (6.16) 2.0 ×105 Pa. Therefore, equilibrium constant
On the basis of the stoichiometric equation, at 1100K for the above reaction is:
we can write, Kp = PCO2 = 2 × 105 Pa/105 Pa = 2.00
CaO  s  CO2  g  Similarly, in the equilibrium between
Kc 
CaCO3  s  nickel, carbon monoxide and nickel carbonyl
(used in the purification of nickel),
Since [CaCO3(s)] and [CaO(s)] are both
constant, therefore modified equilibrium Ni (s) + 4 CO (g) Ni(CO)4 (g),
constant for the thermal decomposition of the equilibrium constant is written as
calcium carbonate will be
 Ni CO 4 
K´c = [CO2(g)] (6.17) Kc  
or Kp = pCO (6.18) CO4
2

It must be remembered that for the
existence of heterogeneous equilibrium pure
Units of Equilibrium Constant solids or liquids must also be present (however
The value of equilibrium constant Kc can be small the amount may be) at equilibrium, but
calculated by substituting the concentration their concentrations or partial pressures do
terms in mol/L and for Kp partial pressure not appear in the expression of the equilibrium
is substituted in Pa, kPa, bar or atm. This constant. In the reaction,
results in units of equilibrium constant based Ag2O(s) + 2HNO3(aq) 2AgNO3(aq) +H2O(l)
on molarity or pressure, unless the exponents
of both the numerator and denominator are
 AgNO 
2
3
same. Kc =
HNO 
2
For the reactions, 3
H2(g) + I2(g) 2HI, Kc and Kp have no
unit.
N2O4(g) 2NO2 (g), Kc has unit mol/L
and Kp has unit bar Problem 6.6
Equilibrium constants can also be The value of Kp for the reaction,
expressed as dimensionless quantities if the CO2 (g) + C (s) 2CO (g)
standard state of reactants and products is 3.0 at 1000 K. If initially PCO = 0.48
2
are specified. For a pure gas, the standard bar and PCO = 0 bar and pure graphite is
state is 1bar. Therefore a pressure of 4 bar present, calculate the equilibrium partial
in standard state can be expressed as 4 pressures of CO and CO2.
bar/1 bar = 4, which is a dimensionless
number. Standard state (c0) for a solute is 1 Solution
molar solution and all concentrations can be For the reaction,
measured with respect to it. The numerical
value of equilibrium constant depends on the
let ‘x’ be the decrease in pressure of CO2,
standard state chosen. Thus, in this system
then
both Kp and Kc are dimensionless quantities CO2(g) + C(s) 2CO(g)
but have different numerical values due to Initial
different standard states. pressure: 0.48 bar 0

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 EQUILIBRIUM 181

5. The equilibrium constant K for a reaction
At equilibrium: is related to the equilibrium constant
(0.48 – x)bar 2x bar of the corresponding reaction, whose
equation is obtained by multiplying or
pC2 O dividing the equation for the original
Kp =
pC O2 reaction by a small integer.

Kp = (2x)2/(0.48 – x) = 3 Let us consider applications of equilibrium
constant to:
4x2 = 3(0.48 – x)
predict the extent of a reaction on the
4x2 = 1.44 – x basis of its magnitude,
4x2 + 3x – 1.44 = 0
predict the direction of the reaction, and
a = 4, b = 3, c = –1.44

b  
calculate equilibrium concentrations.
b2  4ac
x 6.6.1 Predicting the Extent of a
2a Reaction
= [–3 ± √(3)2– 4(4)(–1.44)]/2 × 4 The numerical value of the equilibrium
= (–3 ± 5.66)/8 constant for a reaction indicates the extent
of the reaction. But it is important to note
= (–3 + 5.66)/8 (as value of x cannot be that an equilibrium constant does not give
negative hence we neglect that value)
any information about the rate at which
x = 2.66/8 = 0.33 the equilibrium is reached. The magnitude
The equilibrium partial pressures are, of Kc or Kp is directly proportional to the
concentrations of products (as these appear
pCO = 2x = 2 × 0.33 = 0.66 bar
2 in the numerator of equilibrium constant
pCO = 0.48 – x = 0.48 – 0.33 = 0.15 bar expression) and inversely proportional to the
2
concentrations of the reactants (these appear
6.6 APPLICATIONS OF EQUILIBRIUM in the denominator). This implies that a high
CONSTANTS value of K is suggestive of a high concentration
of products and vice-versa.
Before considering the applications of
equilibrium constants, let us summarise the We can make the following generalisations
important features of equilibrium constants concerning the composition of equilibrium
as follows: mixtures:
1. Expression for equilibrium constant is If Kc > 103, products predominate over
applicable only when concentrations of reactants, i.e., if Kc is very large, the
the reactants and products have attained reaction proceeds nearly to completion.
constant value at equilibrium state. Consider the following examples:
2. The value of equilibrium constant is (a) The reaction of H 2 with O 2 at 500 K
independent of initial concentrations of has a very large equilibrium constant,
the reactants and products. Kc = 2.4 × 1047.
3. Equilibrium constant is temperature (b) H2(g) + Cl 2(g) 2HCl(g) at 300K has
dependent having one unique value for Kc = 4.0 × 1031.
a particular reaction represented by a (c) H 2(g) + Br 2(g) 2HBr (g) at 300 K,
balanced equation at a given temperature. Kc = 5.4 × 1018
4. The equilibrium constant for the reverse
If Kc < 10–3, reactants predominate over
reaction is equal to the inverse of the
products, i.e., if Kc is very small, the
equilibrium constant for the forward
reaction proceeds rarely. Consider the
reaction. following examples:

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 182 chemistry

(a) The decomposition of H2O into H2 and If Qc = Kc, the reaction mixture is already
O2 at 500 K has a very small equilibrium at equilibrium.
constant, Kc = 4.1 × 10 –48 Consider the gaseous reaction of H 2
(b) N2(g) + O2(g) 2NO(g), with I2,
at 298 K has Kc = 4.8 ×10 – 31. H2(g) + I2(g) 2HI(g); Kc = 57.0 at 700 K.
If K c is in the range of 10 – 3 to 10 3 , Suppose we have molar concentrations
appreciable concentrations of both [H2]t=0.10M, [I2]t = 0.20 M and [HI]t = 0.40 M.
reactants and products are present. (the subscript t on the concentration symbols
Consider the following examples: means that the concentrations were measured
(a) For reaction of H2 with I2 to give HI, at some arbitrary time t, not necessarily at
equilibrium).
Kc = 57.0 at 700K.
Thus, the reaction quotient, Qc at this
(b) Also, gas phase decomposition of N2O4
stage of the reaction is given by,
to NO2 is another reaction with a value
Qc = [HI]t2 / [H2]t [I2]t = (0.40)2/ (0.10)×(0.20)
of K c = 4.64 × 10 –3 at 25°C which is
neither too small nor too large. Hence, = 8.0
equilibrium mixtures contain appreciable Now, in this case, Qc (8.0) does not equal
concentrations of both N2O4 and NO2. Kc (57.0), so the mixture of H2(g), I2(g) and HI(g)
These generarlisations are illustrated in is not at equilibrium; that is, more H2(g) and
Fig. 6.6 I2(g) will react to form more HI(g) and their
concentrations will decrease till Qc = Kc.
The reaction quotient, Q c 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
Fig.6.6 Dependence of extent of reaction on Kc the reaction (Fig. 6.7) :

6.6.2 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 (Q c with molar
concentrations and QP with partial pressures) Fig. 6.7 Predicting the direction of the reaction
is defined in the same way as the equilibrium If Qc < Kc, net reaction goes from left to
constant Kc except that the concentrations right
in Qc are not necessarily equilibrium values. If Qc > Kc, net reaction goes from right to
For a general reaction: left.
aA+bB c C + d D (6.19) If Qc = Kc, no net reaction occurs.
Qc = [C]c[D]d / [A]a[B]b (6.20)
Problem 6.7
Then,
The value of Kc for the reaction
If Qc > Kc, the reaction will proceed in the 2A B + C is 2 × 10–3. At a given time,
direction of reactants (reverse reaction). the composition of reaction mixture is
If Qc < Kc, the reaction will proceed in the [A] = [B] = [C] = 3 × 10–4 M. In which direction
the reaction will proceed?
direction of the products (forward reaction).

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 EQUILIBRIUM 183

Solution The total pressure at equilbrium was
For the reaction the reaction quotient Qc is found to be 9.15 bar. Calculate Kc, Kp and
given by, partial pressure at equilibrium.
Qc = [B][C]/ [A]2 Solution
as [A] = [B] = [C] = 3 × 10–4M
Qc = (3 ×10–4)(3 × 10 –4) / (3 ×10 –4)2 = 1 We know pV = nRT
as Qc > Kc so the reaction will proceed in the Total volume (V ) = 1 L
reverse direction.
Molecular mass of N2O4 = 92 g
6.6.3 Calculating Equilibrium Number of moles = 13.8g/92 g = 0.15
Concentrations of the gas (n)
In case of a problem in which we know the Gas constant (R) = 0.083 bar L mol–1K–1
initial concentrations but do not know any of Temperature (T ) = 400 K
the equilibrium concentrations, the following
three steps shall be followed: pV = nRT
Step 1. Write the balanced equation for the p × 1L = 0.15 mol × 0.083 bar L mol–1K–1
reaction. × 400 K
Step 2. Under the balanced equation, make p = 4.98 bar
a table that lists for each substance involved N2O4 2NO2
in the reaction: Initial pressure: 4.98 bar 0
(a) the initial concentration, At equilibrium: (4.98 – x) bar 2x bar
(b) the change in concentration on going to Hence,
equilibrium, and ptotal at equilibrium = pN + pNO
2O4 2
(c) the equilibrium concentration.
9.15 = (4.98 – x) + 2x
In constructing the table, define x as the
concentration (mol/L) of one of the substances 9.15 = 4.98 + x
that reacts on going to equilibrium, then use x = 9.15 – 4.98 = 4.17 bar
the stoichiometry of the reaction to determine Partial pressures at equilibrium are,
the concentrations of the other substances in
pN = 4.98 – 4.17 = 0.81bar
terms of x. 2O4
pNO = 2x = 2 × 4.17 = 8.34 bar
Step 3. Substitute the equilibrium 2

 
2
concentrations into the equilibrium equation K p = p NO2 / p N 2O4
for the reaction and solve for x. If you are
= (8.34)2/0.81 = 85.87
to solve a quadratic equation choose the
mathematical solution that makes chemical Kp = Kc(RT)∆n
sense. 85.87 = Kc(0.083 × 400)1
Step 4. Calculate the equilibrium Kc = 2.586 = 2.6
concentrations from the calculated value of x.
Step 5. Check your results by substituting Problem 6.9
them into the equilibrium equation. 3.00 mol of PCl5 kept in 1L closed reaction
vessel was allowed to attain equilibrium
at 380K. Calculate composition of the
Problem 6.8 mixture at equilibrium. Kc= 1.80
13.8g of N2O4 was placed in a 1L reaction Solution
vessel at 400K and allowed to attain PCl5 PCl3 + Cl2
equilibrium Initial
N 2O4 (g) 2NO2 (g) concentration: 3.0 0 0

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 184 chemistry

Taking antilog of both sides, we get,
Let x mol per litre of PCl5 be dissociated,
At equilibrium: K = e–∆G/RT (6.23)
(3-x) x x Hence, using the equation (6.23), the
Kc = [PCl3][Cl2]/[PCl5] reaction spontaneity can be interpreted in
terms of the value of ∆G .
1.8 = x2/ (3 – x)
If ∆G  < 0, then –∆G /RT is positive,
x2 + 1.8x – 5.4 = 0
and e –∆DG /RT>1, making K >1, which
x = [–1.8 ± √(1.8)2 – 4(–5.4)]/2 implies a spontaneous reaction or the
x = [–1.8 ± √3.24 + 21.6]/2 reaction which proceeds in the forward
direction to such an extent that the
x = [–1.8 ± 4.98]/2
products are present predominantly.
x = [–1.8 + 4.98]/2 = 1.59
If ∆G  > 0, then –∆G /RT is negative, and
[PCl5] = 3.0 – x = 3 –1.59 = 1.41 M
e –∆G [OH– ]
Some substances like water are unique in
their ability of acting both as an acid and a Neutral: [H3O+] = [OH– ]
base. We have seen this in case of water in Basic : [H3O+] < [OH–]
section 6.10.2. In presence of an acid, HA it
accepts a proton and acts as the base while 6.11.2 The pH Scale
in the presence of a base, B– it acts as an Hydronium ion concentration in molarity is
acid by donating a proton. In pure water, one more conveniently expressed on a logarithmic
H2O molecule donates proton and acts as an scale known as the pH scale. The pH of a
acid and another water molecules accepts a solution is defined as the negative logarithm
proton and acts as a base at the same time.
The following equilibrium exists:
to base 10 of the activity a H   of hydrogen

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 194 chemistry

ion. In dilute solutions (< 0.01 M), activity when the hydrogen ion concentration, [H+]
of hydrogen ion (H+) is equal in magnitude changes by a factor of 100, the value of pH
to molarity represented by [H+]. It should changes by 2 units. Now you can realise why
be noted that activity has no units and is the change in pH with temperature is often
defined as: ignored.
= [H+] / mol L–1 Measurement of pH of a solution is very
From the definition of pH, the following essential as its value should be known
when dealing with biological and cosmetic
can be written,
applications. The pH of a solution can be
pH = – log aH+ = – log {[H+] / mol L–1} found roughly with the help of pH paper that
Thus, an acidic solution of HCl (10–2 M) has different colour in solutions of different
will have a pH = 2. Similarly, a basic solution pH. Now-a-days pH paper is available with
of NaOH having [OH–] =10–4 M and [H3O+] = four strips on it. The different strips have
10–10 M will have a pH = 10. At 25 °C, pure different colours (Fig. 6.11) at the same pH.
water has a concentration of hydrogen ions, The pH in the range of 1-14 can be determined
[H + ] = 10–7 M. Hence, the pH of pure water is with an accuracy of ~0.5 using pH paper.
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
Fig.6.11 pH-paper with four strips that may have
Acidic solution has pH < 7 different colours at the same pH
Basic solution has pH > 7
Neutral solution has pH = 7 For greater accuracy pH meters are used.
pH meter is a device that measures the
Now again, consider the equation (6.28)
pH-dependent electrical potential of the test
at 298 K
solution within 0.001 precision. pH meters
Kw = [H3O+] [OH–] = 10–14
of the size of a writing pen are now available
Taking negative logarithm on both sides in the market. The pH of some very common
of equation, we obtain substances are given in Table 6.5 (page 195).
–log Kw = – log {[H3O+] [OH–]}
Problem 6.16
= – log [H3O+] – log [OH–]
The concentration of hydrogen ion in a
= – log 10 –14
sample of soft drink is 3.8 × 10–3M. what
pKw = pH + pOH = 14 (6.29) is its pH ?
Note that although K w may change
with temperature the variations in pH with Solution
temperature are so small that we often pH = – log[3.8 × 10–3]
ignore it. = – {log[3.8] + log[10–3]}
pK w is a very important quantity for = – {(0.58) + (– 3.0)} = – { – 2.42} = 2.42
aqueous solutions and controls the relative Therefore, the pH of the soft drink is 2.42
concentrations of hydrogen and hydroxyl and it can be inferred that it is acidic.
ions as their product is a constant. It should
Problem 6.17
be noted that as the pH scale is logarithmic,
a change in pH by just one unit also means Calculate pH of a 1.0 × 10 –8 M solution of
change in [H+] by a factor of 10. Similarly, HCl.

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 EQUILIBRIUM 195

Table 6.5 The pH of Some Common Substances

Name of the Fluid pH Name of the Fluid pH

Saturated solution of NaOH ~15 Black Coffee 5.0
0.1 M NaOH solution 13 Tomato juice ~4.2
Lime water 10.5 Soft drinks and vinegar ~3.0
Milk of magnesia 10 Lemon juice