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Lanthanides perchlorate

A solution of an unspecified lanthanide perchlorate in acetonitrile detonated while being heated under reflux. [Pg.287]

Individually indexed metal perchlorates are f Acetonitrile, Lanthanide perchlorate, 0758... [Pg.251]

These and related incidents are detailed under f Acetonitrile, Lanthanide perchlorate, 0758 Chromium(III) perchlorate. 6 dimethyl sulfoxide Cobalt(II) perchlorate hydrates, 4051... [Pg.389]

Moeller and Vicentini (48) have reported the complexes of DMA with lanthanide perchlorates in which the number of DMA molecules per metal ion decreases from eight for La(III)—Nd(III) to six for Tm(III)—Lu(III).apparently due to the decrease in the cationic size. The complexes of the intermediate metal ions have seven molecules of DMA in their composition. Complexes of lanthanide chlorides with DMA (49, 50) exhibit a decrease in L M from 4 1 to 3 1 through 3.5 1. These complexes probably have bridging DMA molecules. The corresponding complexes with lanthanide iodides (51), isothiocyanates (52), hexafluorophosphates (57), nitrates (54, 55), and perrhenates (49, 56) also show decreasing L M with decreasing size of the lanthanide ion. However, complexes of DMA with lanthanide bromides (55) do not show such a trend. Krishnamurthy and Soundararajan (41) have reported the complexes of DPF with lanthanide perchlorates of the composition [Ln(DPF)6]... [Pg.149]

Complexes of picolinamide with lanthanide perchlorates, nitrates, and isothiocyanates have been isolated by Condorelli et al. (59). All these complexes show changes in the stoichiometry on going from La(III) to Lu(III). The ligand acts as bi-dentate with the oxygen of the amide group as well as the heterocyclic nitrogen coordinating to the metal (Structure I). While the anions in the perchlorate complexes are not coordinated to lanthanide ions, those in the nitrate and isothiocyanate complexes are coordinated. [Pg.149]

Complexes of the lanthanides with a few cyclic amides are known. Miller and Madan have reported the complexes of 7-butyrolactam with lanthanide nitrates (60) and perchlorates (61). Complexes of lanthanide perchlorates and lighter lanthanide nitrates with BuL have a L M of 8 1. However, complexes of heavier lanthanide nitrates have a L M of only 3 1. By changing the solvent used for the crystallization of the abovementioned complexes, complexes of the formula [La(BuL)4(N03)3] and [Gd(BuL)3(N03)3] could be prepared (60). Complexes of NMBuL (61, 62) and CLM (63-66) have also been reported. [Pg.149]

Probably, the first series of lanthanide complexes with neutral oxygen donor ligands is that of AP with the lanthanide nitrates. In 1913, Kolb (79) reported tris-AP complexes with lighter lanthanide nitrates and tetrakis-AP complexes with heavier lanthanide nitrates. Subsequently, complexes of lanthanide nitrates with AP which have a L M of 6 1 and 3 1 have also been prepared (80-82). Bhandary et al. (83) have recently shown through an X-ray crystal and molecular structure study of Nd(AP)3(N03)3 that all the nitrates are bidentate and hence the coordination number for Nd(III) is nine in this complex. Complexes of AP with lanthanide perchlorates (81, 84), iodides (81, 85), and isothiocyanates (66, 86, 87) are known. While the perchlorates and iodides in the respective complexes remain ionic, two of the isothiocyanates are coordinated in the corresponding complexes of AP with lanthanide isothiocyanates. [Pg.150]

Castellani Bisi (98) has synthesized complexes of lanthanide perchlorates with DMP which have a L M of 8 1 for the lighter lanthanide and 7 1 for the heavier lanthanide complexes. These complexes were prepared by reacting the respective metal salts with an excess of the ligand. When the complexes were prepared under conditions of lower concentrations of the ligand, complexes of DMP with a L M of 6 1 were obtained. The perchlorate groups in all three groups of complexes are ionic. [Pg.151]

A number of methyl substituted PyO have been tried as ligands for coordination with the lanthanides. Depending on the position of the substituent, these ligands impart different degrees of steric strain for the formation of complexes. Since substituents in the 4 or 3 position do not introduce substantial steric hindrance to coordination, Harrison and Watson (160) could synthesize octakis-4-MePyO complexes. Subsequently, Koppikar and Soundararajan (161) could also synthesize octakis-3-MePyO complexes with lanthanide perchlorates. Complexes of 4-MePyO (162, 163) and 3-MePyO (164, 165) with lanthanide iodides and bromides also have a L M of 8 1. [Pg.156]

Substitution at the 2-position of the pyridine ring in PyO introduces steric hindrance to coordination as is evident from the formation of Heptakis-2-MePyO complexes with lanthanide perchlorates (167) and pentakis-2-MePyO complexes with the corresponding bromides (168), iodides (162) and chlorides (169). The lanthanide nitrate complexes prepared by Ramakrishnan and Soundararajan (170) have the formula Ln(2-MePy0)3(N03)3 -xH20in which all the nitrate groups are bidentate. [Pg.156]

Complexes of PyzO with lanthanide perchlorates (2 79) and hexafluorophosphates 180) are eight coordinate. However, La(III) perchlorate gives the complex La(Pyz0)7(C104)3 2 H20 in which both the water molecules are coordinated to La(III). In the case of complexes of PyzO with lanthanide chlorides 180), the number of coordinated ligands increases as the ionic radius of the lanthanide ion decreases. These complexes probably contain bridging ligands. [Pg.157]

Vicentini and coworkers have reported the complexes of DPPA with lanthanide perchlorates 224), hexafluorophosphates 225), chlorides and nitrates 226). The anions in the perchlorate and hexafluorophosphate complexes are noncoordinated and hence the complexes are six coordinated. Conductance data for the nitrate complexes indicate that the coordination interaction between the lanthanide ion and the nitrate ion decreases along the lanthanide series 226). [Pg.162]

Vicentini and Dunstan (227) have obtained tetrakis-DDPA complexes with lanthanide perchlorates in which the perchlorate groups are shown to be coordinated to the metal ion. DDPA also yields complexes with lanthanide isothiocyanates (228) and nitrates (229). All the anions in these complexes are coordinated. DPPM behaves more or less like DDPA which is reflected in the stoichiometry of the complexes of DPPM with lanthanide perchlorates (230), nitrates, and isothiocyanates (231). Hexakis-DMMP complexes of lanthanide perchlorates were recently reported by Mikulski et al. (210). One of the perchlorate groups is coordinated to the metal ion in the lighter lanthanide complexes, and in the heavier ones all the perchlorate groups are ionic. [Pg.163]

Sylvanovich and Madan (234) have isolated the complexes of OMPA with lanthanide nitrates. With the lighter lanthanide nitrates, bis-OMPA complexes were obtained and the heavier lanthanide nitrates yielded complexes of the type Ln2(OMPA)3-(N03)6. In the latter complexes both bridging and chelating ligands are present. Complexes of OMPA with lanthanide perchlorates are also known (235). Airoldi et al. [Pg.163]

Since 1972, complexes of lanthanides with cyclic sulfoxides have received considerable attention. Zinner and Vicentini (261) have reported the complexes of lanthanide perchlorates with TMSO. The L M in these complexes decreases along the lanthanide series. But in the case of complexes of lanthanide chlorides with TMSO, the L M increases from 2 1 for the lighter lanthanides to 3 1 for the heavier lanthanides (262). It has been suggested that these complexes, especially the bis-TMSO complexes, contain bridging chloride ions. Tetrakis-TMSO complexes with lanthanide isothiocyanates have also been reported (263). [Pg.167]

Complexes of TSO with lanthanide perchlorates which have the formula Ln(TS0)9(C104)3 have been reported by Edwards et al. (266) (Ln = Ce or Y). Later, Vicentini and Perrier (267) have prepared the whole series of complexes of TSO with lanthanide perchlorates and have shown that the L M in these complexes gradually decreases from 9 1 to 7 1 as the cationic size decreases. These authors could not prepare Y(TS0)g(C104)3 reported by Edwards et al. (266). Instead, they obtained the complex of the composition Y(TS0)7(C104)3. Two series of complexes of TSO with lanthanide hexafluorophosphates are known (268, 269). While the L M in one of the series is 7.5 1, in the other series it is found to be 8 1. The change in the stoichiometry of the two series of compounds is attributed to the preparative procedures adopted. In both the series of complexes, the PFg ion remains ionic. Lanthanide nitrates (270), chlorides (270), and isothiocyanates (271) also yield complexes with TSO. In all these complexes, changes in the stoichiometry could be observed when the lanthanide series was traversed. In all these complexes the anions are coordinated to the metal ion. [Pg.167]

DTMSO reacts with lanthanide perchlorates to yield complexes of the composition Ln(DTMSO)g(C104)3 (Ln = La, Nd) and Ln(DTMS0)7(Cl04)3 2 H20 (Ln =... [Pg.167]

Complexes of the lanthanides with only one ligand of this type have been reported so far. Paetzold and Bochmann (276) have reported the complexes of lanthanide perchlorates with DMSeO which have the composition Ln(DMSe0)8(C104)3. A distorted square antiprismatic structure with a point group symmetry )4 has been proposed for these complexes. [Pg.168]

The metal-oxygen and related vibrations occur in the far IR region and these vibrations have been studied only in a few cases. In the complexes of lanthanide perchlorates with PyO, i>Ln o occurs in the region of 270-370 cm-1 (148). Three i n-o... [Pg.176]

In the complexes of TBPO with lanthanide perchlorates, absorptions at 400 cm-1 have been ascribed to i>Ln o (210). Absorptions due to lanthanide-perchlorate vibrations (Ln—OC103) have been identified in the region 290—360 cm-1 for the complexes of lanthanide perchlorates with 2,6-DMePyO (171), TBPO (210), DMMP (210), and for the complexes of Ce(III) perchlorate with TPPO and TBPO (206, 211). Ln-Cl vibrations occur at 230 cm-1 in the complexes of lanthanide chlorides with TBP (195) and TPPO (202). In the complexes of lanthanide bromides with TBP (295), i Ln— Br occurs in the region of 195 cm-1. [Pg.177]

Fig. 5. Variation of i Ln-O with the ionic radii of the tripositive lanthanides in the complexes of lanthanide perchlorates with PyO, A, LnfPyOglClO , Ln(PyO)7(004)3 O, Ln(Py0)5(H20)(C104>3 (redrawn and reproduced with permission from Ref. 148)... Fig. 5. Variation of i Ln-O with the ionic radii of the tripositive lanthanides in the complexes of lanthanide perchlorates with PyO, A, LnfPyOglClO , Ln(PyO)7(004)3 O, Ln(Py0)5(H20)(C104>3 (redrawn and reproduced with permission from Ref. 148)...
See other pages where Lanthanides perchlorate is mentioned: [Pg.188]    [Pg.331]    [Pg.287]    [Pg.179]    [Pg.150]    [Pg.150]    [Pg.151]    [Pg.153]    [Pg.157]    [Pg.158]    [Pg.158]    [Pg.162]    [Pg.162]    [Pg.163]    [Pg.165]    [Pg.167]    [Pg.169]    [Pg.170]    [Pg.170]    [Pg.170]    [Pg.171]    [Pg.175]    [Pg.175]    [Pg.176]    [Pg.177]    [Pg.179]    [Pg.180]    [Pg.181]    [Pg.190]    [Pg.190]   
See also in sourсe #XX -- [ Pg.264 ]

See also in sourсe #XX -- [ Pg.128 ]



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Anion lanthanide perchlorates

Perchlorate complexes, lanthanide

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