Ytterbium(III) chloride (YbCl<sub>3</sub>) is an inorganic compound. It was first synthesized by Jan Hoogschagen in 1946. It is a paramagnetic Lewis acid, like many of the lanthanide chlorides. This gives rise to pseudocontact shifted NMR spectra, akin to NMR shift reagents. It reacts with NiCl<sub>2</sub> to form a very effective catalyst for the reductive dehalogenation of aryl halides.
The valence electron configuration of Yb<sup>+3</sup> (from YbCl<sub>3</sub>) is 4f<sup>13</sup>5s<sup>2</sup>5p<sup>6</sup>, which has crucial implications for the chemical behaviour of Yb<sup>+3</sup>. Also, the size of Yb<sup>+3</sup> governs its catalytic behaviour and biological applications. For example, while both Ce<sup>+3</sup> and Yb<sup>+3</sup> have a single unpaired f electron, Ce<sup>+3</sup> is much larger than Yb<sup>+3</sup> because lanthanides become much smaller with increasing effective nuclear charge as a consequence of the f electrons not being as well shielded as d electrons. This behavior is known as the lanthanide contraction. The small size of Yb<sup>+3</sup> produces fast catalytic behavior and an atomic radius (0.99 ÃÂ ) comparable to many biologically important ions.
The gas-phase thermodynamic properties of this chemical are difficult to determine because the chemical can disproportionate to form [YbCl<sub>6</sub>]<sup>âÂÂ3</sup> or dimerize. The Yb<sub>2</sub>Cl<sub>6</sub> species was detected by electron impact (EI) mass spectrometry as (Yb<sub>2</sub>Cl<sub>5</sub><sup>+</sup>). Additional complications in obtaining experimental data arise from the myriad of low-lying f-d and f-f electronic transitions. Despite these issues, the thermodynamic properties of YbCl<sub>3</sub> have been obtained and the C<sub>3V</sub> symmetry group has been assigned based upon the four active infrared vibrations.
Anhydrous ytterbium(III) chloride can be produced by the ammonium chloride route. In the first step, ytterbium oxide is heated with ammonium chloride to produce the ammonium salt of the pentachloride:
In the second step, the ammonium chloride salt is converted to the trichloride by heating in a vacuum at 350-400 ðC:
Membrane biology has been greatly influenced by YbCl<sub>3</sub>, where<sup>39</sup>K<sup>+</sup> and<sup>23</sup>Na<sup>+</sup> ion movement is critical in establishing electrochemical gradients. Nerve signaling is a fundamental aspect of life that may be probed with YbCl<sub>3</sub> using NMR techniques. YbCl<sub>3</sub> may also be used as a calcium ion probe, in a fashion similar to a sodium ion probe.
YbCl<sub>3</sub> is also used to track digestion in animals. Certain additives to swine feed, such as probiotics, may be added to either solid feed or drinking liquids. YbCl<sub>3</sub> travels with the solid food and therefore helps determine which food phase is ideal to incorporate the food additive. The YbCl<sub>3</sub> concentration is quantified by inductively coupled plasma mass spectrometry to within 0.0009 üg/mL. YbCl<sub>3</sub> concentration versus time yields the flow rate of solid particulates in the animal's digestion. The animal is not harmed by the YbCl<sub>3</sub> since YbCl<sub>3</sub> is simply excreted in fecal matter and no change in body weight, organ weight, or hematocrit levels has been observed in mice.
The catalytic nature of YbCl<sub>3</sub> also has an application in DNA microarrays, or so-called DNA âÂÂchipsâÂÂ. YbCl<sub>3</sub> led to a 50âÂÂ80 fold increase in fluorescein incorporation into target DNA, which could revolutionize infectious disease detection (such as a rapid test for tuberculosis).