The Lanthanum-Titanium-Oxygen System - Journal of the American

Mohsen Danaie , Demie Kepaptsoglou , Quentin M. Ramasse , Colin Ophus , Karl R. Whittle , Sebastian M. Lawson , Stella Pedrazzini , Neil P. Young , Pa...
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Dec. 5 , 1955 The Lanthanum-Titanium-Oxygen System BY MICHAELKESTIGIAN AND ROLAND WARD RECEIVED AUGUST8, 1955

The preparation of LaTi03, a compound with the perovskite structure, was described in a previous publication. A lanthanum titanium oxide having the composition Laz/3Ti03 has been reported.2 According to G. H. Jonker,a the formation of a phase approximating this composition is facilitated by the presence of a small amount of an alkaline earth ion in the stoichiometric mixture of lanthanum sesquioxide and titanium dioxide. The structure is said to be a deformed perovskite type. It occurred to us that a phase with the perovskite structure should exist with a composition range La(2/3 + %)Ti03 where x could have values from 0 to I/$. Such a phase would be analogous to the sodium tungsten bronzes. The assumption appeared more reasonable since it has been shown that a similar phase (Sr(o.5+ .)NbOa) exists in the strontiumniobium-oxygen ~ y s t e m . ~This paper describes the preparation and properties of the lanthanum titanium analog.

scribed previously.' Table I.

The results of analysis are given in

TABLE I COMPOSITION AND LATTICE CONSTANTS OF PURE PHASES OBTAINED BY INTERACTION OF Laz03, T i 2 0 3 AND TiOn" Ti(II1).

Ti(tota1).

La, %

%

%

58.95 (59.16) 56.73 (57.13)

20.58 (20.40) 15.84 (16.06)

Lattice constant

(A.j 19.75 3.926 (20.40) .25 21.01 3.918 (21.41) .I5 ... ... ... 3.904 (10.27) (22.83) (54.29) .09 51.93 6.25 23.95 3,896 (23.77) (52.40) ( 6.42) .03 49.95 2.11 25.02 3.888 (24.80) (50.36) ( 2.14) a The values given in parentheses are calculated from the quantities of oxides used in making the mixtures. * Precision of determination 2~0.002A. Lyeighted value for the wave length of CuKa used was 1.5418 A. X

0.33

The structure of the phases was determined from X-ray powder diffraction patterns using copper K a radiation with a camera of 57.3 mm. radius. All of the phases listed i n Experimental Table I have the cubic perovskite structure. The Straumanis method was used in calculating the sin'% The preparation of phases as indicated by the formula The lattice constants were obtained by extrapola3,)0a was attempted by heating stoichi- values. La~2/a+s,Ti:,"Tif~tion of a0 versus (cos28/sin 8 coSze/e) to e = 90". ometric mixtures of the reactants in evacuated silica The unit cell was found to vary from 3.887 to 3.926 (10.002 capsules. The mixtures used contained lanthanum(II1) A.) with increasing lanthanum content. The cell constants oxide, titanium(1V) oxide and (a) lanthanum metal, (b) titanium metal, (c) titanium(II1) oxide. Because of reac- are given in Table I. The density as determined pycnotion with the containers, the mixtures containing lanthanum metrically indicates one formula weight of La(ni3+.)Ti03 metal gave only impure products. Cubic perovskite phases per unit cell. The plot of the lattice constant as a function of x (Fig. 1) were obtained from the mixtures containing metallic tia Vegard's law dependence. A mixture correspondtanium, but complete reaction was not obtained even with shows to x = 0.02 gave a product having a complex X-ray prolonged heating at 1200'. Changes in lattice constant ing were observed in the products, however, when mixtures diffraction pattern which, however, contained the lines of containing different proportions of titanium metal were the cubic perovskite. Extrapolation to the lattice constant given by the latter (a0 = 3.887 j=0.002 B.)suggests that the used. The most satisfactory procedure was to prepare mixtures lower limit of composition of the cubic phase is near Lao.,oTiOs. This point appears as a full circle in Fig. 1. The half according to the equation circle represents a phase for which no analyses were per(1/3 x/2)Laz03 (3/2x)TizOa (1 - 3x)TiOz = formed. The white product obtained with the mixtures L a m +=)Ti03 corresponding to .2: = 0 gave a very complex diffraction pattern which has not, as yet, been interpreted. The lanthanum oxide was ignited a t llOOo just before weighing and mixing with the titanium oxides. The titanium(II1) 7 3.930 I r oxide was prepared by the method of Friedel and Guerin.6 The mixture was thoroughly ground in an agate mortar and pressed into pellet form. The sample was heated in an 3.920 evacuated, sealed, silica capsule at 1150' for 24 hours and finally a t 1250' for 48 hours, with regrinding every 24 hours. For samples over 1 g., the second heating process had to be 3.910 extended for five days to ensure complete reaction. Phases which appeared homogeneous under microscopic and X-ray examination were obtained for values of x from 3.900 0.03 to 0.33. The phases with lanthanum content above x = 0.09 are black, but, with lower lanthanum content the phases gradually lighten in color. Qualitative tests indicate that they are fairly good conductors of electricity. 3.890 The products are impervious to attack by cold hydrochloric acid, nitric acid, perchloric acid, hot, dilute nitric acid and boi!ing perchloric acid. They are slowly attacked by aqua 3.880 regia. For analysis, the samples were brought into solution by fusing with potassium bisulfate containing a few drops of 3.870 sulfuric acid and taking up the melt in 1 M sulfuric acid 0 0.05 0.10 0.15 0.20 0.25 0.30 solution. The titanium was precipitated with cupferron, and the lanthanum was precipitated as the oxalate a t PH 4. X. The percentage of titanium(II1) was determined as deFig. 1.-The variation of lattice constant with composition in (1) M. Kestigian a n d R . W a r d , THIS JOURNAL, 76, 6027 (1954). the cubic phases of composition La(2/3 .+ .)TiOa.

+

+

+

+

(2) English P a t e n t 574,577 (1946) (3) Private communication from G. H. Jonker, N. V. Philips, Gloielampenfabriken, Eindhoven, Holland. (4) D. Ridgley a n d R . W a r d , THISJ O U R N A L7 ,7 , 6132 (1955). ( 6 ) C. Friedel and J . Guerin, A i z i z . chim., 8 , 38 (1876).

It is interesting t o note that the presence of a very small amount of titanium(II1) is capable of stabilizing the cubic perovskite structure leading to a relatively wide range of homogeneity. The properties of the phases throughout this

NOTES

6200

range are reminiscent of the tungsten bronzes except for the more restricted range of color.

Acknowledgment.-The authors wish to acknowledge the generous support for this work given by the Office of Naval Research. Reproduction in whole or in part is permitted for any purpose of the United States Government. DEPARTMEXT OF CHEMISTRY UNIVERSITYOF CONSECTICUT STORRS, CONNECTICUT

The Osmotic and Activity Coefficients of Aqueous Solutions of Thorium Chloride at 25" BY R. A. ROBINSON RECEIVED AUGUST1, 1955

Isopiestic vapor pressure measurements have been made on solutions of thorium chloride at 25'. The results are not claimed to be of high accuracy but they are of some interest in that they add to our very meager knowledge of 1: 4 and 4 : 1 electrolytes, thorium nitrate and potassium ferrocyanide being the only two electrolytes already studied. Thorium chloride was prepared by crystallization of a commercial sample which analysis showed to be considerably basic and to which therefore was added slightly more than the requisite amount of hydrochloric acid to give the correct T h :C1 ratio. After three recrystallizations the solution gave the correct T h : C1 ratio on analysis. Table I gives the results of the isopiestic measurements, using sodium chloride as reference salt. Table I1 gives the calculated osmotic and activity coefficients, the latter being expressed relative to the arbitrary value of 0.330 a t 0.05 M . TABLE I MOLALITIES O F ISOPIESTIC SOLUTIONS O F THORIUM C H L O -

NaCl

ThClr

NaCl

0 05252 1286 1584 ,2137 ,3009 3699 ,3023 ,6152 ,6712

0.1029

0.7864 ,8805 ,9983 1.112 1.223 1.368 5.372 5.818 6.150

2,356 2.755 3.249 3.752 4.199 4.803 1.495 I.590 1.663

,2584 ,3241 ,4531 ,6833

,8813 1.288 1.682 1 852 TaBLE

11

OSMOTIC A P D A C T I V I T Y COEFFICIESTS OF RIDE AT 25'

THORICM CHLO-

m

c

Y

m

c

Y

0.05 .I

7

. I IC,

3 .4

,840 . 9Oti

.5

,974 1.048

(0.330) ,292 .257 ,253 ,261 ,275 ,297

0.7

.l

0.731 ,736

1.129 1.214 1.302 1.390 1.536 1.665 1.847

0.327 ,364 ,409 ,463 ,583 ,729 ,966

,

. ti

there is a possibility of this being promoted by loss of hydrogen chloride, formed by hydrolysis, during the evacuation of the desiccator. Thus, in an attempt to extend the range of measurement beyond 1.6 M ThC4, using sulfuric acid as reference electrolyte, I failed to get any consistent results a t these high concentrations. For this reason, I do not claim high accuracy for the data in Table 11. I think, however, that they are accurate enough to show that thorium chloride has higher osmotic coefficients than thorium nitrate, as has been found with the chlorides and nitrates of lower valency metals. UNIVERSITYOF MALAYA SINGAPORE

Solid Solutions Treatment of Calorimetric Purity Data BY

.8 .9 1.0

1.2 1.4 1.6

I suspect that, as in the case of uranyl nitrate,' the osmotic coefficient is very sensitive to any departure from the exact Th:CI ratio. Moreover, (1) R. A. Rohirison a n d C I;. L i m , J . Cherii Soc., 1540 (1931).

s. \;.

R. MASTRASGELO AND R. \Ir. DORNTE RECEIVED JCLY 12, 1953

The application of calorimetry to the absolute determination of purity, in the absence of solid solution formation, is well e s t a b 1 i ~ h e d . l ~Al~ though methods are available4s5for detecting solid solutions, no quantitative treatment for these data exists. IVe have derived a solid solutions treatment for calorimetric melting point data which provides a method for calculating To,the melting point of pure major component, and Xz,the total mole fraction of minor component. This treatment is based on analysis of the curvature of the plot of the equilibrium temperature, T,, "J. l / y , the reciprocal of the fraction melted. The occurrence of solid solutions, although rare a t low temperatures, is relatively great a t high temperatures. The Lewis and RandallGdifferential equation for solid solutions

SODIUM CHLORIDE

RIDE AND ThClr

--

VOl. 77

dT = dX2

011

(L,

- 1)

I