TY - JOUR
T1 - High-energy ion implantation for electrical isolation of microelectronic devices
AU - Ridgway, M. C.
AU - Ellingboe, S. L.
AU - Elliman, R. G.
AU - Williams, J. S.
PY - 1994/5/1
Y1 - 1994/5/1
N2 - Recent developments in the use of high-energy ion implantation for electrical isolation of both group IV (Si) and III-V (InP, GaAs) devices are presented. For Si devices, dielectric isolation can be achieved with the fabrication of a buried SiO2 layer by high-dose (∼ 1018/cm2), high-energy (1 MeV) O-ion implantation. With MeV implant energies, implant temperatures ( ∼ 150°C) can be significantly reduced compared to those required ( ∼ 550°C) in a conventional, low-energy (150-200 keV) SIMOX fabrication process and consequently, striking differences in post-anneal defect structures are apparent. Also, novel methodologies (high-energy O and Si co-implantation) for achieving low defect density SIMOX material are described. For III-V devices, electrical isolation can be accomplished with the production of implantation-induced disorder wherein the resulting deep-levels effectively trap charge carriers. Conventional, low-energy (100-200 keV) implant isolation schemes necessitate multiple-energy, multiple-ion implant sequences. In the present report, a single, low-dose (∼ 1013/cm2), high-energy (5 MeV) O-ion implant is shown to result in comparable electrical isolation with significant processing simplification.
AB - Recent developments in the use of high-energy ion implantation for electrical isolation of both group IV (Si) and III-V (InP, GaAs) devices are presented. For Si devices, dielectric isolation can be achieved with the fabrication of a buried SiO2 layer by high-dose (∼ 1018/cm2), high-energy (1 MeV) O-ion implantation. With MeV implant energies, implant temperatures ( ∼ 150°C) can be significantly reduced compared to those required ( ∼ 550°C) in a conventional, low-energy (150-200 keV) SIMOX fabrication process and consequently, striking differences in post-anneal defect structures are apparent. Also, novel methodologies (high-energy O and Si co-implantation) for achieving low defect density SIMOX material are described. For III-V devices, electrical isolation can be accomplished with the production of implantation-induced disorder wherein the resulting deep-levels effectively trap charge carriers. Conventional, low-energy (100-200 keV) implant isolation schemes necessitate multiple-energy, multiple-ion implant sequences. In the present report, a single, low-dose (∼ 1013/cm2), high-energy (5 MeV) O-ion implant is shown to result in comparable electrical isolation with significant processing simplification.
UR - http://www.scopus.com/inward/record.url?scp=0000587014&partnerID=8YFLogxK
U2 - 10.1016/0168-583X(94)00032-8
DO - 10.1016/0168-583X(94)00032-8
M3 - Article
AN - SCOPUS:0000587014
SN - 0168-583X
VL - 89
SP - 290
EP - 297
JO - Nuclear Instruments and Methods in Physics Research, Section B: Beam Interactions with Materials and Atoms
JF - Nuclear Instruments and Methods in Physics Research, Section B: Beam Interactions with Materials and Atoms
IS - 1-4
ER -