Title :
Quantification of Drain Extension Leakage in a Scaled Bulk Germanium PMOS Technology
Author :
Eneman, Geert ; De Jaeger, Brice ; Simoen, Eddy ; Brunco, David P. ; Hellings, Geert ; Mitard, Jérôme ; De Meyer, Kristin ; Meuris, Marc ; Heyns, Marc M.
Author_Institution :
Interuniversity Microelectron. Center, Leuven, Belgium
Abstract :
This paper is the first to quantify drain extension leakage in a sub-100-nm gate-length bulk germanium technology. Leakage through the transistor´s extension/halo junction is shown to be the dominant leakage component in a scaled transistor layout. Optimizing halo and extension implants to improve short-channel control further increases the extension leakage. As a consequence, drain-to-bulk leakage in Ge pFETs is likely 4 times 10-7 A/mum or higher for an LG = 70-nm pMOS technology with good short-channel control at a supply voltage of 1 V. The weak thermal sensitivity of the extension leakage points to a band-to-band tunneling (BTBT) mechanism, which leads to only 40%-50% increase of the extension leakage between 25degC and 100degC. As BTBT depends exponentially on the electric field across the junction, lowering the supply voltage below 0.7 V can lead to drain leakages below 1 times 10-7 A/mum.
Keywords :
MOS integrated circuits; field effect transistors; germanium; FET; Ge; band-to-band tunneling mechanism; drain extension leakage; halo junction; scaled bulk PMOS technology; size 100 nm; size 70 nm; temperature 100 degC; temperature 25 degC; transistor extension; voltage 1 V; Energy consumption; FETs; Germanium; Implants; MOSFETs; Microelectronics; Paper technology; Passivation; Silicon; Tunneling; Germanium; MOSFETs; halo implant; leakage current; p$+$-n junctions;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2009.2033156
