Title :
Single-electron-transistor behavior in deep sub-0.1 μm planar-doped-barrier FETs
Author :
Pesic, I. ; Mutlu, A. ; Gunther, N. ; Rahman, M. ; Schulze, J. ; Hansch, W. ; Eisele, I.
Author_Institution :
Electron Devices Lab., Santa Clara Univ., CA, USA
Abstract :
Planar-doped-barrier FETs (PDBFETs) show low-temperature current measurements similar to those of single-electron-transistors (SETs). Also, it appears from simulation that a dynamic LDD-like region in the PDBFET is created when the device is under gate bias. This paper discusses the concept of an N-PDBFET working as a SET. Under no gate bias, the silicon band-gap forms a large barrier which prevents tunneling from occurring. In addition, the region underneath the valence band can be treated as a quasi-continuum. However, under gate bias, the barrier produced by the silicon band-gap is narrowed significantly and discrete energy levels begin to appear under the valence energy band, enabling electrons to tunnel through the available valence energy states. Similarly, in P-PDBFETs, hole tunneling through available conductance energy states occurs.
Keywords :
field effect transistors; single electron transistors; tunnelling; valence bands; 0.1 micron; N-PDBFET; P-PDBFET; SET; band-gap barrier; conductance energy states; discrete valence energy band levels; electron tunneling; gate bias; hole tunneling; low-temperature currents; planar-doped-barrier FET; single-electron-transistor behavior; valence energy states; Electron devices; Energy states; FETs; Laboratories; MOSFET circuits; Molecular beam epitaxial growth; Physics; Potential well; Silicon; Tunneling;
Conference_Titel :
Device Research Conference, 2004. 62nd DRC. Conference Digest [Includes 'Late News Papers' volume]
Print_ISBN :
0-7803-8284-6
DOI :
10.1109/DRC.2004.1367799
