Title :
Arsenic-spike epilayer technology applied to bipolar transistors
Author :
Van Noort, Wibo D. ; Nanver, Lis K. ; Slotboom, Jan W.
Author_Institution :
Lab. of Electron. Components, Delft Univ. of Technol., Netherlands
fDate :
11/1/2001 12:00:00 AM
Abstract :
For the first time, epilayers with an arsenic-doped spike of 50 nm width have been grown and used in silicon bipolar junction transistors (BJTs). The epilayer has been optimized such that the collector-base junction of the BJT is formed within the arsenic spike. The counterdoping of boron out-diffusion by arsenic strongly reduces the basewidth. The portion of the spike that is not counterdoped increases the total amount of n-type doping in the collector without reducing BV ceo. The increased collector-doping allows a 60% higher collector current prior to fT fall-off. Arsenic has a low diffusivity so very few constraints are put on the thermal budget of the final process. This high flexibility makes the presented epilayer technology a promising candidate to enhance a bipolar process significantly
Keywords :
arsenic; bipolar transistors; diffusion; elemental semiconductors; semiconductor doping; semiconductor epitaxial layers; silicon; Si:As; arsenic doped spike; boron out-diffusion; collector current; collector-base junction; counterdoping; cut-off frequency; diffusivity; epilayer technology; silicon bipolar junction transistor; thermal budget; Annealing; Bipolar transistors; Boron; Cutoff frequency; Delay effects; Kirk field collapse effect; Laboratories; Semiconductor device doping; Semiconductor epitaxial layers; Silicon;
Journal_Title :
Electron Devices, IEEE Transactions on
