Studies on Ion Exchange Resins. IX. Capacity and Specific Volumes of

Harry P. Gregor, Jack Belle, and R. A. Marcus. J. Am. Chem. Soc. , 1954, 76 (7), pp 1984– ... Robinson, Stokes. 1954 76 (7), pp 1991–1994. Abstrac...
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Dowex 50. Under these conditions there was essentially no separation of yttrium and europium. The single peak in the citrate elution curve was shown t o contain both yttrium a n d europium by compariion of a n absorption curve with th,it obtained on the original tracer mixture. \5’ith slightly different conditions and longer columns, europium arid yttrium have been separated using c i t r : ~ t e . ~These workers found yttrium between dysprosium and holmium in the order expected from crystal ionic radii. Others have reported8 t h a t , under conditions slightlv different from those of Ketelle and Boyd and also different from those employed here, europium, gadolinium and yttrium are eluted a t very nearly the same rate.

Discussion The fact t h a t successful separations by ion ex( 7 ) B. H. Ketelle and G . E . Boyd, THISJ O I I R K A I . , 69, 2800 119471. (8) Geoffrey X’ilkinson and H a r r y G. Hicks, P h y s . Rea., 75, 1370 (194Y).

change using mixed solvents can be achieved suggests t h a t many new complexing agents which are insoluble in water can be used if a suitable mixed solvent can be found which is sufficiently polar in nature to permit ion exchange to occur reversibly. The fact t h a t the reaction by which the metal chelate is formed is not rapid does not rule out the use of the chelating agent, since HTTA is known to be slow in forming these complexes. The method may be useful for more rapid and efficient separation of those rare earth elements which are commonly separated by citrate elution. I t may also be applicable to the separation of certain transuranium elements. LOS

ANGELES.CALIFOR.UI.4

[COSTRIBUTIUS FROM ‘THE UEPARTMENT O F CHEMISTRY O F THE POLYTECHSIC INSTITUTE Ob’ ~ R O O K L Y S]

Studies on Ion Exchange Resins. IX. Capacity and Specific Volumes of Quaternary Base Anion Exchange Resins1 BY HARRY P.GREGOR, JACK BELLE’ ASD R. A. GR ARC US RECEIVED SOVEMBER 27, 1953 The exchange capacities, wet weights and volumes of a quaternary ammonium anion exchange resin in a number of univalent anionic states including the halide, strong mineral acid anion, hydroxide, chloro-substituted acetate and benzene and iiaphthalene sulfonate states, were measured. The exchange capacity was the same for all anions, and showed the absence of appreciable adsorption effects. The swelled volume of the resin phase was correlated with the partial molal volumes of the exchange anions. Swelling appears to be determined, t o a considerable extent, b y ion-pair formation.

This paper describes the exchange capacity of a base anion exchange resin for various univalent inorganic and organic anions. The specific wet weight and the specific volume of the resin phase when these ions occupy the exchange positions are also given. -4 subsequent paper in this series will present selectivity coefficient data on these same systems.

Experimental Methods A series of Dowex 1 and Dowex 2 resins (Dow Cheniical

Co., Midland, Michigan) were used for these stutiies.3 These resins are prepared from a polystyrene-divinylbenzene (DVB) copolymer having varying degrees of crosslinking. The designation DT‘B 8 refers t o the 8% crosslinked material, which is the standard commercial product. DVB resins 1, 2 , 4, 6 and 16 were also used. The exchange groups in the Dowex 1 resins are largely of the benzyltrimethylammonium type. I n Dowex 2 resins they are of the benzylethanol-dimethylammonium type. Similar resins have been prepared b y chloromethylation of the styrenedivinylbenzene copolymer, followed by treatment with t h e corresponding amine.4J Since the chloromethylation step itself introduces a small amount of cross-linking, the actual degree of cross-linking is higher than t h a t corresponding t o the DT‘B content. In this paper most of the data are for the Doirex 2 type of resin, which is referred to simply by its percentage crosslinking. Data for the Dowex 1 type of resin are so specified. Both types of resins were conditioned by treatment with 1 (1) T h e authors wish t o t h a n k t h e Signal Corps, U. S. Army, and t h e ORice of Naval Research for t h e support given this work. (2) T a k e n in p a r t from t h e dissertation of J . Belle, submitted in partial fulfillment of t h e requirements for t h e degree of Doctor of Philosophy in Chemistry, Polytechnic I n s t i t u t e of Brooklyn, October, lY51. (3) X . R I . X‘heatiin a n d IT’. C . Hniirnann, l i i , l E11.t. Churn., 4 3 , 1088 ( I !I3 I ( 4 ) ( 5 ) S. L. ‘l’liumas, paper given at the 11’0tli l!cetiiig of t h e Attieiicaii Cliernical Society, New E’ork, Septenilier, 1‘331,

m (molal) sodium hydroxide and 1 vz hydrochloric acid S O ~ U tions alternately, using a twofold excess in terms of cxchange capacity each time, at a flow rate of approximately 0.1 ml./min./ml. bed of reqin. Three cycles of this treatment were followed by passing a 10-fold excess of 1 m sodium chloride through the bed a t the same, slow flow rate. The resins were then rinsed with carbon dioxide free distilled water until the conductance of the effluent dropped t o less than 2 10-h mho, They were then air-dried to freeflowing state and dry screened t o - 18 30 meqh and -:3(1 60 mesh sizes for the DVB 8 and t o -60 100 mesh for the DVB 1. 2. 4. G and 16 resins. This chloride state of thcb resins was taken as the “standard” state upon which all subsequent calculations of specific capwit!, etc., \rere based. The resins were also placed in the hydroside state b y treatment with base after the conditioning procedure. Rinsing with carbon dioxide free water was continued to an effluent conductance of 10-6 mho. The moisture content of the chloride resin was determined by drying in a desiccator over phosphorus pentoxide; constant weight was attained in about 3 weeks. IVith oven drying a t 100’ the same, constant weight ~ r a attained s within 24 hours. The hydroxide form was dried only in the dcsiccator, a s it decomposed partially a t the elevated temperature. Quaternary base anion exchange resins which contain the ethanolic group are not stable in the hydroxide form, but decompose quite slowly t o an amine.3 Gilwood and Utermohlen6 measured the stability of various resins the hydroxide state a t both room temperature and 100 , and observed that the ethanolic substituted quaternary ammonium resins are unstable relative t o the purely aliphatic suhstituted ones. All types of resins are considerably inore stable as salts of mineral acids than in the hydroxide statc. However, even the decomposition of the ethanolic type resins is slow a t room temperature, requiring several weeks t o become measurable. I n this investigation, all resins were stored in the salt (chloride) state, and were converted to the base state for use in that form. ____

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