Abstract
A back-gate (BG) effect on a Coulomb blockade in a double-gate silicon-on-insulator (SOI) nanowire is investigated. The nanowire, which is situated at the bottom of a trench and connected to thicker source/drain regions, has a naturally formed barrier at both ends and works as a single-electron transistor at low temperatures. We found that a negative BG voltage increases the charging energy of the Coulomb-blockade island in the nanowire as well as the tunnel resistance of the barriers. This indicates the possibility that the BG voltage shifts the electron wave functions in the source/drain area away from the Coulomb-blockade island and decreases the capacitance of the small junctions located at both ends of the island.