X-ray crystallographic measurements on
crystals at −100 °C give average C=Se bond lengths of 1.86
Å, and 1.37 Å for C−N. Both the Se−C−N and N−C−N angles were measured at 120°, as expected for an
sp2-hybridized carbon. Through these same studies, the existence of Se−H
hydrogen bonding in the
crystal lattice—suggested from the O−H and S−H hydrogen bonding found in crystals of
urea and
thiourea—was confirmed. Both the shortened length of the N−C bond and the longer Se=C bond suggest a delocalization of the
lone pair on the amines; the Se=C
π-bonding electrons are drawn towards the selenium atom, while the nitrogen's lone pair is drawn towards the
carbonyl carbon. A similar effect is observed in urea and thiourea. In going from urea to thiourea to selenourea the double bond is more delocalized and longer, while the C−N
σ bond is stronger and shorter. In terms of
resonance structures, the
selenol form (structures II, III) is more prevalent compared to urea and thiourea analogs; however, the lone pair the nitrogen of selenourea delocalizes only slightly more than the lone pair on thiourea (in contrast to a much greater delocalization in going from urea to thiourea). These minor differences suggest that the properties emergent from the delocalized nitrogen lone pair and destabilization of the C=S and C=Se π bond in thiourea and selenourea will also be similar. : Unlike urea and thiourea, which have both been researched extensively, mainly qualitative and comparative information on selenourea's
tautomerization is available. In comparable manner to ketones, selones also tautomerize: : Since the greater delocalization of the lone pair electrons correlates with the selone product, the equilibrium position of selenourea likely has an
equilibrium position comparable to thiourea's (which is lies more to the right that than urea's). Thiourea has been shown to exist predominantly in its thione form at 42 °C in dilute
methanol, with the thionol tautomer almost nonexistent at neutral
pH. ==Reactivity==