THE REPRODUCIBILITY OF THE CADMIUM ELECTRODE. - Journal

VOL. XXXVII.

MAY, 1915.

No. 5 .

THE JOURNAL OF THE

American Chemical Society with which has bssn incorpomted the

Ameriian Chemical Journal (FwndedbyIraRemren)

THE REPRODUCIBILITY OF THE CADMIUM ELECTRODE. BY FREDERICK H. GETMAN AND VERNBTTE .,I GIBBONS. Received February 22, 1915.

TABLEOF CONTENTS.-I. Introduction. 11. Study of the e. m. f. of spongy cadmium and stick cadmium electrodes-(a) in concentration cells of methyl alcoholic solutions of cadmium iodide; ( b ) in concentration cells of aqueous solutions of cadmium iodide. 111. Measurements of e. m. f. of stick electrodes against a standard electrode. IV. Consideration of the formation of hydriodic acid in the solution or of cadmium hydroxide on the electrodes as possible causes of the observed abnormalities. V. Consideration of allotropy as possible cause of the observed abnormalities. ( a ) Historical. ( b ) Evidence from e. m. f. measurements at different temperatures. VI. Formation of crystals on the electrodes and their analysis. VII. Study of other forms of cadmium electrodes. VIII. Evidence for allotropy of cadmium given by photomicrographic study of the various cadmium deposits.

The present work was undertaken to elucidate, if possible, some of the abnormalities observed by Getman' in the measurements of the potential of cadmium rods In alcoholic solutions of cadmium iodide. In a study of the reproducibility of the copper electrode, Getman2 (in a paper read before a recent meeting of the American Electrochemical Society a t Niagara Falls) showed that spongy copper, deposited electrolytically upon a loop of platinum wire, gave a constant and reproducible e. m. f . when measured in concentration cells of aqueous solutions of copper sulfate. 1 Am. C h . J., 46, 117 (19x1). Trans. Am. Electrochem. SOC.,26, 67 (1914).

954

FREDERICK H . GETMAN AND VERNETTE

t. GIBBONS.

The attempt was first made to study cadmium in the same way. An apparatus was devised similar to the one described by Gibbons and Getman,l whereby the two solutions were kept separated from one another except during the time of actual measurement. The measurements were all made at 2 5 ' . The temperature was maintained constant to within * O . O j ', in an electrically controlled thermostat. The purest obtainable methyl alcohol was dehydrated over pure lime for a week, then distilled into a dry receiver which was protected from the gases and moisture in the atmosphere by means of a soda-lime tube. The boiling point of this alcohol was 84.2' to 64.5' a t 752 mm. of mercury. The solutions were made up by direct weighing of pure cadmium iodide and all volumetric apparatus used was carefully calibrated. The electrodes were either of spongy cadmium deposited on loops of platinum wire with high current density, or freshly cast rods of the purest cadmium obtainable. The PoggendoriT compensation method was employed for measuring the electromotive forces of the different cells, and an enclosed type of Lippmann electrometer was the zero instrument. The e. rn.i. of the combination Cd; 0.13 l*CdIz 1 0.013 S CdIz 1 Cd-, with methyl alcohol as solvent was much higher when electrolytically deposited electrodes instead of when stick electrodes were used. The greatest value obtained for any pair of stick electrodes was 0.048 volt, after about five hours' standing in the cell, whereas the greatest value obtained for any pair of electrolytically deposited electrodes was 0.1049 volt, after twenty-four hours' standing. No constant values could be obtained, as in every case there seemed to be an increase in e. m. f. with the time, although there was no regularity in this increase. The cell stood in the thermostat for twenty minutes to acquire a uniform temperature, then the solutions were brought into contact with each other and the first measurement was made as quickly as possible. It was thought possible that the greater e. m. f . shown with the electrolytically deposited electrodes might be due to the contact of the finely divided metal with the solution. Therefore, each solution was shaken in a shaking machine for one-half hour in contact with some of the electrolytically deposited metal. The e. m. f. measurements obtained when these solutions were put in the cell were much smaller than before, but quite a deposit of cadmium hydroxide was produced during the shaking. ion of the hydroxide indicated that the action between the finely divided metal and the methyl alcoholic solution of cadmium iodide was a comRlex one. It, therefore, seemed inadvisable to consider further tbe reproducibility of an electrode of cadmium deposited electrolytically with high current density. THISJOVRNAL, 36, 1645 (1914).

TBE RF$'PRODUCIBILITY OF THE CADMIUM ELEC'PRODE.

95 5

TABLEI. Stick electrodes. Total time. Hrs. Mins. 0

0

Electrolytically deposited electrodes. -

7 -

0

DifT. in time. Hrs. Mins. 0

00

o

ij

4

35

o

30

5 5

15

o

40

45

0

30

E. M. F.

r

Volts.

0.0188 0.0287 0.0310 0,0373 0.0373 0.0369 0.0364 0,0399 0.0381 0.0431 0.0431 0.0468 0.0468 0.0452 0.0482 0.0472

Total time. Hrs. Mins. 0 0

,5 5

0

DiE. in time. Hrs. Mins.

E. M. F. Volts.

0

0

I5

0

15

0

I j

0.

15

0.0181 o 0264 0.0366 0.0477

0

I5

0.0530

0

I j

0

1.5

1 0

45 I j

0.0599 0.0623 0.0773 0.0792

0

I j

0.0792

0

I5

0.0792

0

Ij

0

20

0.0812 0.0814 0.0841 0.0857 0.0867 0.0871 0.1018~ 0.1038 0.1036 0.1046

40

1

55

0

0

0

5

5.1

6 6

IO

0

15

25

0

Ij

32

45

16

20

33 23 23 23 24 24 24 34 34

00

0

Ij

15

0

15

30

0

45

0

I5 I5

5

0

20

20

0

15

35 40

0

I5

55

0

0

.

5 15

0.

I044

0.1049 0.I049 0. I049 0.10342 0.1046.

A study of the behavior of stick cadmium electrodes in aqueous solutions of cadmium iodide was then undertaken. The following combination was used: Cd' I 0 . 2 N CdIz [ 0.02 A; CdI:, 1 CdThree pairs of electrodes were so tested and in each case the e. m. f., at first very small, increased with the time. The electrodes did not seem to tie coated with white hydroxide, but, on the contrary, the one in the more concentrated solution became gray in color and appeared coated over with a multitude of tiny crystals; and the electrode in the more dilute solution did not so appes. Evidently the cadmium was deposited upon the positive electrode in a different form from that which dissolved from the negative electrode. To test this assumption the electrodes were each in turn measured against a standard electrode similar to a calomel electrode, only iqstead of calomel and 0.1 N potassium chloride, mercurous sulfate and 0.1N After standing over night.

* After making a fresh boundary between

the solutions.

FREDERICK H. GETMAN AND VERNEETTE I,. GIBBONS.

956

cadmium sulfate were used. The standard electrode in each case proved to be the positive electrode of the combination: +Hg-Hg*SOr i 0.1N CdSO4 1 0.1N CdSO, CdTABLE11. 12.

11.

U. Diff..in time Hrs. Mins.

E. M. F.

Di5. In time Hrs. Mins.

E.M F. Volts.

I332 . I324

0

0

00

1 . I282

0

0

20

I .

1326

0

0

20

I .

I

0

20

I

c:

0

0

I5

I .

0

0

20

I

I

0

2j

I ,

I

0

30 30

1,1324 1.1325

(J

Total time.

Hrs. Mins.

Volts.

3

I

15

3 4

0

40

iI

20

4

CI

20

1296 1302 I . I304 I . 1306 I . 1310 I . 1318 I . 1320 I . 1325 1 I325 I . 1325

20

I

20

20

(I

b

11:

11,. (:

n o 0 c 20

0

0

20

I

0

20

I

(1

20

I

0

20

I8

16

25

0

1326 I , 1328 I . 1328 I . 1336 1.1336 I . 1336 I , 1322 I .

0

0

00

I . 1272

0

o

20

I .

1306

0

L

2c;

I .

1312

(I

20

I

c

20

I .

1317 1319

I I

3

I

20

I

1322

c1

20

I .

c,

20

I

I323 '324

I . 1316

C.

1112.

1111. 0

o

m

1.

0

CI

20

1.