Photoluminescence and transport studies of boron in 4H SiC

Sridhara, S.G.; Clemen, L. L.; Devaty, Robert P.; Choyke, W. J.; Larkin, David J.; Kong, H.S.; Troffer, T.; Pensl, Gerhard

doi:10.1063/1.367970

Cited by 120 publications

(56 citation statements)

References 38 publications

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“…It is well known 15 that, under appropriate values of the different chemical potentials involved, these sites are highly stable, and this stability is exploited in many microelectronic applications, where B is used as a shallow acceptor at a Si site. 16 Our results 11 reproduce this evidence, and confirm that substitution in the C sublattice is most favorable. However, in this work we focus on the analysis of the interaction of a B interstitial with the lattice, and of a B substitutional in the Si sublattice with the corresponding Si interstitial, in order to probe the possibility of intrinsic defect mediated diffusion.…”

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confidence: 79%

Theoretical evidence for the kick-out mechanism for B diffusion in SiC

Rurali

Godignon

Rebollo

et al. 2002

Applied Physics Letters

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In this letter, we analyze by means of first-principles electronic structure calculations the diffusion of B impurities in 3C-SiC. We find, through molecular dynamics, that substitutional B at a Si lattice site is readily displaced by a nearby Si interstitial by the process known as a kick-out mechanism, in agreement with recent experimental results. This is in contrast to the situation in Si, where B has recently been shown to diffuse via an interstitialcy mechanism.

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confidence: 79%

Theoretical evidence for the kick-out mechanism for B diffusion in SiC

Rurali

Godignon

Rebollo

et al. 2002

Applied Physics Letters

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“…[10] Unfortunately in many cases, a comprehensive and quantitative correlation between the change in LTPL intensity and the concentration of residual species is still lacking. Basically, what is done is that a normalized LTPL intensity curve is drawn for a given polytype versus SIMS concentration or (below the SIMS detection limit) versus results of capacitance-voltage (C-V) measurements obtained from a mercury probe or a similar technique.…”

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confidence: 99%

Application of LTPL Investigation Methods to CVD‐Grown SiC

Camassel

Juillaguet

Zieliński

et al. 2006

Chemical Vapor Deposition

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We review in detail the few (simple) theoretical equations that rule all near-equilibrium recombination processes in semiconductors with direct or indirect bandgaps. In the case of 4H-SiC, we discuss their physical significance and show the corresponding limits. Next, we discuss the effect of residual doping in 3C-SiC and show that, from typical low-temperature photoluminescence (LTPL) data, very simple estimates of the doping level can be made. Finally, we focus on aluminum doping in 4H-SiC. Performing a systematic comparison of LTPL spectra with secondary ion mass spectroscopy (SIMS) and/or capacitance-voltage measurements, we show that a reasonably good value of the residual (or intentional) doping level can be obtained from simple optical measurements. An interesting point is that, in many cases, the use of such optical techniques offers the non-negligible advantage to allow detection beyond the SIMS limit.

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“…17 Al has also a lower thermal ionization energy in 4H-SiC than B, about 200 meV 19 against about 600 meV. 20 Moreover, the Al ionization energy shows an important dependence on the Al acceptor concentration. 21 In the case of identical B and Al acceptor concentrations, such differences favor a higher p-type conductivity in the Al case because of its lower partial ionization at any sample temperature.…”

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

Fedeli

Gorni

Carnera

et al. 2016

ECS J. Solid State Sci. Technol.

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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 4H-SiC wafer with an implanted Al concentration lower than the Al solubility limit in 4H-SiC at the annealing temperature of 1950 • C. The annealing time was varied in the range 5-40 min.

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Photoluminescence and transport studies of boron in 4H SiC

Cited by 120 publications

References 38 publications

Theoretical evidence for the kick-out mechanism for B diffusion in SiC

Theoretical evidence for the kick-out mechanism for B diffusion in SiC

Application of LTPL Investigation Methods to CVD‐Grown SiC

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

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Photoluminescence and transport studies of boron in 4H SiC

Cited by 120 publications

References 38 publications

Theoretical evidence for the kick-out mechanism for B diffusion in SiC

Theoretical evidence for the kick-out mechanism for B diffusion in SiC

Application of LTPL Investigation Methods to CVD‐Grown SiC

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

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