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Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry PDF Download

GALVANIC CELL

 This cell converts chemical energy into electrical energy.

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

Galvanic cell is made up of two half cells i.e., anodic and cathodic. The cell reaction is of redox kind.
Oxidation takes place at anode and reduction at cathode. It is also known as voltaic cell.  It may be represented as shown in Fig. Zinc rod immersed in ZnSO4 behaves as anode and copper rod immersed in CuSO4 behaves as cathode.
 

Oxidation takes place at anode: 

Zn → Zn2+  + 2e-  (loss of electron : oxidation)

Reduction takes place at cathode: 
Cu2+ + 2e →  Cu (gain of electron ; reduction)

Over all process: 
Zn(s) + Cu2+     →   Cu(s) + Zn2+
In galvanic cell like Daniell cell; electrons flow from anode (zinc rod) to the cathode (copper rod) through external circuit; zinc dissolves as Zn2+ ; Cu2+ ion in the cathode cell picks up two electron and become deposited at cathode.

SALT BRIDGE

Two electrolyte solutions in galvanic cells are seperated using salt bridge as represented in the Fig.  salt bridge is a device to minimize or eliminate the liquid junction potential. Saturated solution of salt like KCI, KNO3, NH4Cl and NH4NO3 etc. in agar-agar gel is used in salt bridge. Salt bridge contains high concentration of ions viz. Kand NO3- at the junction with electrolyte solution. Thus, salt bridge carries whole of the  current across the boundary ; more over the K+and NO3- ions have same speed.
Hence, salt bridge with uniform and same mobility of cations and anions minimize the liquid junction potential & completes the electrical circuit  & permits the ions to migrate

 REPRESENTATION OF AN ELECTROCHEMICAL CELL (GALVANIC CELL)

The following universally accepted conversions are followed in representing an electrochemical cell :

(i) The anode (negative electrode) is written on the left hand side and cathode (positive electrode) on the right hand side.
(ii) A vertical line or semicolon (;) indicates a contact between two phases. The anode of the cell is represented by writing metal first and then the metal ion present in the electrolytic solution.  Both are separated by a vertical line or a semicolon. For example Zn | Zn2+  or  Zn ; Zn2+ The molar concentration or activity of the solution is written in brackets after the formula of the ion.
For example

Zn | Zn2+  (1 M)  or  Zn | Zn2+ (0.1 M)

(iii) The cathode of the cell is represented by writing the cation of the electrolyte first and then metal. Both are separated by a vertical line or semicolon.
For example,

Cu2+ | Cu or Cu2+ ; Cu or Cu2+ (1 M) | Cu

(iv) The salts bridge which separates the two half-cells is indicated by two parallel vertical lines.

(v) Sometimes negative and positive signs are also put on the electrodes.
The Daniel cell can be represented as :

Zn | ZnSO4(aq)  ||  CuSO4(aq) | Cu

Anode        Salt bridge       Cathode

Oxidation    half-cellReduction half-cell

or Z n | Z n2+ || Cu2+ | Cu
or Zn | Zn2+ (1 M) || Cu2+ (1 M) | Cu

 

ELECTROCHEMICAL SERIES

By measuring the potentials of various electrodes versus standard hydrogen electrode (SHE), a series of standard electrode potentials has been established.  When the electrodes metals and non-metals) in contact with their ions are arranged on the basis of the values of their standard reduction potential or standard oxidation potential, the resulting series is called the electrochemical or electromotive or active series of the elements Standard Aqueous Electrode Potentials at 25°C

‘The Electrochemical Series’

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry
Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry
Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry
Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

APPLICATION  OF ELECTROCHEMICAL SERIES

(i) Reactivity of metals : The activity of the metal depends on its tendency to lose electron or electrons, i.e., tendency to form cation (Mn+).  This tendency depends on the magnitude of standard reduction potential. The metal which has high negative value (or smaller positive value) of standard reduction potential readily loses the electrons and is converted into cation.  Such a metal is said to be chemically active.
The chemical reactivity of metals decreases from top to bottom in the series. The metal higher in the series is more active than the metal lower in the series. For example,

(a) Alkali metals and alkaline earth metals having high negative values of standard reduction potentials are chemically active.  These react with cold water and evolve hydrogen. These readily dissolve in acids forming corresponding salts and combine with those substance which accept electrons.

(b) Metals like Fe, Pb, Sn, Ni, Co, etc., which lie a little down in the series do not react with cold water but react with steam to evolve hydrogen.

(c) Metals like Cu, Ag and Au which lie below hydrogen are less reactive and do not evolve hydrogen from water.

(ii) Electropositive character of metals : the electropositive character also depends on the tendency to lose electron or electrons. Like reactivity, the electropositive character of metals decreases from top to bottom in the electrochemical series. On the basis of standard reduction potential values, metals are divided into three groups :

(a) Strongly electropositive metals : Metals having standard reduction potential near about 2.0 volt or more negative like alkali metals, alkaline earth metals are strongly electropositive in nature.

(b) Moderately electropositive metals. Metals having values of reduction potential between 0.0 and about – 2.0 volt are moderately electropositive. Al, Zn, Fe, Ni, Co, etc., belong to this group.

(c) Weakly electropositive metals :  The metals which are below hydrogen and possess positive values of reduction potentials are weakly electropositive metals. Cu, Hg, Ag, etc., belong to this group.

 

(iii) Displacement reactions :

(a) To predict whether a given metal will displace another, from its salt solution :  A metal higher in the series will displace the metal from its solution which is lower in the series, i.e., the metal having low standard reduction potential will displace the metal from its salt’s solution which has higher value of standard reduction potential. A metal higher in the series has greater tendency to provide electrons to the cations of the metal to be precipitated.

(b) Displacement of one non-metals from its salt solution by another non metal : A nonmetal higher in the series (towards bottom side), i.e.,  having high value of reduction potential will displace another non metal with lower reduction potential i.e., occupying position above in he series. The nonmetal’s which possess high positive  reduction potentials have the tendency to accept electrons readily.  These electrons are provided by the ions of the nonmetal having low value of reduction potential.  Thus, Clcan displace bromine and iodine from bromides and iodides.

Cl2 + 2KI   →  2KCl + I2
2I- →  I2 + 2e- (Oxidation)
Cl+ 2e- →  2Cl- (Reduction)

 [The activity or electronegative character or oxidising nature of the nonmetal increases as the value of reduction potential increases.]

(c) Displacement of hydrogen from dilute acids by metals :  The metal which can provide electrons to H+ ions present in dilute acids for reduction, evolve hydrogen from dilute acids.
Mn   →  Mnn+ + ne- (Oxidation)
2H+ 2e- →  H2 (Reduction)
The metal having negative values of reduction potential possess the property of losing electron or electrons.
Thus, the metals occupying top positions in the electrochemical series readily liberate hydrogen from dilute acids and on descending in the series tendency to liberate hydrogen gas from dilute acids decreases.
The metals which are below hydrogen in electrchemical series like Cu, Hg, Au, Pt, etc., do not evolve hydrogen from dilute acids.

(d) Displacement of hydrogen from water :  Iron and the metals above iron are capable of liberating hydrogen from water.  The tendency decreases from top to bottom in electrochemical series.
Alkali and alkaline earth metals liberate hydrogen from cold water but Mg, Zn and Fe liberate hydrogen from hot water or steam.

(iv) Reducing power of metals :  Reducing nature depends on the tendency of losing electron or electrons.
More the negative reduction potential, more is the tendency to lose electron or electrons. Thus, reducing nature decreases from top to bottom in the electrochemical series.  The power of the reducing agent increases as the standard reduction potential becomes more and more negative.
Sodium is a stronger reducing agent than zinc and zinc is a stronger reducing agent than iron.

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

Reducing nature decreases

Alkali and alkaline earth metals are strong reducing decreases.

(v) Oxidising nature of nonmetals : Oxidising nature depends on the tendency to accept electron of electrons. More the value of reduction potential, higher is the tendency to accept electron or electrons.
Thus, oxidising nature increases from top to bottom in the electrochemical series. The strength of an oxidising agent increases as the value of reduction potential becomes more and more positive.
F2 (Fluorine) is a stronger oxidant than Cl2 , Br2 and I2.
Cl2 (Chlorine) is a stronger oxidant than Br2 and I2.

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

Oxidising nature increases

 Thus, in electrochemical series T

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

(vi) Thermal stability of metallic oxides : The thermal stability of the metal oxide depends on its electropositive nature.  As the electropositivity decreases from to top bottom, the thermal stability of the oxide also decreases from top to bottom. The oxides of metals having high positive reduction potential are not stable towards heat.  The metals which come below copper form unstable oxides, i.e. these are decomposed on heating.

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry
Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry
Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

 

(vii) Product of electrolysis : In case two or more type of positive and negative ions are present in solution, during electrolysis certain ions are discharged or liberated at the electrode in preference to others. In general, in such competition the ions which is stronger oxidising agent (high value of standard reduction potential) is discharged first at the cathode. The increasing order of deposition of few cations is :

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

Similarly, the anion which is stronger reducing agent (low value of standard reduction potential) is liberated first at the anode.
The increasing order of discharge of few anion is :

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

Thus, when an aqueous solution of NaCl containing Na+, Cl, H+ and OH ions is electrolysed, H+ ions are discharged at cathode and Cl ions at the anode, i.e., H2 is liberated at cathode and chlorine at anode.
When an aqueous solution of CuSO4 containing Cu2+, SO42–, H+ and OH ions is electrolysed, Cu2+ ions are discharged at cathode and OH ions at the anode.
Cu2+ + 2e →  Cu (Cathodic reaction)
4OH →  O2 + 2H2O + 4e- (Anodic reaction)
Cu is deposited on cathode while O2 is liberated at anode.

 

(viii) Corrosion of metals :  Corrosion is defined as the deterioration of a substance because of its reaction with its environment.  This is also defined as the process by which metals have the tendency to go back to their combined state, i.e., reverse of extraction of metals.
Ordinary corrosion is a redox reaction by which metals are oxidised by oxygen in presence of moisture.
Oxidation of metals occurs more readily at points of strain.  Thus, a steel nail first corrodes at the tip and head. The end of a steel nail acts as an anode where iron is oxidised to Fe2+ ions.
Fe   →  Fe2 + 2e-  (Anode reaction)
The electrons flow along the nail to areas containing impurities which act as cathodes where oxygen is reduced to hydroxyl ions.
O2 + 2H2O + 4e →  4OH-  (Cathode reaction)


REVERSIBLE AND IRREVERSIBLE CELLS

In dealing with the energy relations of cells, thermodynamic principles find extensive applications.
However, the use of these principles is subject to one important restriction, namely, that the system to which they are applied be reversible in thermodynamic sense.  This require that :
(1) the driving and opposing forces the infinitesimally different from each other, and
(2) it should be possible to reverse any change taking place by applying a force infinitesimally greater than the acting one.
A cell satisfying the above two requirements constitutes a reversible cell.  The potential difference of the cell can be substituted into the relevant thermodynamic relations and hence the value of thermodynamic properties such as free energy change, entropy change and enthalpy change of the cell reaction can be determined.  When the above conditions are not satisfied, the cell is said to be irreversible, and thermodynamic relations do not apply.
The difference between reversible and irreversible cells may be illustrated with the following two examples.

Example of Reversible Cell 

Consider a cell composed of Zn and Ag-AgCl electrodes into an aqueous solution of zinc chloride. As seen earlier, the following reactions take place on connecting externally.
Anode 1/2 Zn(s) →  1/2 Zn2+(aq) + e-
Cathode : AgCl(s) + e- → Ag(s) + Cl-(aq)
with the net reaction 1/2Zn(s) + AgCl(s) → Ag(s) + 1/2 Zn2+(aq) + Cl-(aq)

The above process continues as long as the external opposing potential is infinitesimally smaller than that of the cell.  However, if the opposing potential becomes slightly larger than that of the cell, the direction of current flow is reversed, and so is the cell reaction.  Now zinc ions are converted to zinc at one electrode, silver chloride is formed from silver and chloride ions at the other, and the overall cell reaction becomes

Ag(s) 1/2 Zn2+ (aq) + Cl-(aq) → 1/2 Zn(s) + AgCl(s)
Thus, it is  obvious that the second condition of irreversibility mentioned above is satisfied.  The first condition can be satisfied by drawing from or passing through the cell a very minute current. Hence, the cell is reversible.

STANDARD ELECTRODE POTENTIAL

The potential difference developed between metal electrode and the solution of its ions of unit molarity (1 M) at 25°C (298 K) is called standard electrode potential.

 Standard reduction potential = – (Standard oxidation potential)
 or Standard oxidation potential = – (Standard reduction potential) 


CONCEPT OF ELECTROMOTIVE FORCE (EMF) OFA CELL

Electron flows from anode to cathode in external circuit due to a pushing effect called electromotive force (e.m.f.). E.m.f. is some times called as cell potential. Unit of e.m.f. of cell is volt.
EMF of cell may be calculated as :
Ecell = reduction potential of cathode  - Reduction potential of anode
Similarly, standard e.m.f. of the cell (E°) may be calculated as
cell  = Standard reduction potential  of cathode - Standard reduction potential of anode

SIGN CONVENTION OF EMF
 EMF of cell should be positive other wise it will not be feasible in the given direction .
Zn | ZnSO4 || CuSO4 | Cu        E = +1.10 volt (Feasible)
Cu | CuSO4 || ZnSO4 | Zn           E = -1.10 volt  (Not Feasible)

Nernst Equation 

  • For a single electrode involving the reduction process, Mn+ + ne- → M, the nernst equation is

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry  orGalvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

  •  For an electrochemical cell having net reaction :

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry the EMF can be calculated as

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

  •  In using the above equation, the following facts should be kept in mind.
    (i) Concentration or activity of solids is taken to be UNITY.
    (ii) Concentration of activity of gases is expressed in terms of their partially pressures.
    (iii) n, the number of electrons transferred should be calculated from the balanced net reaction.

Free Energy Change & EMF

  • Relationship between free energy change and cell potential can be written as
    ΔG = -nF Ecell 
    For standard state condition
    ΔG° = -nF E°cell 
  • Equilibrium constant of net cell reaction is related to the standard EMF as

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

EMF  OF GALVANIC CELL

Every galvanic or voltaic cell is made up of two half-cells, the oxidation half-cell (anode) and the reduction half-cell (cathode). The potential of these half-cells are always different. On account of this difference in electrode potentials, the electric current moves from the electrode at higher potential to the electrode at lower potential, i.e. from cathode to anode. The direction of the flow of electrons is from anode to cathode.

 Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry

The difference in potential of the two half-cells is known as the electromotive force (emf) of the cell or cell potential.

The document Galvanic Cells, EMF & Gibbs Free Energy | Physical Chemistry is a part of the Chemistry Course Physical Chemistry.
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FAQs on Galvanic Cells, EMF & Gibbs Free Energy - Physical Chemistry

1. What is a galvanic cell and how does it work?
Ans. A galvanic cell is an electrochemical cell that produces electrical energy through a redox reaction. It consists of two half-cells, each containing an electrode immersed in an electrolyte solution. The oxidation half-cell loses electrons, while the reduction half-cell gains electrons. The flow of electrons between the two half-cells generates an electric current.
2. How is the electromotive force (EMF) related to galvanic cells?
Ans. The electromotive force (EMF) of a galvanic cell is a measure of its ability to produce electrical energy. It is the potential difference between the two electrodes in the cell when no current flows. The EMF is determined by the difference in the reduction potentials of the two half-reactions involved in the cell. A higher EMF indicates a greater driving force for the redox reaction and a higher voltage output.
3. What is the significance of Gibbs free energy in galvanic cells?
Ans. Gibbs free energy is a thermodynamic quantity that determines the spontaneity of a reaction. In galvanic cells, the Gibbs free energy change (∆G) is related to the EMF of the cell through the equation ∆G = -nFEMF, where n is the number of moles of electrons transferred and F is the Faraday constant. A negative ∆G indicates a spontaneous reaction and a positive EMF, while a positive ∆G indicates a non-spontaneous reaction and a negative EMF.
4. Can the EMF of a galvanic cell be used to predict the spontaneity of a redox reaction?
Ans. Yes, the EMF of a galvanic cell can be used to predict the spontaneity of a redox reaction. If the EMF is positive, the reaction is spontaneous and will proceed in the forward direction. If the EMF is negative, the reaction is non-spontaneous and will proceed in the reverse direction. The magnitude of the EMF also provides information about the extent of the reaction and the amount of electrical energy that can be obtained from the cell.
5. How can the Gibbs free energy be related to the voltage output of a galvanic cell?
Ans. The Gibbs free energy change (∆G) is directly related to the voltage output of a galvanic cell. The equation ∆G = -nFEMF relates the two quantities, where n is the number of moles of electrons transferred and F is the Faraday constant. The magnitude of ∆G determines the maximum electrical work that can be obtained from the cell, while the EMF indicates the actual voltage output. The relationship between ∆G and EMF ensures that the cell operates within the limits of thermodynamic feasibility.
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