Gadolinium(III) chloride, also known as gadolinium trichloride, is GdCl<sub>3</sub>. It is a colorless, hygroscopic, water-soluble salt. The hexahydrate GdCl<sub>3</sub>âÂÂ6H<sub>2</sub>O is commonly encountered and is sometimes also called gadolinium trichloride. Gd<sup>3+</sup> species are of special interest because the ion has the maximum number of unpaired spins possible, at least for known elements. With seven valence electrons and seven available f-orbitals, all seven electrons are unpaired and symmetrically arranged around the metal. The high magnetism and high symmetry combine to make Gd<sup>3+</sup> a useful component in NMR spectroscopy and MRI.
GdCl<sub>3</sub> is usually prepared by the "ammonium chloride" route, which involves the initial synthesis of (NH<sub>4</sub>)<sub>2</sub>[GdCl<sub>5</sub>]. This material can be prepared from the common starting materials at reaction temperatures of 230 ðC from gadolinium oxide:
from hydrated gadolinium chloride:
from gadolinium metal:
In the second step the pentachloride is decomposed at 300 ðC:
This pyrolysis reaction proceeds via the intermediacy of NH<sub>4</sub>[Gd<sub>2</sub>Cl<sub>7</sub>].
The ammonium chloride route is more popular and less expensive than other methods. GdCl<sub>3</sub> can, however, also be synthesized by the reaction of solid Gd at 600 ðC in a flowing stream of HCl.
Gadolinium(III) chloride also forms a hexahydrate, GdCl<sub>3</sub>âÂÂ6H<sub>2</sub>O. The hexahydrate is prepared by gadolinium(III) oxide (or chloride) in concentrated HCl followed by evaporation.
GdCl<sub>3</sub> crystallizes with a hexagonal UCl<sub>3</sub> structure, as seen for other 4f trichlorides including those of La, Ce, Pr, Nd, Pm, Sm, Eu. The following crystallize in theYCl<sub>3</sub> motif: DyCl<sub>3</sub>, HoCl<sub>3</sub>, ErCl<sub>3</sub>, TmCl<sub>3</sub>, YdCl<sub>3</sub>, LuCl<sub>3</sub>, YCl<sub>3</sub>). The UCl<sub>3</sub> motif features 9-coordinate metal with a tricapped trigonal prismatic coordination sphere. In the hexahydrate of gadolinium(III) chloride and other smaller 4f trichlorides and tribromides, six H<sub>2</sub>O molecules and 2 Cl<sup>âÂÂ</sup> ions coordinate to the cations resulting in a coordination group of 8.
Gadolinium salts are of primary interest for relaxation agents in magnetic resonance imaging (MRI). This technique exploits the fact that Gd<sup>3+</sup> has an electronic configuration of f<sup>7</sup>. Seven is the largest number of unpaired electron spins possible for an atom, so Gd<sup>3+</sup> is a key component in the design of highly paramagnetic complexes. To generate the relaxation agents, Gd<sup>3+</sup> sources such as GdCl<sub>3</sub>âÂÂ6H<sub>2</sub>O are converted to coordination complexes. GdCl<sub>3</sub>âÂÂ6H<sub>2</sub>O can not be used as an MRI contrasting agent due to its low solubility in water at the body's near neutral pH. "Free" gadolinium(III), e.g. [GdCl<sub>2</sub>(H<sub>2</sub>O)<sub>6</sub>]<sup>+</sup>, is toxic, so chelating agents are essential for biomedical applications. Simple monodentate or even bidentate ligands will not suffice because they do not remain bound to Gd<sup>3+</sup> in solution. Ligands with higher coordination numbers therefore are required. The obvious candidate is EDTA<sup>4âÂÂ</sup>, ethylenediaminetetraacetate, which is a commonly employed hexadentate ligand used to complex to transition metals. In lanthanides, however, exhibit coordination numbers greater than six, so still larger aminocarboxylates are employed.
One representative chelating agent is H<sub>5</sub>DTPA, diethylenetriaminepentaacetic acid. Chelation to the conjugate base of this ligand increases the solubility of the Gd<sup>3+</sup> at the body's neutral pH and still allows for the paramagnetic effect required for an MRI contrast agent. The DTPA<sup>5âÂÂ</sup> ligand binds to Gd through five oxygen atoms of the carboxylates and three nitrogen atoms of the amines. A 9th binding site remains, which is occupied by a water molecule. The rapid exchange of this water ligand with bulk water is a major reason for the signal enhancing properties of the chelate. The structure of [Gd(DTPA)(H<sub>2</sub>O)]<sup>2âÂÂ</sup> is a distorted tricapped trigonal prism.
The following is the reaction for the formation of Gd-DTPA: