Self-passivation Causes the Different Fermi Level Pinning between Metal-Si and Metal-Ge Contacts

Metal-Ge contacts possess much stronger Fermi level pinning (FLP) than metal-Si contacts, which is commonly believed to be due to Ge having a narrower bandgap and higher permittivity in the context of FLP caused by metal-induced gap states. Here, we show that both Ge and Si have a similar FLP strength if they adopt an identical interface chemical bonding configuration at the contact interface by performing first-principles calculations: Si and Ge have FLP factors of 0.16 and 0.11, respectively, if they adopt the same reconstructed bonding configuration and have FLP factors of 0.05 and 0, respectively, if they adopt the same non-reconstructed bonding configuration. We illustrate that Ge prefers the latter configuration at the contact interface, which has denser dangling-bond-induced surface states, and Si prefers the latter one, which has a self-passivation effect for reducing the dangling bond-induced interface states, to reproduce the experimental data. By revealing the significance of dangling bond-induced interface gap states on FLP, these findings shed new light on lowering the contact resistance for developing future Si CMOS technology.
Comment: 20 pages, 10 figures