The Crystal Structure of Pb3O4 - Journal of the American Chemical

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THECRYSTAL STRUCTURE OF PbaOI

June, 1943 [CONTRIBUTION FROM THE WILLIAM

1107

ALBERTNOYEILABORATORY OF CHEMISTRY,

UNIVERSITY OF ILLINOIS]

The Crystal Structure of Pb,O, BY S. T. GROSS Crystal structure investigations have been reported for PbO2,’ PbO(r)2 and PbO(y).3 The structures for the first two compounds are well established. Few structural data have been available for the other oxides of lead. The preparation of single crystals of Pb203 and Pb304 by Clark, Schieltz and Quirke4 made possible a study of these structures, and perhaps will eventually show how the transition from one form to another is effected. Dimensions and likely space group assignments have been published for these comp0unds.j Investigations of this type are of interest both because of the variation in chemical composition (without change in X-ray diffraction effects) and also because of the commercial importance of such phenomena in the field of the leadacid accumulator. The individual crystals of PbaOi are transparent red needles about 4 mm. long, show parallel extinction, and have a perfect cleavage parallel to the axis of the needle. Powder diffraction patterns and chemical analysis confirm the identity of the material. Optical and X-ray examination prove the crystals to be tetragonal, the cleavage corresponding to the 110 plane. Laue patterns of the single crystals show distorted and split interferences (indicating considerable strain and fragmentation within the crystal), but serve to require a Laue symmetry 4/mmm. This limits the possible point groups to 4/mm, 42, 4mm or 42m. No pyroelectric effects could be detected, and such face development as could be observed in a large number of individual crystals failed to require any symmetry lower than illmmm(D4h). Rotation patterns with rotation about the c-axis were used to calculate cot equatorial interferences and goniometer patterns served to establish the value for a. (Table I).6 The best values are a0 cg

= 8.86

= 6.66

If four PbaOc units are considered included in one unit cell, the calculated density is 8.66, which agrees satisfactorily with the value of 9.1 given in the literature. (The literature density value corresponds to the powdered material and was probably contaminated with the dense yellow PbO.) TABLE I UNITCELLDIMENSIONS Sample-film distance 5 cm., rotation pattern, CuK,. Layer line separations. No. of layer line

Measurement, cm.

sin 24

CO

1 2

2.53 5.23

0.2306 .4634

6.678 6.646

Equatorial layer line measurements of hhO interferences: Measurement, cm. sin 9 a0

h k 10

1 2 3 4 5 6

1 2 3 4 5 6

0 0 0 0 0 0

2.5 5.0 7.56 10.26 13.23 16.54

0.1248 .2474 .3692 .490? .6134 .7359

* 0.1 A. (goniometer) = 8.87

8.71 8.79 8.83 8.86 8.86 8.86

a0 = 8.86 a0

4.

The low values of the inner interferences are probably the result of the dimensions of the crystal under examination, since PbaOc is quite opaque to copper radiation.

One extinction is observed, hOZ interferences are absent when h is odd. In addition the hhl reflections are extremely weak when 1 is odd (only two such interferences can be observed, and these are both extremely faint). Examination of the X-ray patterns (and subsequent examination of the intensity data) indicate that the correct space group is probably PZb2, although the structure very closely approximates special positions in the holohedral space group P4/mbc (assuming that the hhZ reflections are entirely absent when 1 is odd). For this reason the analysis was based on the assumption of the higher symmetry. The special positions for P4/mbc7 are

* 0.03 A. * 0.02 A.

(1) Bragg, “Atomic Structure of Minerals.” Cornell University Press, 1937, p. 103. JOURNAL, 46, 2457 (1924); G.R. (2) Dickinson and Friauf, THIS Levi, Nuovo Cimento, 1, 335 (1924). (3) F. Halla and F. Pawlek, 2. physik. Chem., 118, 49 (1927). (4) G . L. Clark, N C Schieltz and T . T.Quirke. THISJOURNAL, 69, 2305 (1937). ( 5 ) S . T . Gross, abad, 63, 1168 (1941). ( 6 ) DeJong and Bouman, Physica, I , 220 (1938).

8: ( e ) 002; 00.3; 0 , 0 , $ $12;

(f) 032;

+oz;

+ z;

0, 0, f

- z;

13.3; f, +,y + 2; $, 3. 1 - z 01.3; 0, f, 3 + 2; 0, f, 4 - 2; 30.3; 3, 0, 3 + 8; +, 0 , 3 - e

(7) “Internationale

Tabellen zur Bestimmung strukturen,” Gebruder Borntraeger, Berlin, 1933.

von Kristall-

S. T. GROSS

110%

Assuming P4/mbc correct, there must be four plumbic ions in a, b, c or d and eight plumbous ions in e, f, g or h. For interferences hkl where I is odd, a, b, c, d, f and g all require zero contribution to the intensity. Since each layer line observed on the rotation patterns is quite intense and therefore could not be due to oxygen ions alone, the plumbous ions must occupy h. The 440 interference is one of the more intense reflections on the patterns, but the 412 interference is not evident. This requires that the plumbic ions occupy either b or cl. Microdensitometer curves were made for the equatorial layer line of several rotation patterns, and the relative intensities of a series of hh0 interferences measured. Values obtained are listed in Table 11, calculated as relative structure factors with the usual formula I = Conit (1 4 cos* 2 8 ) F2 sin 28

where the structure factor F was considered equal to Afpb. This assumption is justified since the scattering of the oxygen is negligible, and that due to plumbous and plumbic lead will be practically identical to the atomic scattering factor for lead. Values for f p h (atomic) were taken from the table by Pauling and Sherman.* ‘Z‘ABLF,

I1

CALCULATED AND OBSERVED SCATTERING

FACTORF FOR

hh0 INTERFERENCES Assumed position for plumbous ion 2: = 0.165, y = 0.14. ii

k 1

1 10 2 2 0 3 3 0 4 4 0

5 5 0 6 6 0

sin

€3

0 124

.245 366 482 606 ,734

Intensit)

F/fph(%C)

F/fpb(calcd )

0.174 776 175 1 07 0 328 519

10 34 25 79 58

1.40 4.72 3.04 8 02 5.12 8 32

83

The inequalities evident in the table (except for the somewhat questionable 440-660) limit the 3: and y values for the plumbous ions to the region 0.16-0.18 and 0.125-0.15. I n this region the best agreement of F/fPbwas found at the position x = 0.165, y = 0.14. In the absence of absorption and extinction corrections the agreement is satisfactory. Table I11 compares visually estimated intensities with intensities calculated in the manner of (8) Linus Prilling and J Sherman, 2 Krtsl , 81, 1 (1932)

VOl. 65

CALCULATED AND

k 1

k

0 0 0 0 0 0 0 0 1 0 :{ 1 0 4 I. 0 2 4 8 8 2

5 1 0 6 10

7 8 3 4 5

1 1 2 2 2 ii 2

0 0 0 0 0 0

2 0 1 10 1 A 0 1 8 0 1 2 1 1 3 1 1 .I 1 1 5 11 tilt 7 1 1 8 1 1 :i2 1 1 2 1 5 2 1

I c a ~ .

0.51 0.34 4.0 0.62 0.11 10.3 0.15 .69 .28 .01 .00

.28 2.9 0.00 .18

7.5 0.21 .12 .49 . . 15 .08 1.22 0.16 .34 .01 .58 .:34 .13 2.2

TABLE 111 ESTIMATED INTENSITY VALUES Ivat.

0 1

3 *.I I1

5 0 ? (J

0 0 3 18 0

-

9

18 ii 1 >

0 0 8 0

3 0

h k 1

Ioa~cd.

Ieat.

7 2 82 4 3 5 3 ti 3 7 3 8 3 5 4 6 4 7 4 84 6 5 7 5 85 7 6

0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

0.37 .19 .14 .79 .00 2.5 0.06 .12 .02 .06 .a5 .19 .18 .02 .18

5 3 1 7

6 7 8 4 5 6 7 8

1 1 1 1 1 1 1 1 1 1 1 1 1 1

.00 .20 .07 .15 .31 .OO .10 .07 .66 .16 .01 .22 .26 .14

0 3 2 2-3 5 0 2 2 20 5 2 2 10

.19

0

.18

0

.oo

0 1-2 0 2

2 2 2 3 3 3 3 3

5 4 ti 4

1.5

7 4

3 I

8 4

25

7 5

8 5

2 2 2 2 2 2 2 3 5 3

2 0 2 1 I) 2 6 0 2 80 2 10 0 2 2 1 2 3 1 2 1 1 2 5 12 fi 1 2 7 1 2 8 12

6.0 6.4 0.13 0.14 2.8 0.06 I01 .11 .91 .23 1.3 0.00

2 2 0 0 5 0 0 0 0 2 0

2 2 2 2 2 2 2 2 2 6 3 2 7 32 832

9 1 2 10 1 2

.04

0

9 3 2

.61

2

5 4 2

6 4 2

1.95 0.06 .35 .31 .17 .55 .03 .92

7 8 9 6 7 8 9 7

4 4 4 5 5 5 5 6

2 2 2 2 2 2 2 2

8 ti 3

0

-,

0 2 1 -

a

.19

5 0 1 1

.12

1

3 4 5 6 7 8 9 4

9 6 8 7 11 2 2 33 4 4 5 5 tj 6 7 7

2 2 2 2 2 2 2 2 2

.99 .30 .55 .24 .ll .45 .00 .08 .06 1.5 0.10

0

20 ? 0 0 1-2 1 2 2 0 0

3

+

0 1 0 0 0 5

0

0.00 0.10 7.1 1.1 7.3 0.00 .21

0 1 3 3 20 0

.OU

0 7

1.3

1

THECRYSTAL STRUCTURE OF Pba04

June, 1943 TABLE I11 (Concluded) h k

Icslod.

2 0 3 4 6 8 2 3 4 5 6 7

0 0 0 1 1 1 1 1 1

3 3 3 3 3 3 3 3 3

813 9 3 4 5 A 7

1 2 2 2 2 2

3 3 3 3 3 3

.05 .ll .09 .48 2.6

0.04 .65 .11 .24 .01 .55 .17 .16 .07 1.4

0.00 0.17

leet.

0 0 0

2 5 0 10

1 7 0 10

3 2 20 0 3

h k 2

8 9 4 5 6

7 8 9 5 6 7 8 9 6 7 8

2 2 3 3 3 3 3 3 4 4 4 4 4 5 5 5 6

3 3 3 3 3 3 3 3 3 3 3 3 3 3

3 3 3

Ioalod.

1-t.

.08 .40

0

.10

.22 .OO .09 .08 .32 .51 .14 .01 .25 .42 .22 .15 1.0 0.21

2 2 3 1 2 2 2 10 2 1 2 8 5 1 12 3

7 The crystals are bounded by prism faces (110) so that absorption characteristics will be greatest in the h00 planes, and the most intense reflections will be observed for the hh0 interferences. The table above has been arranged in such a manner that interferences of like nature are grouped together. Various films were used for 1 = 0, 1,2, and 3.

1109

values for lead dioxide, and from the Dickinson and Friauf structure for red PbO.

1-1 I 0.t 0.1

I

0.2

0.3

I

0.4

X. Fig. 1.-Continuous line represents possible positions of the plumbous ions based upon the coiirdination theory.

The agreement of position predicted by this coordination treatment with that previously determined furnishes strong evidence that the coordination suggested is correct, and also shows by DeJong and Bouman6 and there can be no that the ionic distances are identical with those ambiguity of hkl data. The calculated intensities found in PbO (red) and PbOz. A projection of the unit cell on 001 is shown in were corrected only for polarization and the scatFig. 2a, with a scale projection on 001 of PbO(r) tering factor of the lead. The oxygen ions, with their negligible scat- beside it to show the similarity in plumbous ion tering power, cannot be located by X-ray means arrangement in the two cells. Also a projection alone. Application of the coordination theory of PbO2 has been included to show the similarity may be expected to furnish some information in of the PbOl shared octahedron chain positions. Figure 3 is a cross-section to show how the plumthis respect. The co dimension of PbO2, corresponding to the bous ions are arranged between adjacent chains distance between two opposite shared edges of an of the shared octahedra. For the proposed Pb304 oxygen octahedron about a plumbic ion, is 3.4 structure Pb++ has as its nearest neighbors three A.; co for pb304is practically equal to two times almost equidistant oxygen ions a t an average distance of 2.30 k., the next nearest oxygen ion is this value. Chains of such shared oxygen octahedra may be separated by about 3.01 from the lead ion. This arranged up the sides of the Pb304 unit cell in may be compared with PbO(r) where each Pb++ such a manner that the plumbic lead ions would is adjacent to four oxygen ions a t about 2.302 k., occupy the positions required by the preceding and is separated from four additional oxygen ions treatment. Shared oxygen ions on one chain by 4.10 k. The c glide plane assumed in working with would be in very close proximity to unshared oxygen ions from an adjacent chain. This arrange- P4/mbc as pointed out previously is only a very ment would permit plumbous ions to lie very good approximation. The space group which close to three oxygen ions. The various possible probably describes the material is P3b2, with the positions for such plumbous ions (as the plumbic plumbous ions so arranged that their separation octahedra chains are rotated) have been graphi- in the co direction will correspond very closely to cally determined in Fig. 1, the position deter- 0.25. (The physical nature of the Pb304 crystals mined for the plumbous ion on the basis of in- available made it impossible to obtain orders of tensity data is indicated by a cross. The atomic the 001 interference to establish the value acdistances involved were taken from the accepted curately .)

1110

S . T. GROSS

Vol. G5

I

\

/'

Fig. 3.-Arrangement of the plumbous ions between adjacent chains of the shared octahedra. Large circles oxygen, intermediate circles plumbous lead, small filled-in circles plumbic lead; plane of projection, 110. 4 oxygen ions in ( 8 ) with x = 0.17 y = 0.33 4 oxygen ions in (h) with x = 0.17 y = 0.33 8 oxygen ions in (i) with x = 0.40 Y = 0.10 = 0.25

Acknowledgment.-The author takes this opportunity to express his appreciation to Professor George L. Clark for his deep interest in this problem and many stimulating discussions helpful t o its solution. Summary

The atoms would be arranged as follows 2 plumbic ions in (c) at O $ t ,

2 plumbic ions in (d) a t O+q, 40% 8 plumbous ion$ in (i) with x = 0.14 v = 0 165 2 = 0.23 iapprox )

The crystal structure of minium, Pb301, has been determined. The positions of the lead ions were determined from X-ray intensity values; application of the coordination theory confirmed these positions and placed the oxygen ions. The plumbic ions are associated in chains of coordinated oxygen octahedra with opposite edges shared; practically identical even to the dimensions with those found in lead dioxide. These chains are arranged in a parallel manner, so that shared and unshared oxygen ions from adjacent chains approach closely in such a manner that three oxygen ions are coordinated with each plumbous ion. The plumbous ion arrangement is practically the same as in red PbO, so that the structure can be considered as basically built up from PbO(r) units and Pb02 units. The space group as based upon the structure is taken as PZb2. I T ~ nILLINOIS ~ ~ ~ ,

RECEIVED JANUARY 18, 1943