Title :
Fabrication of CaF2/Si/CaF2 resonant-tunneling diodes by B-surfactant enhanced epitaxy of Si quantum-well layers
Author :
Wang, C.R. ; Bierkandt, M. ; Müller, B.H. ; Bugiel, E. ; Hofmann, K.R.
Author_Institution :
Inst. for Semicond. Devices & Electron. Mater., Hannover Univ., Germany
Abstract :
Double-barrier CaF2/Si/CaF2 resonant-tunneling diodes (RTDs) were fabricated by utilizing a new boron (B) surfactant-enhanced solid-phase epitaxy (SPE) technique for the critical growth of the Si quantum-well films on CaF2/Si(111) substrates. This technique consists of the room temperature deposition of an amorphous Si film, the subsequent deposition of one monolayer of B atoms, and annealing to about 635°C. This resulted in continuous and smooth epitaxial Si layers on CaF2 with a sharp B-induced (√3×√3 )R30° surface reconstruction. At 77 K the RTDs exhibited stable N-type I-V characteristics with negative differential resistance (NDR) with 2-7 orders of magnitude higher peak currents and much lower peak voltages than in earlier results.
Keywords :
amorphous semiconductors; annealing; boron; calcium compounds; current density; elemental semiconductors; monolayers; negative resistance; resonant tunnelling diodes; semiconductor epitaxial layers; semiconductor growth; semiconductor quantum wells; silicon; solid phase epitaxial growth; surface reconstruction; surfactants; 293 to 298 K; 635 degC; 77 K; B; CaF2-Si-CaF2; CaF2/Si(111) substrates; I-V curves; NDR; Si quantum-well films; Si quantum-well layers; amorphous Si film; annealing; boron; double-barrier CaF2-Si-CaF2 resonant-tunneling diodes; monolayer; negative differential resistance; peak current density; room temperature deposition; smooth epitaxial Si layers; surface reconstruction; surfactant-enhanced solid-phase epitaxy; Amorphous materials; Boron; Diodes; Epitaxial growth; Fabrication; Quantum wells; Resonant tunneling devices; Semiconductor films; Substrates; Temperature;
Conference_Titel :
Nanotechnology, 2004. 4th IEEE Conference on
Print_ISBN :
0-7803-8536-5
DOI :
10.1109/NANO.2004.1392356
