Samples containing chromium (both 53Cr-enriched and non-enriched) have been prepared by equilibrium adsorption or impregnation methods at low loadings (<0.5%) using ZrO, , y-Al,O, , SnO,, TiO, (anatase) and SiO, as supports. Heating in O,, generally at 773 K, yielded mononuclear CrV species in a square-pyramidal configuration, Crgc (A), on all supports with the exception of SiO, where CrV is in a tetrahedral configuration, Crxc (A). H, O or NH,, both a t room temperature (RT), yielded the Crxv (A) species from CrEc (A), that is, the complex changes its coordination from five to six. After H, O adsorption and evacuation at RT, Crgc (A) is reversibly restored; however, N H, adsorption and evacuation at increasing temperature gives a new CrV species at 473 K. In the EPR signal of this species, designated Cr& (B), the perpendicular component is split into three lines with 14NH3 (A,4N = 4.0 G) and t w o lines with 15NH3 (A,5N = 5.5 G). The species is therefore assigned to a chromyl complex with an equatorial 0,ligand replaced by a nitrogen-containing NH:-3 species, possibly the NH; anion. With H,O or NH, at RT, the Crgc (B) species is transformed into the corresponding hexacoordinated species, Cr& (B).Upon adsorption of small H, O doses on the CrO,/SiO, sample, the Crgc (A) species is transformed into Crgc (A) and Crxc (A). In the presence of excess water, the chromyl species on SiO, becomes unstable, undergoing disproportionation t o Cr"' and Cr"' On adsorption of NH,, Cr& (6) is formed from Cr& (A) at RT. With 5N H,, a small superhyperfine interaction with nitrogen is partially resolved. Computer-calculated spectra enable us t o assign the Cr& (B) species o n SiO, t o a slightly distorted chromyl complex with slightly nonplanar equatorial ligands.
