Growth, disorder, and physical properties of ZnSnN2.

Authors :: Feldberg, N.
Aldous, J. D.
Linhart, W. M.
Phillips, L. J.
Durose, K.
Stampe, P. A.
Kennedy, R. J.
Scanlon, D. O.
Vardar, G.
Field, R. L.
Jen, T. Y.
Goldman, R. S.
Veal, T. D.
Durbin, S. M.
Source :: Applied Physics Letters; 7/22/2013, Vol. 103 Issue 4, p042109-042109-5, 1p, 1 Diagram, 1 Chart, 3 Graphs
Publication Year :: 2013
Abstract: We examine ZnSnN2, a member of the class of materials contemporarily termed 'earth-abundant element semiconductors,' with an emphasis on evaluating its suitability for photovoltaic applications. It is predicted to crystallize in an orthorhombic lattice with an energy gap of 2 eV. Instead, using molecular beam epitaxy to deposit high-purity, single crystal as well as highly textured polycrystalline thin films, only a monoclinic structure is observed experimentally. Far from being detrimental, we demonstrate that the cation sublattice disorder which inhibits the orthorhombic lattice has a profound effect on the energy gap, obviating the need for alloying to match the solar spectrum. [ABSTRACT FROM AUTHOR]