JOURNAL OF THE AMERICAN CHEMICAL SOCIETY

(Registered in U. S. Patent Office) (Copyright, 1952, by the American Chemical Society). VOLUME 74 ... The results of representative titrations of met...
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JOURNAL OF THE AMERICAN CHEMICAL SOCIETY (Registered in U. S. Patent Office)

(Copyright, 1952, by the American Chemical Society)

NOVEMBER 5, 1952

VOLUME74

[CONTRIBUTION NO.851 FROM

THE

NUMBER 21

DEPARTMENT OF CHEMISTRY, UNIVERSITY

O F PITTSBURGH]

Structure and Behavior of Organic Analytical Reagents. 111. Stability of Chelates of 8-Hydroxyquinoline and Analogous Reagents1 BY WILLIAMDWIGHTJOHNSTON

AND

HENRYFREISER

RECEIVED JANUARY 11, 1952 Stabilities of chelates of 8-hydroxyquinoline and several analogous reagents have been determined for a representative group of common divalent metals in order t o determine the effect of certain structural changes on chelate stability. Stability measurements made on a series of chelates of 8-hydroxyquinaldine show that significant steric hindrance, considered responsible for the non-reaction of this reagent with Al(III), is also encountered in the case of Ni(I1). A study of the stabilities of chelates of 2-(o-hydroxyphenyl)-quinolineand 1-(o-hydroxypheny1)-isoquinoline was undertaken in order t o evaluate the effect of ring size on chelate stability. The lack of reactivity of 2-(o-hydroxyphenyl)-quinolinewith divalent metals and the relatively low stability of chelates of 1-(o-hydroxypheny1)-isoquinolineindicate that for this type of reagent five-membered ring chelates are more stable than chelates having six membered rings. The divalent metal stability sequence of 8-hydroxyquinoline chelates is in agreement with reported metal orders for other chelating reagents. This order for the transition metals shows an increase in chelate stability as the transition electron shell becomes more completely filled. A similar effect has been noted in the case of La(II1) and Ce(II1) of the inner transition metals.

Since 8-hydroxyquinoline is a most useful and versatile analytical reagent, it was thought desirable t o subject it and compounds of similar structure to a study of the stability of their metallic chelates. As steric factors have been considered responsible for several cases of abnormal reagent b e h a v i ~ r ,we ~ ~ have ~ included in this study the determination of stabilities of typical metal chelates of 8-hydroxyquinaldine in order to learn whether the inactivity of this reagent toward aluminum would also be reflected in the stability of the chelates of divalent metals. The compounds, 2-(0hydroxyphenyl) -quinoline and 1- (0-hydroxyphenyl) isoquinoline, were included in an attempt to compare %-hydroxyquinoline with 6-membered ring analogs. Both of these proved surprisingly inactive chelating agents. Experimental Materials.-B. L. Lemke Co. pure 8-hydroxyquinoline n-as recrystallized several times from water and alcohol to give a compound that melted a t 74-76' which is in agree(1) Paper 11, THISJ O U R N A L , 74, 1385 (1952).

(2) L. L. Merritt a n d J. K. Walker, I n d . Eng. C h e m , Aizal. E d . , 16, 387 (1944), found t h a t 8-hydroxyquinaldine formed well-defined com-

ment with reported values.' 8-Hydroxyquinaldine was prepared by a modified Skraup synthesis.2 After several recrystallizations from alcohol and water it melted a t 7274" (reported5 74'). 2-( o-Hydroxypheny1)-quinoline and 1-(o-hydroxypheny1)-isoquinoline were made by the method of Geissman and co-workers.6 The melting points obtained after several recrystallizations from alcohol and water are in agreement with those reported by Geissman. Anal. Calcd. for C ~ S H I I S OC, : 81.42; H, 5.01. Found7 for 2-( o-hydroxypheny1)-isoquinoline: C, 80.84; H, 5.11. Found for 1-(o-hydroxyphenyl)-isoquinoline: C, 81.05; H , 4.76. The method of purification of dioxane and the procedures used in standardizing metal perchlorate solutions have been previously described.* Apparatus and Procedure.-The titration apparatus and procedure have been previously described.*

Results The results of representative titrations of metals with the various compounds are given in Table I , where ? isithe average number of bound reagent anions per metal ion and PR is the negative logarithm of the concentration of reagent anion. Included in Table I are the acid dissociation constants of the reagents studied. Table I1 summarizes the chelate formation constants calculated from the titration data. It has been previously pointed out that incorrect stability values may result if measurements are carried out in a PH range in which the metal ion will undergo appreciable hydrolysis. The measurements listed in Table I were

pounds with all of the metals t h a t reacted with 8-hydroxyquinoline, except with aluminum which gave no precipitate a t all. (4) K. Bedall a n d 0. Fischer, Ber., 14, 442 (1881). (3) H. Irving, E. J. Butler a n d M. F. Ring, J. Chem. Soc., 1489 ( 5 ) 0. Doebner and W. v. Miller, ibid., 17, 1698 (1884). (1949), extending the study of Merritt a n d Walker, found t h a t other (0) T. A . Geissman, M. J. Schlatter, I. D. Webb and J. D . Roberts, J . O i g . C h e m . , 11, 741 (1946). 2-substituted 8-hydroxyquinolines failed to react with aluminum a s did 1-hydroxyacridine a n d Q-hydroxy-1,2,3,4-tetrahydroacridine. (7) All microanalyses by Mr. G. L. Stragand With all other metals these reagents behaved similarly t o 8-hydroxy(8) H. Freiser, R. G. Charles and W. D. Johnston, THISJ O U R N A L , 74, 1383 (1952). quinoline.

5239

TABLE I A C I D I)ISSOCIATION

TABLE I1 50%

CONSTANTS IS

8-Hydroxyquinoline 8-Hydroxyquinaldine I-(o-Hydroxyphenyl j-isoquiiioline 2-(o-Hydroxypliciiyl)-quinoiine

REPRESENTATIVE 'rITRAT1ONS

l l I O X A X E AT

9KSii

PROlI

3.97 4.51 4 . 31 cn. 2

11.54 11.69 1 1 ,5'3 12.77

O F SOLUTIONS O F

PERCHLORATES ASD CHELATING A G E N T S I N \\;ATER

25'

s()';h

PURMATXON CONSTANTS I N S-Hydroxy quinoline

Cu( 11) Ni(I1) Co( 11) Zn(I1) Pb(I1) Mn(I1) Cd(I1j mdII1 La( 111)" Ce( 1111"

METAL

DIOXASE-

SOLUTIONS WITH SODIUM I~YIJROXIDE AT 25"

Cu( 11) and 8-hydroxyquinoline: 0.0002981 inole organic reagent , 0.00005271 mole metal ion, 0.0005403 mole pcrchloric acid, origiiinl volutnc 100 nil., ccniccntratioii NuOII 1~.014S111. NaOII, ml. p 1-1 li P 0.0l) 2.47 0. s.4 13.18 1 .00 2.49 ,911 13.16 2,35 4.00 1 .or, 13,117 2.57 5.00 1.11 13.05 2.68 10.00 1.33 12.89 2.78 1.48 14.00 12.74 2 , so 1,5,i 12.72 l5.UO 2 , 93 20.00 1.75 12.50

Cei 111) and 8-hyclrospquiiii~liiie: 0.0003275 iriolc organic reagent, 0.01!0046~1L5inole tnct:tl ion, li.0004880 mole pcrchloric acid, original \-olume 110 iiil., concentratioti S a O i I 0.0980 -11. PI1

S a O I I , ml.

I

0,:H

4.75 5.00 5.l i l .;.20 3.40 5.50 3 . DO

4.74

3,96 ii.11

1.17 1 . .'3 k

5.70

ii,L';

1,Xj

5,lt.j 5 2:i 5 , -1 s ,7,7X

,

5ii

.(is .7s 90

,b R

9 .4 5 0 . l:i 8,91 8 ,Tli 8.40 8 2:j ,

8.07 7 .O i

Cu(1I) m d 8-hydrosyquiIialdinc: 1I.O0033(i3 niolc orgaiiic reagent, 0.00004790 inolc inetal ion, i).OO05370 mole perchloric aciii, original rolunie 110 nil ., conccritrntioii Sa011

-

h-aOH, tnl.

,l

10. 00 12,01, 1:i.O!) 15,OO

:i. 1 1

iI.Xl

I' I