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N-thiocarbamoyl-N′-carbamoyl hydrazine derivatives and their metal complexes
J. inorg,nucl.Chem., 1966,Vol.28, pp. 1633to 1644. PergamonPre~tLtd. Printedin NorthernIreland
N-THIOCARBAMOYL-N'-CARBAMOYL HYDRAZINE DERIVATIVES AND THEIR METAL COMPLEXES A. DUTTA AHMED* and P. K. MANDAL Inorganic Chemistry Division, Indian Association for the Cultivation of Science, Calcutta-32, India (Received 23 November 1965)
~ - - A study of N-thioearbamoyl-N'-carbamoylhydrazine derivatives as complexing ligands and their Ni, Cu, Zn and Cd complexes is described. The metals form 1 : 1 chelates with the ligands. One compound with formula Cu(I) (C~J-Is.NH.CS.NH.NH.C0.NH~)sC1 is also described. Ultraviolet and i.r. spectra of the ligands and the metal complexes and the magnetic properties of the latter are discussed. Structures for the metal complexes are proposed.
JENSEN and MIQUEL¢1) have described nickel complexes of N-thiobenzoyl-N'-(carbamoyl, thiocarbamoyl) hydrazine. Metal chelates of N-N'-di(allylthioearbamoyl) hydrazine have also been described from this laboratory t2.a). Recently ABLOV and G~R~LEU t~ have reported metal salts and complexes of a number of thiosemicarbazides and thiosemicarbazones. Now, it might be of interest to make a similar study with N.thiocarbamoyl N'.carbamoyl hydrazine derivatives. These compounds enolize and function as dibasic and possibly tetradentate ligands just as N-N'-di(thiocarbamoyl) hydrazine derivatives do. Metal chelates with these ligands have not been previously described. The present communication describes three ligands and their nickel, copper, zinc and cadmium chelates, of the same general formulae: (i) Ligand I: N-phenylthiocarbamoyl-N'-carbamoyl hydrazine CoHsNH-CS.NHNH.CO.NH z (ii) Ligand II: N-thiocarbamoyl-N'-phenylcarbamoyl hydrazine HzN.CS.NHNH-CO.NHCoH 5 (iii) Ligand III: N-allylthiocarbamoyl-N'-carbamoyl hydrazine CaHsNH.CS.NHNH.CO.NH 2 EXPERIMENTAL Preparation of Ligand I
The ligand was prepared from potassium cyanate, 4-phenylthiosemicarbazide and hydrochloric acid or from semicarbazide hydrochloride (0.1 mole), sodium carbonate and phenyl-isothiocyanat¢ as described by AgNOT et aL ~s~ The ligand was purified by repeated recrystallization from aqueous ethanol and analysed (m.p. 196°C). * To whom correspondence concerning this paper should be addressed. txJ K. A. JENSENand J. F. MIQUEL,Acta chem. scand. 6, 189 (1952). n~ N. K. DuTr and K. P. SEN SARMA, Analytica. chim. Acta 15, 21 (1956). cs~A. D u r r a ~ and S. N. DHAR, Sci. & Cult. 28, 540 (1962). ~'~ A. V. AnLOVand N. V. G~V.LEU, Zh. neorg. Khim. 9, 85 (1964) (eng. edn. p. 46). ~5~F. ARNO% E. MILI)~ and F. TSC~NSCHL~, Ber. dr. chem. Ges. 5513, 341 (1922). 1633
21"83 (22"01)
24.39 (23"60)
23"33 (23"39)
23 "08 (23-39)
25"28 (25.05)
Ni-Ligand IIb
Ni-Ligand III b
Cu-Ligand I b
Cu-Ligand H b
Cu-Ligand
(20"62)'
22.24 (22-09)
(20.62)
(11-79)
12.91 (12.62)
20"94
(20.62)
20-53
21 "75 (22-52)
21.13 (21"00)
11-97
11"68 (11-79)
12"83 (12-87)
(I 1"99)
11-10
19"72 (19-67)
Ni-Ligand I b
11.85 (11.24)
32.10 (32-18)
Ligand HI
20.76
26-54 (26-67)
Nitrogen
Ligand II
Sulphur 26"14 (26.67)
Metal
Ligand I
Compound
33-78 (34.48)
46.11 (45.72)
45"80 (45.72)
7"15 (7"10)
6"99 (7.24)
6"69 (6"67)
HsO e
5.79 (5.75)
4.93 (4.76)
4"89 (4-76)
Hydrogen
Others Formula
CUO1)(CsHsON,S)" 1 H,O
Cu(H)(CsHsON,S)
Cu(H)(CsHsON,S)
Ni(II)(CsHsON,S)" 1 HsO
Ni(II)(CsHaON,S)
Ni(II)(CsHsON4S)'I HsO
CsHioON~S
CsHloON,S
CsHxoOHN,S
LIGANDS A N D T H E I R COMPLEXES
Carbon
TABLE 1.--ANALYmSSo v
204°(d)
200°(d)
188°(d)
193°
218 °
196°
m.p./d.p. (uncorrected)
r~
ta,
.>
22.26 (22.44)
27.04 (27"54)
34-17 (35.09)
35.43 (35.09)
39"41 (39"53)
14"08 (14-21)
Zn-Ligand II °
Zn-Ligand IIIe
Cd-Ligand I a
Cd-Ligand II °
Cd-Ligand I l l e
Cu(I)-Ligand III a
15"02 (14.32)
11"65 (11-26)
10.03 (9-99)
9.94 (9.99)
13.32 (13"48)
10.92 (10.98)
11.10 (10.98)
18"23 (18"52)
16.98 (17.48)
17.39 (17.48)
22"81 (23.59)
19.30 (19.22)
19-12 (19"22) 6"15
8"24 (7"94)
Cl
6"21 (6.18)
(6"18)
ts~ Figures in parentheses are the required percentages tb~ Prepared by method A and/or B '~ Prepared by method A; preparation by method B needs extensive purification ca~ Prepared by method C ,e~ from dehydration cf~could not be determined.
22"71 (22-44)
Zn-Ligand 1 °
173°(d)
205-210°(d)
225°(d)
Cd(CaHaON4S)
Cd(CaHaON4S)
Cd(C6HsONIS)
196°(d)
200°(d)
Zn(CsHaON,S)
Cu(I)(CsHxoON,S),CI
220°(d)
200°(d)
Zn(CaHaON4S)" 1 HaO
Zn(CsHsON4S)q HtO
VI
t~
0
l-t
ea~
g
0"
1636
A. DUTTAAHMEDand P. K. MANDAL
Preparation of Ligand II The ligand was prepared from thiosemicarbazide and phenyl-isocyanate as described by FmSUND and SCHA~,U3F.Z~ te~ and was purified by repeated recrystallization from aqueous ethanol, and analysed (m.p. 218°(2).
Preparation of Ligand III The compound was prepared from semicarbazide hydrochloride and allyl-isothiocyanate as described by Busch and LoTz c7~ and was purified by repeated recrystallization from water and finally from ethanol and analysed (m.p. 193°C0.
Other chemicals Chemicals other than the ligands were of reagent grade. Ethanol and other solvents used for spectroscopic measurements were spectroscopically pure. cs~
Preparation of solutions of the ligands Thrice recrystallized ligands were used. For water solutions, warming to 60-70°C was allowed. Aqueous solutions of the ligands did not keep for more than 36 hr, decomposition being noted spectroscopically.
Preparation of metal chelates Three methods were used. (a) On addition of a soluble ammine complex of the metal (0.002 to 0.005 mole) to an aqueous solution or aqueous-ethanol solution of the ligand (0.008 to 0.020 mole), immediate precipitation occurred. The precipitate was heated on a water-bath for about half an hour, filtered, washed with dilute ammonia and finally with aqueous-ethanol, dried in a desiccator and analysed. The yield was quantitative. Co) On mixing an aqueous solution of the metal salt with an aqueous or aqueous--ethanol solution of the ligand in the same ligand/metal ratio as stated above, warming on waterbath, and on gradually raising the pH with a dilute solution of sodium bicarbonate, precipitation occurred. The precipitate was heated on a water bath for about half an hour, filtered, washed with warm water followed by aqueous-ethanol, dried in a desiccator and analysed. Yield was quantitative at proper pH values. (c) On addition of a hot ethanolic solution of metal chloride to a hot ethanolic solution of the ligand, pre~pitation occurred. The precipitate was washed with warm ethanol, desolvated and analysed.
Apparatus and measurements Absorptions in the u.v. and visible ranges were measured with a Hilger Uvispek, against the same solution minus the ligand as reference solution. Infra-red spectra were recorded with Perkin-Elmer models, 221 and 137B. Magnetic susceptibilities were measured with a Guoy Balance. The analyses of the compounds are shown in Table 1, along with their melting/decomposition points. The Amaxof u.v. spectra of ligands and complexes are summarized in Tables 2 and 4. Infrared bands are summarized in Table 3. The results of magnetic susceptibility measurements axe shown in Table 5. TAnLE 2.--Am~x (LOG0
96~o Ethanol 75~o Ethanol 50~o Ethanol 25yo Ethanol Water
VALUES OF LIGANDS IN AQUEOUS-ETHANOL soLUTION, IN
m/~
Ligand I
Ligand II
Ligand III
215(4.18), 235(4.12), 270(3.99) 214(4.22), 235 sh, 267 sh 212(4-27), 234 sh, 265sh
210(3.86), 245(4.39) 211(3-91), 245(4.41) 208(4.04), 243(4.42) 205(4.23), 242(4.40) 202(4-40), 242(4-38)
215(3.84), 245(4.13) 213(3.87), 244(4.12) 212(3.94), 243(4.12) 209(4.03), 241(4.13) a 240(4.14)
203(4.37), 245 sh
The Am,x value is at or below 200 m/~. I~UND and ScriAm~, Ber. dr. chem. Ges. 29, 2510 (1896). c7~M. BuscI~ and D. LOTZ, 3". Pr. 90, 270 (1914). c,~ A. WEISSaEROER,Editor, Techniqueof Organic Chemistry, Vol. VII. Interscience, New York (1955). ce~ M .
N-thiocarbamoyl-N'-carbamoyl hydrazine derivatives and their metal complexes RESULTS
AND
1637
DISCUSSION
The identification and characterization of the compounds have mainly b~en attempted from spectroscopic data. It is obvious though that due to the composite nature of the vibrations, interpretation and band assignment of the ligands and their metal derivatives is difficult.
The ligands The N-thiocarbamoyl-N'-carbamoyl hydrazine derivatives should have the following structure R--NH----C---NH--NH--C---NH--R'
II
II
S
O
It is possible that the ligands will exist in "keto" as well as "enol" forms, along with hydrogen-bonded and a number ofzwitter-ionic species. The effects are not necessarily of equal magnitude in both the "thiourea" and "urea" parts of the molecules. There is no band for OH or SH in the i.r. spectra of the ligands but hydrogen bonding and zwitterionic species are indicated, the complex nature and splitting of bands being observed in certain regions involving CS, CO and CN vibrations. Aqueous or alcohol solutions of the ligands show the existence of enol forms. Absorptions of a series of ligand-in-aqueous-ethanol solutions of differing water and ethanol proportions (Table 2 and a typical set of spectra in Fig. 1) as well as of isopropanol solution suggest tautomeric equilibria and zwitterionic species. Of the various resonating structures, the skeleton N - - ~ N - - N - - C - - N is most significant the delocalization of ~r-electrons lower the energy. The absorption maxima and extinction at 210 mp ascribed to this skeleton compares well with the data for CeHs--CH--N--N---CH--CeHs. ~°~ The usual changes in NCS band at 245 m/~ at higher pH's and in the absorption characteristics at 300 m/~ are also observed. The ligands are found to be dibasic. It may thus be concluded that the ligands form chelates through the following enolized form, R--NH~N--N~C--NH--R'
I
SH
L
OH
The observation agrees with previous finding¢1°-1~) in analogous cases. 1 :1
Metal chelates That the metal atoms are directly linked with the oxygen atoms can be proved by the absence of C----O and - - O H bands in the i.r. spectra. As far ~ts C-~-S is concerned there is some difference of opinion over the characteristic absorption region e.g. 1080 cm-1 ~ 1120 cm-1, ~13),~ 1400 cm- m i , m and ~ 730 cm-1. oz~ The latter two regions ~*~H. C. BARASY, E. A. BSAUDe and M. Pt~rr~, J. Chem. Soc. 1898 (1949). cxo~j. SA}r~srgoM, Acta chem. scand. 14, 1037 (1960). m} K. A. JmqseN and C. P~SRSeN, Acta chem. scand. 15, 1124 (1961). cm B. A. G ~ o P , t.s, R. L. SOMOIUAXand C. H. BAYLEY, Can. J. Chem. 39, 973 (1961). ix,} A. YAMAOUCHI,R. B. PEIqLAND, S. M x z U S ~ , T. J. LANE,C. CURRAN arid J. V. QUAGI.,IANO, J. Am. chem. Soc. 80, 527 (1958). cm E. Lnmmt, C. N. R. Rxo, C. N. PmL~, J. R~,~.AC[-IANDRANand R. D. HITeS, Can. J. Chem. 36, 801 (1958). cxs~j. E. STEWART,J. chem. Phys. 26, 248 (1957).
1565m
1310m
1310 s
1330s
1397sh
1315 s
1335 s
1420sh
1315 s
1335 s
1399sh
1310m
1345sh
1490m
1409ms
1350sh
1495 s
1495 s
1491 sh
1495 s
1525sh
1515 sb
1519m
1520s
1553 m
1540sh
1539ms 1515 s
1590 s 1550sh
1600s
1597sh
1575sh
1612m
1606 s
1615ms
3150m
3300sh
3350s
3500 m
Ligand
1612ms
2668 wb
2743m
3335 s
Ni
1655m
3280mb
3310mb
3557 mb
3500 mb
3375mb
Zn
Cu
Ligand I
1657 s
3185s
3244 s
3373m
Ligand
1325 sb
1490 s
1530sb
1550sb
1580s
1600 s
3220m
3350m
3500 m
Cu
L i g a n d II
1320sb
1510 s
1525m
1585 vs
1608 vs
2650mb
2720
3200s
3315 s
3435 m
3600 m
Zn
1325m
1390m
1505 w
1540s
1558sh
1592m
1608m
1515 m
1525m
1550m
1565m
1500sh
1535 s
1550sh?
1325 w
1522m
1555s
1580 s
1635m
1700s
2725 w
3140sb
3230 s
3300s
3346m
3368 m
3418m
3515
Cu0igandlII)2C1
1640m
1600 s
2730 m
3330 mb
3465 mb
Zn
Ligand HI
1672s 1600m
2720m
2770m
3300mb
3450 mb
Cu
1662 s
1692m
3160s
3315 s
3435 m
Ligand
TABLE 3.--SUMMARY OF i.r. BANDS OF LIGANDS AND THEIR CHELATES IN NUJOL IN c m -x
.>
890 w
880wb
835 w b
880m
820 wb
710m
680m
696sh
687ms
733m
740 m
705m
755m
690 m
715-730 m b
696ms
745 w
690s
720 s
750 s
710m 680 w
690 s
748m
720 m
750 s
710m 680m
685m
765m
710m
760sh
686 m
703 m
760 w
780 w
745m
760m
915 m
930 m
768 w
820m
915m
955 m
767m
835wb
885 w
910 w
950m
960m
982 m
lO00m
1040 w
1078 m
l130m
1160m
1230m
1292m
800 w
830m
910m
980m
980m
1030m
1060m
1145 s
1230m
1300s
785sh
835m
835 w
895 w 860m
895m
965m
960 m
965m 945m
990m
1035m
1080sh
1025 m ?
1070m
1027m
862 v w
910 v w
?
1026m
1070m
1145 m
1220m
1295m
795 v w
750m
930 v w
930 v w
930 v w
? 1041 m
l120m
l150m
1225m
1290m
795 w
926 w
962 w
960m
965m
985 w
950m
1020m
1005 w
990sh
1005 w
1070m
1030m
1030m
1025 w
1076m
070m
I074m
1094sh
ll50sh
l150m
l130m
ll30ms
1122 m
ll50wb
ll50sh
l145mb
1165sh
1135m
1222 m 1160 w
1220m
1220m
1215m
1240s l170m
1235m l170m
1260 w
1255sh?
1256sh?
1250sh?
1300 b
1215m
1300 s b
1256m
1296 m
1290sh?
1290sh?
1290m
ou
g
8
Z
1640
A. DUTTAAHM~ andP. K. MANDAL
LIGAND I
fir ~|1
I.o
II
rl
IN
,.,.~.~.o~ "'/" " ,o.~o ,,
|tl
I~I
o =.
O5
2OO
250 3OO WAVELENGTH (m/.c)--~
350
F]Q. 1.--Absorptions of N-allylthiocarbamoyl-N'-carbamoylhydrazine; 9.060 x 10-' M. BO
60~. ,, .o 0..,,,°,,..°.~
5G
\"
w U Z 4[ II-
4C
Z
3C
p--
20
I0
0 3600
I 3500
I 3400
I 3300
WAVELENGTH 1:;IO. 2a
I 3200
I 3lOG
3000 cn'T'
N-thiocarbamoyl-N-carbamoylhydrazine derivatives and their metal complexes
1641
{]
('l I ,
I/V/ •
v
....
r..-;
.
: ",./
/
/',i -i:/ 30 " U
:
: I: ¢6
\/
,
V
~;.
,o
1700
I 1600
I 1500
I 1400
I 1300
I 1200
I I100
I I000
I 900
I 800
I 700
6o(
cm
WAVELENGTH
Fxo. 2b.--I.R. spectra of Ligand HI ( ) and its Cu chelate (- . . . . . ), its Zn chelate ( . . . . . . . . . of Cu (Ligand HI)= C1 ( . . . . . . . -).
TABL~4.--2m=x V~LU~SOF C'H~ATESIN ETHANOL, IN m ~ Ligand I Ni Cu Zn Cd Cus b
215 sh, 238, 260, 282 sh 219 245 sh 220, 238, 250 sh, 265, 282 sh 220, 240, 255 sh, 282 sh
Ligand ]I
Ligand HI
215, 242, 270 sh 216, 220 sh, 280 sh 220, 245 220, 245, 250 sh 207, 239 205(4.38), 245(4.25), 280(4.12) 207(4.30), 245(4.30), 278 sh 206(4.08), 240(4.09) 214 sh, 255 215, 255 210 sh, 250 220, 245
= Cu" (Ligand I]T)aCI in water. b )'max (log e) of Ligand I at pH 11.02 (pH > pK,), of Ligand II at pH 10-87 (pH > pK0 and of Ligand lII at pH 10.50 (pH ~ pK0.
) and
1642
A. DUTI'A AHMED and P. K. M A ~ A ~
"-- 0
0
Z 0
8
0
u')
iln
0
~
X
!
Z 0 ".~
L 8N
0
~
~2
u.
"0"0 O
"O 0
•
u. o
13
q
,~
z
u
O
6
I O t.f3
I t.n f~
O
0 "(0"O
8
N-thiocarbamoyl-N'-carbamoyl hydrazine derivatives and their metal complexes
1643
are preferred, tm although some CN interactions are always likely to be present. However, bands present in the ligands in this region are absent in the chelates, and their absence is taken as evidence of metal-sulphur linkages. It is believed that certain new bands o f the chelates in the 800--1000 cm -~ region are overtones of metaloxygen/sulphur/nitrogen fundamentals. Similar to the azine group) xT~all the chelates show a band at ~-d600 cm -x. TABLE 5 . - - M A O N E T I C SUSCEPTIBILITIES OF COMPLEXES
Compounds Ni(CsHaON,S)'I HBO(I)~ Ni(CaH,ON,S) (II) Ni(CsHaON4S)'I HIO(IU) Cu(CaHsON4S) (I) Cu(CsHsON4S) (II) Cu(CsHBON,S)'I HtOOII) Cu(CsHloON,S)sCI(I~
XM(corrected) 2409.41 × 1211"34 × 2445.50 × 1142.44 × 1277"14 × 938.80 ×
10-6 10-6 10-e 10-6 10-6 10-6
(Diamagnetic correction) 100-61 × 10-6 90"14 × 10-e 76-70 × 10-6 90"14 × 10-e 90"14 × 10-6 76-70 × 10-6 Diamagnetic
/~B 2.39 1"70 2'41 1"65 1"75 1"50
a the numbers in the parenthesis denote the Ligand of which the compound is. The chelates are insoluble in organic solvents and in water, but the freshly prepared chelates are slightly soluble in organic solvents. Solutions for the measurements o f the u.v. absorption were prepared by refluxing freshly prepared chelates with ethanol. The insolubility is best explained by a polymeric structure. In such cases, the NH/NH~ of the (thio)carbamoyl group and either of the two nitrogen atoms of the azine group are capable of co-ordinating. The probability of co-ordination by both the nitrogen atoms of the azine group to the same metal atom is unlikely. Co-ordination of these two nitrogen atoms to two different metal atoms are possible in which case the ---OH and - - S H groups should be " t r a m " with respect to the N ~ N - - N - - - C - - N skeleton and each of them combine with two different metal atoms; if the two groups are "e/s" and attached to the same metal atom, co-ordination by one of the nitrogen atoms of the azine group to that metal atom will involve a strained four membered ring.* The other alternative is co-ordination by the nitrogen atoms of (thio)carbamoyl groups. All the bands in the region of 3 ~ in the chelates are broad and diffuse suggesting hydrogen bonding. Except the amide I bands observed near 1650 cm -1 (Ligand III has additional bands, including one at 1692 cm -1 of relatively weaker intensity it is difficult to identify the other bands. Complex formation and conjugation modify their locations. This could be the reason for the nature and position of bands in the chelates, specially those corresponding to ligand-bands at 1539 cm -1, 1553 cm -x and 1558 cm -x (probable Amide II), at 1519 cm -1, 1525 cm -1 and 1540 cm -1 (probable "NCS"), at 1490 cm - t (probable b(NH) and v(CN)), at 1250 ~ 1300 cm -1 (probable Amide III), at 1215 cm -x ~ 1 2 2 5 cm -x (probable ~(CN), b(NH)) and at ~ 7 5 0 cm -1 (probable v(CS) and v(CN)). The bands at 820 , ~ 845 cm -x for the chelates may also correspond to N---C--O and C - - S vibrations. However, these may be best explained if co-ordination by two azine nitrogen atoms and hydrogen bonding of NH/NH2 to C m O / C - - S . * Molecular models were tried. c16~K. Sw~mAx~.~ and H. M. N. H. IRVING,J. inorg, nucL Chem. 26, 1291 (1964). exT~E. R. BLowr, M. F ~ s and R. KARVLUS,J. Am. chem. Soc. 70, 195 (1948).
1644
A. DtrrrA Arn~D and P. K. M.ANDAL
A representation set of u.v. spectra of the metal chelates is shown in Fig. 3 (cf. Table 4). The spectra closely resemble the general character of those of the respective ligands at higher pH (el. Table 4 and Fig. 4). The significant feature is the general shift of the high energy band to a lower one and of the other to a higher energy. This may be due to more effective delocalization of electrons and increased metal ligand interaction. This should also corroborate the assignment of the ~ 2 0 5 mp band to N--~N--N=C--N skeleton. The following structure is proposed for the 1 : 1 complexes:
I c
N
N
o S
I
/
tt
s
I
N~
j
I
N~ C
C N
N
I
The magnetic susceptibility measurements show the nickel complexes to be paramagnetic; but the values are low for two unpaired electrons and the value for the Ni-ligand II is abnormally low. This might be due to metal-metal bonding. Only one copper complex could be obtained, Cu(Ligand III)2C1. JENSm,I and MIQUEL(1) could prepare only an inner metallic complex of nickel with N-thiobenzoyl N'-carbamoyl hydrazine. The magnetic data show the copper to be monovalent. The compound is unstable in water solution, becomes turbid and then violet with time, probably due to oxidation of the monovalent copper. The u.v. absorption spectrum was taken immediately after preparing the solution. It is similar to that of the ligand in water. The i.r. spectrum of this compound shows evidence of nitrogen co-ordination; but the NH2 group might be free. The magnitude of the shift in the carbonyl frequency is also not in favour of NH2 co-ordination. The stretching modes of C--~S are considered to be present. The following structure is proposed for this complex. S o --
I!
![
CsHs--N~N~--N~/~H--C--N
-q
/cu\ /c NH2--C--NH--NH--C--NH--CaH5 [ --
II
O
II
S
__l
Attempts to prepare the corresponding nitrates and sulphates failed. Acknowledgements--Authors' sincerest thanks are due to S~ P. S. KOLrUffKAR o f Regional Research Laboratory, Hyderabad, India for i.r. spectra, to Dr. P. BANDYOPADrrVAVof University College of Science,Universityof Calcutta for magneticmeasurementsand to Prof. N. K. Dtrrr for his stimulating interest and encouragement.
N-THIOCARBAMOYL-N'-CARBAMOYL HYDRAZINE DERIVATIVES AND THEIR METAL COMPLEXES A. DUTTA AHMED* and P. K. MANDAL Inorganic Chemistry Division, Indian Association for the Cultivation of Science, Calcutta-32, India (Received 23 November 1965)
~ - - A study of N-thioearbamoyl-N'-carbamoylhydrazine derivatives as complexing ligands and their Ni, Cu, Zn and Cd complexes is described. The metals form 1 : 1 chelates with the ligands. One compound with formula Cu(I) (C~J-Is.NH.CS.NH.NH.C0.NH~)sC1 is also described. Ultraviolet and i.r. spectra of the ligands and the metal complexes and the magnetic properties of the latter are discussed. Structures for the metal complexes are proposed.
JENSEN and MIQUEL¢1) have described nickel complexes of N-thiobenzoyl-N'-(carbamoyl, thiocarbamoyl) hydrazine. Metal chelates of N-N'-di(allylthioearbamoyl) hydrazine have also been described from this laboratory t2.a). Recently ABLOV and G~R~LEU t~ have reported metal salts and complexes of a number of thiosemicarbazides and thiosemicarbazones. Now, it might be of interest to make a similar study with N.thiocarbamoyl N'.carbamoyl hydrazine derivatives. These compounds enolize and function as dibasic and possibly tetradentate ligands just as N-N'-di(thiocarbamoyl) hydrazine derivatives do. Metal chelates with these ligands have not been previously described. The present communication describes three ligands and their nickel, copper, zinc and cadmium chelates, of the same general formulae: (i) Ligand I: N-phenylthiocarbamoyl-N'-carbamoyl hydrazine CoHsNH-CS.NHNH.CO.NH z (ii) Ligand II: N-thiocarbamoyl-N'-phenylcarbamoyl hydrazine HzN.CS.NHNH-CO.NHCoH 5 (iii) Ligand III: N-allylthiocarbamoyl-N'-carbamoyl hydrazine CaHsNH.CS.NHNH.CO.NH 2 EXPERIMENTAL Preparation of Ligand I
The ligand was prepared from potassium cyanate, 4-phenylthiosemicarbazide and hydrochloric acid or from semicarbazide hydrochloride (0.1 mole), sodium carbonate and phenyl-isothiocyanat¢ as described by AgNOT et aL ~s~ The ligand was purified by repeated recrystallization from aqueous ethanol and analysed (m.p. 196°C). * To whom correspondence concerning this paper should be addressed. txJ K. A. JENSENand J. F. MIQUEL,Acta chem. scand. 6, 189 (1952). n~ N. K. DuTr and K. P. SEN SARMA, Analytica. chim. Acta 15, 21 (1956). cs~A. D u r r a ~ and S. N. DHAR, Sci. & Cult. 28, 540 (1962). ~'~ A. V. AnLOVand N. V. G~V.LEU, Zh. neorg. Khim. 9, 85 (1964) (eng. edn. p. 46). ~5~F. ARNO% E. MILI)~ and F. TSC~NSCHL~, Ber. dr. chem. Ges. 5513, 341 (1922). 1633
21"83 (22"01)
24.39 (23"60)
23"33 (23"39)
23 "08 (23-39)
25"28 (25.05)
Ni-Ligand IIb
Ni-Ligand III b
Cu-Ligand I b
Cu-Ligand H b
Cu-Ligand
(20"62)'
22.24 (22-09)
(20.62)
(11-79)
12.91 (12.62)
20"94
(20.62)
20-53
21 "75 (22-52)
21.13 (21"00)
11-97
11"68 (11-79)
12"83 (12-87)
(I 1"99)
11-10
19"72 (19-67)
Ni-Ligand I b
11.85 (11.24)
32.10 (32-18)
Ligand HI
20.76
26-54 (26-67)
Nitrogen
Ligand II
Sulphur 26"14 (26.67)
Metal
Ligand I
Compound
33-78 (34.48)
46.11 (45.72)
45"80 (45.72)
7"15 (7"10)
6"99 (7.24)
6"69 (6"67)
HsO e
5.79 (5.75)
4.93 (4.76)
4"89 (4-76)
Hydrogen
Others Formula
CUO1)(CsHsON,S)" 1 H,O
Cu(H)(CsHsON,S)
Cu(H)(CsHsON,S)
Ni(II)(CsHsON,S)" 1 HsO
Ni(II)(CsHaON,S)
Ni(II)(CsHsON4S)'I HsO
CsHioON~S
CsHloON,S
CsHxoOHN,S
LIGANDS A N D T H E I R COMPLEXES
Carbon
TABLE 1.--ANALYmSSo v
204°(d)
200°(d)
188°(d)
193°
218 °
196°
m.p./d.p. (uncorrected)
r~
ta,
.>
22.26 (22.44)
27.04 (27"54)
34-17 (35.09)
35.43 (35.09)
39"41 (39"53)
14"08 (14-21)
Zn-Ligand II °
Zn-Ligand IIIe
Cd-Ligand I a
Cd-Ligand II °
Cd-Ligand I l l e
Cu(I)-Ligand III a
15"02 (14.32)
11"65 (11-26)
10.03 (9-99)
9.94 (9.99)
13.32 (13"48)
10.92 (10.98)
11.10 (10.98)
18"23 (18"52)
16.98 (17.48)
17.39 (17.48)
22"81 (23.59)
19.30 (19.22)
19-12 (19"22) 6"15
8"24 (7"94)
Cl
6"21 (6.18)
(6"18)
ts~ Figures in parentheses are the required percentages tb~ Prepared by method A and/or B '~ Prepared by method A; preparation by method B needs extensive purification ca~ Prepared by method C ,e~ from dehydration cf~could not be determined.
22"71 (22-44)
Zn-Ligand 1 °
173°(d)
205-210°(d)
225°(d)
Cd(CaHaON4S)
Cd(CaHaON4S)
Cd(C6HsONIS)
196°(d)
200°(d)
Zn(CsHaON,S)
Cu(I)(CsHxoON,S),CI
220°(d)
200°(d)
Zn(CaHaON4S)" 1 HaO
Zn(CsHsON4S)q HtO
VI
t~
0
l-t
ea~
g
0"
1636
A. DUTTAAHMEDand P. K. MANDAL
Preparation of Ligand II The ligand was prepared from thiosemicarbazide and phenyl-isocyanate as described by FmSUND and SCHA~,U3F.Z~ te~ and was purified by repeated recrystallization from aqueous ethanol, and analysed (m.p. 218°(2).
Preparation of Ligand III The compound was prepared from semicarbazide hydrochloride and allyl-isothiocyanate as described by Busch and LoTz c7~ and was purified by repeated recrystallization from water and finally from ethanol and analysed (m.p. 193°C0.
Other chemicals Chemicals other than the ligands were of reagent grade. Ethanol and other solvents used for spectroscopic measurements were spectroscopically pure. cs~
Preparation of solutions of the ligands Thrice recrystallized ligands were used. For water solutions, warming to 60-70°C was allowed. Aqueous solutions of the ligands did not keep for more than 36 hr, decomposition being noted spectroscopically.
Preparation of metal chelates Three methods were used. (a) On addition of a soluble ammine complex of the metal (0.002 to 0.005 mole) to an aqueous solution or aqueous-ethanol solution of the ligand (0.008 to 0.020 mole), immediate precipitation occurred. The precipitate was heated on a water-bath for about half an hour, filtered, washed with dilute ammonia and finally with aqueous-ethanol, dried in a desiccator and analysed. The yield was quantitative. Co) On mixing an aqueous solution of the metal salt with an aqueous or aqueous--ethanol solution of the ligand in the same ligand/metal ratio as stated above, warming on waterbath, and on gradually raising the pH with a dilute solution of sodium bicarbonate, precipitation occurred. The precipitate was heated on a water bath for about half an hour, filtered, washed with warm water followed by aqueous-ethanol, dried in a desiccator and analysed. Yield was quantitative at proper pH values. (c) On addition of a hot ethanolic solution of metal chloride to a hot ethanolic solution of the ligand, pre~pitation occurred. The precipitate was washed with warm ethanol, desolvated and analysed.
Apparatus and measurements Absorptions in the u.v. and visible ranges were measured with a Hilger Uvispek, against the same solution minus the ligand as reference solution. Infra-red spectra were recorded with Perkin-Elmer models, 221 and 137B. Magnetic susceptibilities were measured with a Guoy Balance. The analyses of the compounds are shown in Table 1, along with their melting/decomposition points. The Amaxof u.v. spectra of ligands and complexes are summarized in Tables 2 and 4. Infrared bands are summarized in Table 3. The results of magnetic susceptibility measurements axe shown in Table 5. TAnLE 2.--Am~x (LOG0
96~o Ethanol 75~o Ethanol 50~o Ethanol 25yo Ethanol Water
VALUES OF LIGANDS IN AQUEOUS-ETHANOL soLUTION, IN
m/~
Ligand I
Ligand II
Ligand III
215(4.18), 235(4.12), 270(3.99) 214(4.22), 235 sh, 267 sh 212(4-27), 234 sh, 265sh
210(3.86), 245(4.39) 211(3-91), 245(4.41) 208(4.04), 243(4.42) 205(4.23), 242(4.40) 202(4-40), 242(4-38)
215(3.84), 245(4.13) 213(3.87), 244(4.12) 212(3.94), 243(4.12) 209(4.03), 241(4.13) a 240(4.14)
203(4.37), 245 sh
The Am,x value is at or below 200 m/~. I~UND and ScriAm~, Ber. dr. chem. Ges. 29, 2510 (1896). c7~M. BuscI~ and D. LOTZ, 3". Pr. 90, 270 (1914). c,~ A. WEISSaEROER,Editor, Techniqueof Organic Chemistry, Vol. VII. Interscience, New York (1955). ce~ M .
N-thiocarbamoyl-N'-carbamoyl hydrazine derivatives and their metal complexes RESULTS
AND
1637
DISCUSSION
The identification and characterization of the compounds have mainly b~en attempted from spectroscopic data. It is obvious though that due to the composite nature of the vibrations, interpretation and band assignment of the ligands and their metal derivatives is difficult.
The ligands The N-thiocarbamoyl-N'-carbamoyl hydrazine derivatives should have the following structure R--NH----C---NH--NH--C---NH--R'
II
II
S
O
It is possible that the ligands will exist in "keto" as well as "enol" forms, along with hydrogen-bonded and a number ofzwitter-ionic species. The effects are not necessarily of equal magnitude in both the "thiourea" and "urea" parts of the molecules. There is no band for OH or SH in the i.r. spectra of the ligands but hydrogen bonding and zwitterionic species are indicated, the complex nature and splitting of bands being observed in certain regions involving CS, CO and CN vibrations. Aqueous or alcohol solutions of the ligands show the existence of enol forms. Absorptions of a series of ligand-in-aqueous-ethanol solutions of differing water and ethanol proportions (Table 2 and a typical set of spectra in Fig. 1) as well as of isopropanol solution suggest tautomeric equilibria and zwitterionic species. Of the various resonating structures, the skeleton N - - ~ N - - N - - C - - N is most significant the delocalization of ~r-electrons lower the energy. The absorption maxima and extinction at 210 mp ascribed to this skeleton compares well with the data for CeHs--CH--N--N---CH--CeHs. ~°~ The usual changes in NCS band at 245 m/~ at higher pH's and in the absorption characteristics at 300 m/~ are also observed. The ligands are found to be dibasic. It may thus be concluded that the ligands form chelates through the following enolized form, R--NH~N--N~C--NH--R'
I
SH
L
OH
The observation agrees with previous finding¢1°-1~) in analogous cases. 1 :1
Metal chelates That the metal atoms are directly linked with the oxygen atoms can be proved by the absence of C----O and - - O H bands in the i.r. spectra. As far ~ts C-~-S is concerned there is some difference of opinion over the characteristic absorption region e.g. 1080 cm-1 ~ 1120 cm-1, ~13),~ 1400 cm- m i , m and ~ 730 cm-1. oz~ The latter two regions ~*~H. C. BARASY, E. A. BSAUDe and M. Pt~rr~, J. Chem. Soc. 1898 (1949). cxo~j. SA}r~srgoM, Acta chem. scand. 14, 1037 (1960). m} K. A. JmqseN and C. P~SRSeN, Acta chem. scand. 15, 1124 (1961). cm B. A. G ~ o P , t.s, R. L. SOMOIUAXand C. H. BAYLEY, Can. J. Chem. 39, 973 (1961). ix,} A. YAMAOUCHI,R. B. PEIqLAND, S. M x z U S ~ , T. J. LANE,C. CURRAN arid J. V. QUAGI.,IANO, J. Am. chem. Soc. 80, 527 (1958). cm E. Lnmmt, C. N. R. Rxo, C. N. PmL~, J. R~,~.AC[-IANDRANand R. D. HITeS, Can. J. Chem. 36, 801 (1958). cxs~j. E. STEWART,J. chem. Phys. 26, 248 (1957).
1565m
1310m
1310 s
1330s
1397sh
1315 s
1335 s
1420sh
1315 s
1335 s
1399sh
1310m
1345sh
1490m
1409ms
1350sh
1495 s
1495 s
1491 sh
1495 s
1525sh
1515 sb
1519m
1520s
1553 m
1540sh
1539ms 1515 s
1590 s 1550sh
1600s
1597sh
1575sh
1612m
1606 s
1615ms
3150m
3300sh
3350s
3500 m
Ligand
1612ms
2668 wb
2743m
3335 s
Ni
1655m
3280mb
3310mb
3557 mb
3500 mb
3375mb
Zn
Cu
Ligand I
1657 s
3185s
3244 s
3373m
Ligand
1325 sb
1490 s
1530sb
1550sb
1580s
1600 s
3220m
3350m
3500 m
Cu
L i g a n d II
1320sb
1510 s
1525m
1585 vs
1608 vs
2650mb
2720
3200s
3315 s
3435 m
3600 m
Zn
1325m
1390m
1505 w
1540s
1558sh
1592m
1608m
1515 m
1525m
1550m
1565m
1500sh
1535 s
1550sh?
1325 w
1522m
1555s
1580 s
1635m
1700s
2725 w
3140sb
3230 s
3300s
3346m
3368 m
3418m
3515
Cu0igandlII)2C1
1640m
1600 s
2730 m
3330 mb
3465 mb
Zn
Ligand HI
1672s 1600m
2720m
2770m
3300mb
3450 mb
Cu
1662 s
1692m
3160s
3315 s
3435 m
Ligand
TABLE 3.--SUMMARY OF i.r. BANDS OF LIGANDS AND THEIR CHELATES IN NUJOL IN c m -x
.>
890 w
880wb
835 w b
880m
820 wb
710m
680m
696sh
687ms
733m
740 m
705m
755m
690 m
715-730 m b
696ms
745 w
690s
720 s
750 s
710m 680 w
690 s
748m
720 m
750 s
710m 680m
685m
765m
710m
760sh
686 m
703 m
760 w
780 w
745m
760m
915 m
930 m
768 w
820m
915m
955 m
767m
835wb
885 w
910 w
950m
960m
982 m
lO00m
1040 w
1078 m
l130m
1160m
1230m
1292m
800 w
830m
910m
980m
980m
1030m
1060m
1145 s
1230m
1300s
785sh
835m
835 w
895 w 860m
895m
965m
960 m
965m 945m
990m
1035m
1080sh
1025 m ?
1070m
1027m
862 v w
910 v w
?
1026m
1070m
1145 m
1220m
1295m
795 v w
750m
930 v w
930 v w
930 v w
? 1041 m
l120m
l150m
1225m
1290m
795 w
926 w
962 w
960m
965m
985 w
950m
1020m
1005 w
990sh
1005 w
1070m
1030m
1030m
1025 w
1076m
070m
I074m
1094sh
ll50sh
l150m
l130m
ll30ms
1122 m
ll50wb
ll50sh
l145mb
1165sh
1135m
1222 m 1160 w
1220m
1220m
1215m
1240s l170m
1235m l170m
1260 w
1255sh?
1256sh?
1250sh?
1300 b
1215m
1300 s b
1256m
1296 m
1290sh?
1290sh?
1290m
ou
g
8
Z
1640
A. DUTTAAHM~ andP. K. MANDAL
LIGAND I
fir ~|1
I.o
II
rl
IN
,.,.~.~.o~ "'/" " ,o.~o ,,
|tl
I~I
o =.
O5
2OO
250 3OO WAVELENGTH (m/.c)--~
350
F]Q. 1.--Absorptions of N-allylthiocarbamoyl-N'-carbamoylhydrazine; 9.060 x 10-' M. BO
60~. ,, .o 0..,,,°,,..°.~
5G
\"
w U Z 4[ II-
4C
Z
3C
p--
20
I0
0 3600
I 3500
I 3400
I 3300
WAVELENGTH 1:;IO. 2a
I 3200
I 3lOG
3000 cn'T'
N-thiocarbamoyl-N-carbamoylhydrazine derivatives and their metal complexes
1641
{]
('l I ,
I/V/ •
v
....
r..-;
.
: ",./
/
/',i -i:/ 30 " U
:
: I: ¢6
\/
,
V
~;.
,o
1700
I 1600
I 1500
I 1400
I 1300
I 1200
I I100
I I000
I 900
I 800
I 700
6o(
cm
WAVELENGTH
Fxo. 2b.--I.R. spectra of Ligand HI ( ) and its Cu chelate (- . . . . . ), its Zn chelate ( . . . . . . . . . of Cu (Ligand HI)= C1 ( . . . . . . . -).
TABL~4.--2m=x V~LU~SOF C'H~ATESIN ETHANOL, IN m ~ Ligand I Ni Cu Zn Cd Cus b
215 sh, 238, 260, 282 sh 219 245 sh 220, 238, 250 sh, 265, 282 sh 220, 240, 255 sh, 282 sh
Ligand ]I
Ligand HI
215, 242, 270 sh 216, 220 sh, 280 sh 220, 245 220, 245, 250 sh 207, 239 205(4.38), 245(4.25), 280(4.12) 207(4.30), 245(4.30), 278 sh 206(4.08), 240(4.09) 214 sh, 255 215, 255 210 sh, 250 220, 245
= Cu" (Ligand I]T)aCI in water. b )'max (log e) of Ligand I at pH 11.02 (pH > pK,), of Ligand II at pH 10-87 (pH > pK0 and of Ligand lII at pH 10.50 (pH ~ pK0.
) and
1642
A. DUTI'A AHMED and P. K. M A ~ A ~
"-- 0
0
Z 0
8
0
u')
iln
0
~
X
!
Z 0 ".~
L 8N
0
~
~2
u.
"0"0 O
"O 0
•
u. o
13
q
,~
z
u
O
6
I O t.f3
I t.n f~
O
0 "(0"O
8
N-thiocarbamoyl-N'-carbamoyl hydrazine derivatives and their metal complexes
1643
are preferred, tm although some CN interactions are always likely to be present. However, bands present in the ligands in this region are absent in the chelates, and their absence is taken as evidence of metal-sulphur linkages. It is believed that certain new bands o f the chelates in the 800--1000 cm -~ region are overtones of metaloxygen/sulphur/nitrogen fundamentals. Similar to the azine group) xT~all the chelates show a band at ~-d600 cm -x. TABLE 5 . - - M A O N E T I C SUSCEPTIBILITIES OF COMPLEXES
Compounds Ni(CsHaON,S)'I HBO(I)~ Ni(CaH,ON,S) (II) Ni(CsHaON4S)'I HIO(IU) Cu(CaHsON4S) (I) Cu(CsHsON4S) (II) Cu(CsHBON,S)'I HtOOII) Cu(CsHloON,S)sCI(I~
XM(corrected) 2409.41 × 1211"34 × 2445.50 × 1142.44 × 1277"14 × 938.80 ×
10-6 10-6 10-e 10-6 10-6 10-6
(Diamagnetic correction) 100-61 × 10-6 90"14 × 10-e 76-70 × 10-6 90"14 × 10-e 90"14 × 10-6 76-70 × 10-6 Diamagnetic
/~B 2.39 1"70 2'41 1"65 1"75 1"50
a the numbers in the parenthesis denote the Ligand of which the compound is. The chelates are insoluble in organic solvents and in water, but the freshly prepared chelates are slightly soluble in organic solvents. Solutions for the measurements o f the u.v. absorption were prepared by refluxing freshly prepared chelates with ethanol. The insolubility is best explained by a polymeric structure. In such cases, the NH/NH~ of the (thio)carbamoyl group and either of the two nitrogen atoms of the azine group are capable of co-ordinating. The probability of co-ordination by both the nitrogen atoms of the azine group to the same metal atom is unlikely. Co-ordination of these two nitrogen atoms to two different metal atoms are possible in which case the ---OH and - - S H groups should be " t r a m " with respect to the N ~ N - - N - - - C - - N skeleton and each of them combine with two different metal atoms; if the two groups are "e/s" and attached to the same metal atom, co-ordination by one of the nitrogen atoms of the azine group to that metal atom will involve a strained four membered ring.* The other alternative is co-ordination by the nitrogen atoms of (thio)carbamoyl groups. All the bands in the region of 3 ~ in the chelates are broad and diffuse suggesting hydrogen bonding. Except the amide I bands observed near 1650 cm -1 (Ligand III has additional bands, including one at 1692 cm -1 of relatively weaker intensity it is difficult to identify the other bands. Complex formation and conjugation modify their locations. This could be the reason for the nature and position of bands in the chelates, specially those corresponding to ligand-bands at 1539 cm -1, 1553 cm -x and 1558 cm -x (probable Amide II), at 1519 cm -1, 1525 cm -1 and 1540 cm -1 (probable "NCS"), at 1490 cm - t (probable b(NH) and v(CN)), at 1250 ~ 1300 cm -1 (probable Amide III), at 1215 cm -x ~ 1 2 2 5 cm -x (probable ~(CN), b(NH)) and at ~ 7 5 0 cm -1 (probable v(CS) and v(CN)). The bands at 820 , ~ 845 cm -x for the chelates may also correspond to N---C--O and C - - S vibrations. However, these may be best explained if co-ordination by two azine nitrogen atoms and hydrogen bonding of NH/NH2 to C m O / C - - S . * Molecular models were tried. c16~K. Sw~mAx~.~ and H. M. N. H. IRVING,J. inorg, nucL Chem. 26, 1291 (1964). exT~E. R. BLowr, M. F ~ s and R. KARVLUS,J. Am. chem. Soc. 70, 195 (1948).
1644
A. DtrrrA Arn~D and P. K. M.ANDAL
A representation set of u.v. spectra of the metal chelates is shown in Fig. 3 (cf. Table 4). The spectra closely resemble the general character of those of the respective ligands at higher pH (el. Table 4 and Fig. 4). The significant feature is the general shift of the high energy band to a lower one and of the other to a higher energy. This may be due to more effective delocalization of electrons and increased metal ligand interaction. This should also corroborate the assignment of the ~ 2 0 5 mp band to N--~N--N=C--N skeleton. The following structure is proposed for the 1 : 1 complexes:
I c
N
N
o S
I
/
tt
s
I
N~
j
I
N~ C
C N
N
I
The magnetic susceptibility measurements show the nickel complexes to be paramagnetic; but the values are low for two unpaired electrons and the value for the Ni-ligand II is abnormally low. This might be due to metal-metal bonding. Only one copper complex could be obtained, Cu(Ligand III)2C1. JENSm,I and MIQUEL(1) could prepare only an inner metallic complex of nickel with N-thiobenzoyl N'-carbamoyl hydrazine. The magnetic data show the copper to be monovalent. The compound is unstable in water solution, becomes turbid and then violet with time, probably due to oxidation of the monovalent copper. The u.v. absorption spectrum was taken immediately after preparing the solution. It is similar to that of the ligand in water. The i.r. spectrum of this compound shows evidence of nitrogen co-ordination; but the NH2 group might be free. The magnitude of the shift in the carbonyl frequency is also not in favour of NH2 co-ordination. The stretching modes of C--~S are considered to be present. The following structure is proposed for this complex. S o --
I!
![
CsHs--N~N~--N~/~H--C--N
-q
/cu\ /c NH2--C--NH--NH--C--NH--CaH5 [ --
II
O
II
S
__l
Attempts to prepare the corresponding nitrates and sulphates failed. Acknowledgements--Authors' sincerest thanks are due to S~ P. S. KOLrUffKAR o f Regional Research Laboratory, Hyderabad, India for i.r. spectra, to Dr. P. BANDYOPADrrVAVof University College of Science,Universityof Calcutta for magneticmeasurementsand to Prof. N. K. Dtrrr for his stimulating interest and encouragement.