TY - JOUR
T1 - Uncovering the Origin of Divergence in the CsM(CrO4)2 (M = La, Pr, Nd, Sm, Eu; Am) Family through Examination of the Chemical Bonding in a Molecular Cluster and by Band Structure Analysis
AU - Galley, Shane S.
AU - Arico, Alexandra A.
AU - Lee, Tsung-Han
AU - Deng, Xiaoyu
AU - Yao, Yong-Xin
AU - Sperling, Joseph M.
AU - Proust, Vanessa
AU - Storbeck, Julia S.
AU - Dobrosavljevic, Vladimir
AU - Neu, Jennifer N.
AU - Siegrist, Theo
AU - Baumbach, Ryan E.
AU - Albrecht-Schmitt, Thomas E.
AU - Kaltsoyannis, Nikolas
AU - Lanatà, Nicola
PY - 2018
Y1 - 2018
N2 - A series of f-block chromates, CsM(CrO4)2 (M = La, Pr, Nd, Sm, Eu; Am), were prepared revealing notable differences between the AmIII derivatives and their lanthanide analogs. While all compounds form similar layered structures, the americium compound exhibits polymorphism and adopts both a structure isomorphous with the early lanthanides as well as one that possesses lower symmetry. Both polymorphs are dark red and possess band gaps that are smaller than the LnIII compounds. In order to probe the origin of these differences, the electronic structure of CsSm(CrO4)2, CsEu(CrO4)2and CsAm(CrO4)2 were studied using both a molecular cluster approach featuring hybrid density functional theory and QTAIM analysis, and by the periodic LDA+GA and LDA+DMFT methods. Notably, the covalent contributions to bonding by the f orbitals was found to be more than twice as large in the AmIII chromate than in the SmIII and EuIII compounds, and even larger in magnitude than the Am-5f spin-orbit splitting in this system. Our analysis indicates also that the Am‒O covalency in CsAm(CrO4)2 is driven by the degeneracy of the 5f and 2p orbitals, and not by orbital overlap.
AB - A series of f-block chromates, CsM(CrO4)2 (M = La, Pr, Nd, Sm, Eu; Am), were prepared revealing notable differences between the AmIII derivatives and their lanthanide analogs. While all compounds form similar layered structures, the americium compound exhibits polymorphism and adopts both a structure isomorphous with the early lanthanides as well as one that possesses lower symmetry. Both polymorphs are dark red and possess band gaps that are smaller than the LnIII compounds. In order to probe the origin of these differences, the electronic structure of CsSm(CrO4)2, CsEu(CrO4)2and CsAm(CrO4)2 were studied using both a molecular cluster approach featuring hybrid density functional theory and QTAIM analysis, and by the periodic LDA+GA and LDA+DMFT methods. Notably, the covalent contributions to bonding by the f orbitals was found to be more than twice as large in the AmIII chromate than in the SmIII and EuIII compounds, and even larger in magnitude than the Am-5f spin-orbit splitting in this system. Our analysis indicates also that the Am‒O covalency in CsAm(CrO4)2 is driven by the degeneracy of the 5f and 2p orbitals, and not by orbital overlap.
U2 - 10.1021/jacs.7b09474
DO - 10.1021/jacs.7b09474
M3 - Article
SN - 0002-7863
VL - 140
SP - 1674
EP - 1685
JO - Journal of the American Chemical Society
JF - Journal of the American Chemical Society
ER -