1950°C Post Implantation Annealing of Al⁺Implanted 4H-SiC: Relevance of the Annealing Time

Abstract: Previous studies have shown that the electrical activation of a given implanted Al concentration in 4H-SiC increases with the increasing of the post implantation annealing temperature up to 1950-2100 • C and different annealing times in the range 0.5-5 min. This study shows that, at 1950 • C, the electrical activation of Al implanted in 4H-SiC increases with the increase of the annealing time up to attain saturation for annealing times longer than 22 min. Samples were obtained from the same Al implanted HPSI 4… Show more

“…All curves show a negative temperature coefficient at low temperatures, which is more pronounced for the Al implantations. In agreement with previous reports [10], the resistivity decreases with increasing annealing time or annealing temperature. Despite the large differences in dose rate -20 to 70 times larger in Sample C than in Samples A and B -very similar resistivity values between the samples are observed for both the dopants.…”

Phosphorous and Aluminum Implantation for MOSFET Manufacturing: Revisiting Implantation Dose Rate and Subsequent Surface Morphology

“…All curves show a negative temperature coefficient at low temperatures, which is more pronounced for the Al implantations. In agreement with previous reports [10], the resistivity decreases with increasing annealing time or annealing temperature. Despite the large differences in dose rate -20 to 70 times larger in Sample C than in Samples A and B -very similar resistivity values between the samples are observed for both the dopants.…”

Phosphorous and Aluminum Implantation for MOSFET Manufacturing: Revisiting Implantation Dose Rate and Subsequent Surface Morphology

“…The thermal activation energy of the sample annealed 1500 °C/240 min is (115 + 3) meV. The temperature dependence of R sh is mostly dominated by the temperature dependence of the Al acceptor partial ionization as shown in [10]. In such a case the thermal activation of the Arrhenius plots can be used for a rough estimation of the Al electrical activation in the layer by using the dependence of the dopant ionization energy on the dopant density [11]: 23% for 115 meV and 69% for 77 meV.…”

(Invited) Thermal Stability of 1×10²⁰cm^-3Al⁺Implanted 4H-SiC after Electrical Activation at Temperature ≥ 1850°C

“…3(a-d), 4(a-d) and 5(a-d), a remark is necessary. In the case of the 0.5-1×10 20 cm -3 Al implanted wafer [13], the plateau of the Al depth profile was not flat. This prevents to obtain the implanted Al material resistivity and drift carrier density per unit volume from a simple multiplication of the implanted layer thickness times the measured sheet resistance and times the measured Hall coefficient (once corrected by the Hall factor), respectively.…”

“…3(a-d), 4(a-d), and 5(a-d) compare the temperature dependences of the sheet resistance (resistivity), of the drift holes density (per unit area or per unit volume), and of the drift holes mobility, respectively, in Al + ion implanted 4H-SiC layers for equal Al implanted concentrations and equal annealing temperature but different annealing times. The data come from [13,14]. Holes density and holes mobility are defined "drift" because they have been corrected for the Hall factor.…”

“…The results for two annealing temperatures, 1600°C and 1950°C, and two annealing times in the range 5 min -5 h per each temperature, are shown in these figures. The used 4H-SiC substrates were either High Purity Semi Insulating 8° off-axis <0001> (HPSI) [13] or n-type homo epitaxial substrates 4° off-axis <0001> (EPI) [14]. The authors think that this is licit because, in their experience, no significant difference was evident between HPSI and EPI substrates, neither between 8° and 4° off-axis <0001>, for identical study of ion implantation and post implantation annealing.…”

(Invited) Al⁺ Ion Implanted 4H-SiC: Electrical Activation versus Annealing Time