Thermodynamic parameters from an electrochemical cell - Journal of

May 1, 1970 - Evolution of the Second Law of Thermodynamics. Journal of Chemical Education. Raman. 1970 47 (5), p 331. Abstract | PDF w/ Links | Hi-Re...
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Colin A. Vincent St. SalvatortsCollege University of St. Andrews st. Andrews, Fife, Scotland

I1

Thermodynamic parameters from an Electrochemical Cell

In the teaching of thermodynamics it is common to explain how the free energy and entropy changes of a reaction may he determined by measuring the electromotive force of a suitable electrochemical cell over a range of temperatures. The free energy change is related to the emf by

tions for deriving thermodynamic parameters from cell measurements AGO = -zFEo AS*

=

bEO LF- -

bT

and where z is the number of electrons tranferred in the cell equation and F is Faraday's constant. Also

where AHo and ASo refer t o changes a t absolute zero. ZL is the sum of molar latent heats corresponding to phase transitions occurring at T,K (where TL < T), Z(L/T,) defines the entropy due t o such phase transitions, and AC, is the change in total heat capacity accompanying the reaction. Now provided that the temperature range for the investigation of the cell reaction, TI t o T%,is such that

ST:

Ac-~T

and

In practice however, it is not easy to illustrate these relationships in a simple manner: the main reason is that most reactions for which reversible cells may be set up have very low entropy changes. They have therefore small temperature coefficients of emf, and measuring instruments of great precision are required for their investigation. A notable exception to this is a system involving a reactant in the gas phase, as in the cell Pt,HnlHClIAgClIAg

The use of a hydrogen electrode requires a supply of the gas of adequate purity and involves many difficulties at the teaching level. The reaction now to be discussed has a number of interesting features from the theoretical point of view and many practical advantages 2Ag(s)

are negligible and that no phase changes occur within it, we can say that AG = AH

- TAS

+ HgsCIds)

-

2Hg(l)

+ 2AgCKs)

The electrochemistry of this reaction has been treated a number of times in the literature (1-5); here a cell of simple construction is described which permits a reasonably accurate assessment of the thermodynamic parameters with unsophisticated equipment. The cell is

where and the half-cell reactions are

and

The electrode potentials are given respectively, by El = EOA~IA~CIICI- RT - In actF and

Further

For standard states we therefore have three basic equaVolume 47, Number 5, May

1970

/

365

Ed,

=

& - E,

= EOH~IHC.CI~ICI- E0i\~~hgc~~ci= EOdl

Thc cell emjis independent of the activity of the chloride ion in solution and is thus unaffected by the chloride salt used, its concentration, the solvent, and the presence of other electrolytes, provided that the electrodes remain reversible solely to the chloride ion. There are three particular practical advantages of using this cell for teaching purposes 1) A relat.ively high value of bE/aT coupled withavery small emf permits sufficiently accurate meawrements to he made with "stodent!' Poggendorf potent,iomelers by using the potential divider key in the 0.1 position-i.e., reading 0-170 mV. 2) The electrodes, which are fairly simple to -prepare, are not, readily polarized. 3) There is no liquid junction and hence theverydifficult prohlem of variation of liquid junction potential with temperature is eliminated.

Experimental The cell and electrodes are shown in Figure 1. The cell, (C), consist,^ of a glass U-tube with one wide and one narrow limb. The wide limb contains the electrodes and cell solution while the narrow tuhe permits electrical connection to he made to the mercury of the calomel electrode by means of the plstinum wire contact (Dl.

easily prepared second type (Fig. lA), formed by the chloridiaation of silver wire. The thermd-electrolytic electrodes which have been described in detail hv Bates (7) and elsewhere. were constructed bv sealine a small p l ~ t i n u mwire spiral into a soda-glass tube in suih a way that the wire protruded inside the tuhe to form a, mercury contact. After cleaning the spirals in hailing concentrated HNOs, apaste of spectroscopicdy pure silver oxide in distilled water was applied t o them. This paste was then dried out in an oven a t 90°C before being reduced to silver a t 4SO°C. A further ooat of paste was applied and the procedure repeated. Each electrode finally cantained about 60 mg of silver oxide. The electrodes were ehlaridized by making them the anodes of electrolytic cells containing preelectralyzed 1.0 M HC1 as electrolyte solution and an isolated platinum cathode. Using the amperostat described previously (S),the electrolyses were carried out at a constant current of 10 mA for 800 sec to produce a -15% convemion to silver chloride. The simpler type of AgjAgCl/Cl-electrodes were prepared from 10 cm of 0.02 in. best grade silver wire. The latter w a wound in a wide spiral (Fig. 1.4) and then etched by treating it with 5 M HNO. for 60 sec. The wire was then thoroughly washed with distilled water before beine soaked in oonoentrated ammonia.

use. Emjmeasurementk were made with a "portable potentiometer'' (W. G. Pye and Co. Ltd.) which with its range switch at X0.1 had an absolute accuracv of 3 ~ 0 . 1mV. A number of results were also read on a digital voltmeter (Solmtron Electronic Group Ltd., type LM1420.2). The cell wss immersed in a thermostatted bath, the tempers, ture of which could he regulated to *O.OSDC.

Results

Figure 1.

Cell and electroder.

Calmnrl Elrctrodc. This was prepared aft,er the mrtnner of Hills and Ives (6). Mercury was chemically purified in the standard manner and distilled. Mercurous chloride was precipitated from 0.1 M HCl by acidified Hg2(NO&; the precipitate was stirred for 24 hr during which time the HCI was decanted and replaced three bimes. The cxlomel was filtered, washed, and finally dried under vacuum. A few milligrams were then taken and shaken with 1 ml of clean mernny ta produce a. calomel "skin!' The cell was rendered hydrophobic by treatment with "Desicote" liquid (Beckman Instruments Ltd.) to prevent the so-called "wedge effect" where cell solution seeping between the mercury and cell walls produces erratic behavior in the electrode. The electrode was iiet up by introducing mercury to the cell and then transferring a nmall amount of the calomel skin to bhe mercury surface, over which it rapidly spread. The cell solut,ion, normally approximately 0.1 M HC1, was prepared by diluting "AnalaR" hydrochloric acid with disbilled water. Oxygen was removed from the solution by passing oxygen-free nitrogen through it. The deoxygenated solution was then carefully added to the cell with minimum disturbance of the mercury surface. SilverISilver Chloride Electrode. Two tvoes of AelAeClIC1-, were uskd. The first (Fig. 1B) of the thermal-electrolytic type, proved more reliable over the long term compared wit,h the more

I t was straightforward to show that the emf was independent of the concentration of chloride ion; nor was it influeuced by the medium. A range of HC1 and KC1 concentrations were studied. Further solutions were made up in dioxan-water mixtures and others had quantities of NaCIOa added to them. The emf was unaffected. While cells with both types of AglAgCIIC1- electrode maintained constant emf values within better than 0.1 mV for several days, it was found that a number of cells with type A electrodes (based on silver wire) showed variations of *1 mV after numerous heating and cooling cycles. I t was essential to ensure that none of the materials used was contaminated with bromide or iodide ion. Erratic results were sometimes ohtained if the precautions described in the Experimental section were not carried out. The mean value for the cell emfat 298'IC was 45.6 mV, which agrees well with previous measurements (1, 3). The emf as a function of temperature over the range 15-50°C is shown in Figure 2. Within the accuracy

-

366 / Journal

of Chemical Education

Figure 2 .

Typical experimental variation of cell voltage with temperature.

of the present measurements the results may be represented by a straight line of slope +3.34 X V°K-1, which is again in agreement with the findings of other workers. For the reaction 2Ag(s)

+ Hg~Ch(8)

+ 2AgCl(s)

+ 2Hg(l)

we have AGO

= = =

-zFE' - 2 X 96,491 X 0.0456 -8.80kJ

ASQ

=

bE0 +zF bT

= =

2 X 96,491 X 3 . 3 4 X lo-' 64.5 J°K-1

and

Thus

Figure 3.

T A S o = 19.22 kJ for T

=

298'K

and

Variation of speciflc heat with temperature for silver and

merFUry.

and Sommcl, = 195.8 J0K-'

(16)

Therefore Discussion

Perhaps the main interest in this reaction lies in the fact that the thermodynamic parameters derived from the cell measurements refer to pure single components, and do not involve solution species. Provided that both electrodes remain reversible and have their potentials determined solely by the chloride ion, what comprises the solution phase is of no consequence. Attempts have been made in the past to measure the emf of the cell in nonaqueous solvents, mainly with a view to checking the reversibility of the electrodes for their subsequent use as reference electrodes. Unfortunately, irreproducible results were obtained with acetone (9), acetonitrile (9, lo), and cyclohexanol (lo), pfobably due to disproportionation of the mercurous ion. A constant value of 46.5 mV a t 25'C after an equilibration period has been found with formamide as solvent (18). A somewhat unusual feature of the reaction, as is pointed out by MacInnes (11), is that the enthalpy change is opposite in sign to the free energy changethat is to say, the reaction as written is a spontaneous endothermic process. The reaction enthalpy may be calculated from standard heats of formation determined from calorimetric data (18). Thus

This compares well with the result from the cell, considering the uncertainty of the thermal data. The reaction entropy may be derived from standard entropy values determined from heat capacity measurements together with data on the heat and temperature of melting of mercury. At 29X°K we have

Again the agreement is very reasonable, since there is considerable uncertainty in the standard entropy of calomel, which may be lower than the value here selected (17). I t may be noted that the standard entropy of two moles of silver chloride a t 29XoI< is almost the same as that of one mole of mercurous chloride at the same temperature. Hence the reaction entropy is effectively that of Now assuming the absence of phase changes in the solid state the standard entropy of silver is

and for mercury is

where C, is the molar heat capacity at constant pressure and L is the molar heat of fusion at T,, the melting point. For mercury the heat of fusion is 2.295 kJ mole-' at 234.3'1C (IS) so that the entropy of fusion is 9.8 J°K-1 mole-I (or 19.6 JOI . , A > , -"*., -", (161 . . Lmtar~n.W. M.. "Oxidatim Potenti&!' . (2nd . ed,. Prentice-Hall. N e w york, i 0 5 2 , ~ . w z . (17) POGLITZER, F., Z. EleLlroehcm., 19,513 (1913). G., A N D SCROIATI, I>., Rie. Sci., 37, 342 (1967). (18) Dz Rossl, M.,PECCI.

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