Syntheses , Characterization and X-ray Structure of Potassium Hydrotris ( 2-Mercaptothiazolyl ) Borate , KMt , and Potassium Hydrotris ( Methimazole ) Borate , KTm

Os compostos hidrotris(2-mercaptotiazolil)borato de potássio, KMt, (1), e hidrotris(2metimazolil)borato de potássio, KTm, (2), foram preparados ao se reagir a amina tiol correspondente com KBH 4 . Foram caracterizados por métodos espectroscópicos e análise elementar. As estruturas no estado sólido de KMt.4H 2 O e do composto 2 foram determinadas por análises de difração de raios-X. A maior maciez do ânion em KMt.4H 2 O, em comparação com 2, é indicada pela ausência de interação entre ele e o cátion, que possui moléculas de água em sua esfera de coordenação. Em KMt.4H 2 O a geometria em torno do íon potássio é octaédrica distorcida e em 2, pirâmide de base quadrada distorcida. Em 2 o íon potássio está coordenado a dois átomos de enxofre dos anéis de um mesmo ânion e a três outros átomos de enxofre pertencentes a unidades KTm vizinhas. Ambos os compostos possuem uma estrutura polimérica.


Introduction
The cyclopentadienyl anion, C 5 H 5 -, Cp -, is a useful supporting ligand and has been used as such with almost all transition metals.However, in some cases, the synthesis of the CpM starting material is rather difficult, especially when M = early transition metal, mainly due to the lack of stability of the intermediates that originate the metallocenes. 1The hydrotris(pyrazolyl)borate ligand, HB(pz) 3  -, Tp -, belongs to a novel class of potentially tridentate proligands, which are isolobal with Cp -.For many applications it is easier to handle, more stable and cheaper, than Cp -. 2 The pyrazolyl nitrogen atoms are hard donors and analogues of this proligand bearing softer donor atoms, such as sulfur, are of interest.For example, by following Trofimenko's procedure for the preparation of the Tp - proligand, 2 Reglinski et al. demonstrated that reaction of methimazole (2-mercapto-1-methylimidazol) with NaBH 4 yields hydrotris(methimazole)borate, Tm -. 3 A similar but softer proligand, hydrotris(2-mercaptothiazolyl)borate, Mt -, derived from 2-mercaptothiazoline, has also been prepared as the sodium salt. 4n this paper we wish to describe the synthesis and characterization of the potassium salt of Mt -and the solidstate structures of the potassium salts of Mt -and Tm -, determined by X-ray diffraction analyses.

Experimental
General considerations KBH 4 and 2-mercapto-1-methylimidazole were purchased from Fluka, and 2-mercaptothiazoline, from Aldrich.All reagents were used as received.Potassium hydrotris(methimazole)borate, KTm (2), was prepared as described previously. 5Elemental analyses (C, H, N) were performed with a Perkin Elmer mod.PE-2400 CHN instrument.IR spectra were recorded on a Perkin Elmer 283B instrument. 1 H and 13 C spectra were recorded on a Bruker Avance DPX200 spectrometer operating at room temperature, using tetrametilsilane as an internal reference. 11B NMR spectrum was recorded on a Bruker Avance DPX400 spectrometer operating at room temperature, using BF 3 .Et 2 O as an internal reference.

Preparation of potassium hydrotris(2-mercaptothiazolyl)borate, KMt (1)
Finely divided KBH 4 (0.24 g, 4.45 mmol) and 2-mercaptothiazoline, (2.12 g, 17.80 mmol) were placed together with a magnetic stirring bar into a Schlenk flask.The flask was connected to a volumetric device and placed into a bath resting on a heating and stirring plate.The mixture was kept to 80 °C where upon evolution of H 2 commences.The temperature was controlled at 120 °C until 13.4 mmol of H 2 had been evolved.Then the mixture was allowed to cool down to room temperature and 20 mL of CH 2 Cl 2 was added.This mixture was stirred and allowed to rest for 15 min.after which a white solid settled in the bottom of the flask.The solid and the solution were separated and this process was repeated three times.The remaining white solid was dried under vacuum.Yield 75%. 1

X-ray structure analysis of compounds KMt.4H 2 0 (1) and KTm (2)
Good quality crystals of KTm were obtained from an aqueous solution that was left at room temperature for several days.All measurements were made at 120 K on an Enraf-Nonius Kappa-CCD difractometer (95 mm CCD camera on κ-goniostat) with graphite monochromated Mo Kα (λ = 0.71073 Å) radiation.The temperature was controlled using an Oxford Cryosystem low temperature device.Data collections (ϕ scans and ω scans with κ offsets) were carried out using the COLLECT program. 6Integration and scaling of the reflections were performed with the HKL Denzo-Scalepack system of programs. 7The final unit cell parameters were based on all reflections using HKL Scalepack. 7Absorption corrections were carried out using the multi-scan method. 8The structures were solved using Patterson methods with SHELXS-97. 9The models were refined by full-matrix least-squares procedures on F 2 using SHELXL-97. 10The WINGX program was used to analyze and prepare the data for publication. 11Crystal data, data collection procedures, structure determination methods and refinement results are summarized in Table 1.The ORTEP's were prepared using the ORTEP-3 for Windows. 12

Results and Discussion
Amine thiols such as methimazole exist as tautomers of the thiol and thione forms: As pointed out by Reglinski and co-workers 3 and Lobia and co-workers, 13 in these systems the thione form predominates, the acidic hydrogen is bound to the nitrogen atom, thus allowing the preparation of the sodium salt of Tm -.Our preparation is similar to that of Lobia and coworkers, 13 with some modifications in temperature and solvent washes, which led to better yields of Tm -, as the potassium salt. 5The NMR data of the two compounds indicated that the three rings were equivalent, in agreement with the literature, 3 and confirmed by the solid state structures determined by X-ray diffraction studies, discussed below.

Solid State Structural data of KMt.4H 2 O (1) and KTm (2)
Although the preparation of compound 1 has been previously described in the literature, its crystal structure has not been reported so far. 4 The geometry around the boron atom in KMt.indicated by the lack of interaction between its donor atoms and the potassium ion.
The geometry around the potassium cation can be described as a very distorted octahedron, better as a pentagonal pyramid, as observed before for other hydrotris borates. 14The largest deviation from the 90 o degree octahedral geometry takes place in OW(1)-K-OW(2) and OW(4)-K-OW(3) angles, with values of 120.8(1) o and 71.80(6) o , respectively, Table 2.The K-OW(1) bond distance is the shortest one, 2.676(2)Å, and is shorter than the sum of the K + + O 2-ionic radii of 2.78Å. 15Compound 1 has a polymeric structure, with an infinite chain consisting of K(H 2 O) n units that grows along the b axis, inside an approximate hexagonal cavity that is formed by the packing of the anions, that has an average diameter of 10(1)Å, Figure 3.The equivalent bond distances in the three rings were found to have similar values and all of them agree with the expected values for the bonds involved.
The bond distances and angles found for compound 1, are similar to the ones recently described in the literature for the TlTbz, Tbz = 2-mercaptobenzothiazoline, complex. 4In this compound the Tl cations are coordinated to the sulfur atoms and there are infinite one-dimensional polymeric chains, that exhibit a zigzag array of Tl and S atoms that are formed by the association of the monomeric units through the thione sulfur atoms.
The structure of compound 2, described here and shown in Figure 4, exhibits similarities to the X-ray structure previously reported for NaTm.4.5H 2 0, 3 such as bond distances and angles, Table 3. Crystallographic parameters and data collection and refinement details are summarized in Table 1.The counter-ion K + of 2 was found to be coordinated to two sulfur atoms of the hydrotris(methimazole)borate unit and to other three sulfur atoms, symmetrically dependent, belonging to neighboring KTm units, which is indicative of the soft nature of the ligand, and resulting in a pentacoordination environment around the cation.A better view of the environment around the potassium cation is shown in Figure 5.
The geometry around K + can be described as distorted square pyramidal.The K-S(1) bond, which is the longest one in the structure, forms the apex of the pyramid.The K-S(2) #3 is the shortest K-S bond in the structure and Table 2. Selected bond distances (Å) and angles (°) for atoms and the potassium ion for KMt.4H 2 O (1) according to X-ray diffraction analysis together with the K-S(3) are shorter than the sum of the K + + S 2-ionic radius of 3.22Å. 15In this compound there are infinite dimeric chains, along the a axes, that are held together by the potassium atoms, Figure 6.The structure of the sodium salt of Tm, NaTm.4.5H 2 0, was shown to consist of discrete Tm -anions having a distorted onedimensional chains of hydrated sodium cations. 1
4H 2 O is almost a regular tetrahedron.The anion has an approximate C 3 symmetry (average N-B-N = 108.6(3)o ) with the pseudo-symmetry C 3 axis parallel to the crystallographic b axis, Figure1.The rings are bound to the boron through the nitrogen atoms.The B-H bond is located along the C 3 pseudo-symmetry axis.Each ring is twisted around the B-N bond and the average angle between the three planes formed by them is 85(3) o .In each unit the potassium cation is coordinated to six water molecules.Two of them are symmetrically dependent of other neighboring K(H 2 O) 6 units.A view focusing on the potassium solvate sphere is shown in Figure 2. The soft nature of the Mt -anion is

Figure 3 .
Figure 3. ORTEP3 view of KMt.4H 2 O (1) showing the approximate hexagonal cavity that is formed by the packing of the anions along the b and the infinite chain of K(H 2 O)n units.