Veettil, B. P.Patterson, R.Koenig, D.Conibeer, G.Green, M. A.2026-01-012026-01-010295-5075WOS:000298131900039ORCID:/0000-0001-5485-9142/work/173452439https://hdl.handle.net/1885/733801874An improved design for double-barrier resonant tunnelling structures using silicon quantum dots (QDs) was quantitatively analyzed using a multi-mode scatter matrix method. Multilayer metal-barrier-QD/matrix-barrier-metal stacks that maximize both electron transport and confined energy are sought. Si QDs grown in silicon dioxide with silicon carbide barriers were the most advantageous combination for single QD layer double-barrier structures (DBSs). Lateral SiO(2) barriers provided greater confinement, especially in smaller dots and also caused increased splitting between resonant levels. These structures are excellent candidates for use as energy selective contacts (ESCs) and as layers in all-silicon tandem cells. Copyright (C) EPLA, 20114enSilicon nanocrystalsSolar-cellsOptical gainQuantum dotsNanostructures2011-11-2310.1209/0295-5075/96/5700682355194770