Anomalous anisotropy of workfunction values in ternary alkali metal transition metal acetylides is reported. Workfunction values of some characteristic surfaces in these emerging semiconducting materials may differ by more than ≈ 2 eV as predicted by Density Functional Theory calculations. This large anisotropy is a consequence of the relative orientation of rod-like [MC2]∞ negatively charged polymeric subunits and the surfaces, with M being a transition metal or metalloid element and C2 refers to the acetylide ion C22−, with the rods embedded into an alkali cation matrix. It is shown that the conversion of the seasoned Cs2Te photo-emissive material to ternary acetylide Cs2TeC2 results in substantial reduction of its ≈ 3 eV workfunction down to 1.71-2.44 eV on the Cs2TeC2(010) surface while its high quantum yield is preserved. Similar low workfunction values are predicted for other ternary acetylides as well, allowing for a broad range of applications from improved electron- and light-sources to solar cells, field emission displays, detectors and scanners.
@article{arxiv.1207.2512,
title = {Anomalous Workfunction Anisotropy in Ternary Acetylides},
author = {Joseph Z. Terdik and Károly Németh and Katherine C. Harkay and Jeffrey H. Terry, and Linda Spentzouris and Daniel Velázquez and Richard Rosenberg and George Srajer},
journal= {arXiv preprint arXiv:1207.2512},
year = {2015}
}