The coordination complex [Cr(CO)₆] forms colorless, diamagnetic crystals that melt at 90 °C
a. What is the oxidation number of chromium in this compound?
d. Write the name for [Cr(CO)₆] using the nomenclature rules for coordination compounds.

Complete the exercises below. In 2001, chemists at SUNY-Stony Brook succeeded in synthesizing the complex trans-[Fe(CN)₄(CO)₂]²⁻, which could be a model of complexes that may have played a role in the origin of life. a. Sketch the structure of the complex. b. The complex is isolated as a sodium salt. Write the complete name of this salt. c. What is the oxidation state of Fe in this complex? How many d electrons are associated with the Fe in this complex? d. Would you expect this complex to be high spin or low spin? Explain.

Complete the exercises below. When Alfred Werner was developing the field of coordination chemistry, it was argued by some that the optical activity he observed in the chiral complexes he had prepared was due to the presence of carbon atoms in the molecule. To disprove this argument, Werner synthesized a chiral complex of cobalt that had no carbon atoms in it, and he was able to resolve it into its enantiomers. Design a cobalt(III) complex that would be chiral if it could be synthesized and that contains no carbon atoms. (It may not be possible to synthesize the complex you design, but we will not worry about that for now.)

Complete the exercises below. Generally speaking, for a given metal and ligand, the stability of a coordination compound is greater for the metal in the +3 oxidation state rather than in the +2 oxidation state (for metals that form stable +3 ions in the first place). Suggest an explanation, keeping in mind the Lewis acid–base nature of the metal–ligand bond.