Concentration, chemical bonding, and etching behavior of P and N at the SiO2/SiC(0001) interface

Xu, Yi; Xu, Can; Liu, Gang; Lee, H. D.; Shubeita, S. M.; Jiao, C.; Modic, Aaron; Ahyi, A. C.; Sharma, Yogesh; Wan, A.; Williams, John R.; Gustafsson, T.; Dhar, Sarit; Garfunkel, Eric; Feldman, L. C.

doi:10.1063/1.4937400

Cited by 8 publications

(8 citation statements)

References 38 publications

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“…The trap passivation mechanism by phosphorus is only partially understood. It has been reported that, at the interface as well as in the bulk PSG layer, P is primarily bound to O atoms, which are themselves bonded to Si or C atoms [46]. This suggests that the trap passivation mechanism due to P may be related to re-arranging the critical interfacial dielectric layer, relieving interface stress and possibly allowing better passivation of the dangling bonds [46].…”

Section: Resultsmentioning

confidence: 99%

“…It has been reported that, at the interface as well as in the bulk PSG layer, P is primarily bound to O atoms, which are themselves bonded to Si or C atoms [46]. This suggests that the trap passivation mechanism due to P may be related to re-arranging the critical interfacial dielectric layer, relieving interface stress and possibly allowing better passivation of the dangling bonds [46]. Accordingly, the effect of phosphorus on near-interface traps can be summarized by the following theories reported in the literature: (1) the P atoms act as a network former and result in reconstruction of the oxide network in SiO 2 (Si-Si bonds elimination) [26,28,46] (2) C related defects are removed by the P doping of SiO 2 [28,[47][48][49] where threefold carbon atoms at the interface are replaced by a P=O group [28].…”

Section: Resultsmentioning

confidence: 99%

“…This suggests that the trap passivation mechanism due to P may be related to re-arranging the critical interfacial dielectric layer, relieving interface stress and possibly allowing better passivation of the dangling bonds [46]. Accordingly, the effect of phosphorus on near-interface traps can be summarized by the following theories reported in the literature: (1) the P atoms act as a network former and result in reconstruction of the oxide network in SiO 2 (Si-Si bonds elimination) [26,28,46] (2) C related defects are removed by the P doping of SiO 2 [28,[47][48][49] where threefold carbon atoms at the interface are replaced by a P=O group [28]. In this regard, it has been reported recently that POCl 3 annealing can form a peculiar -O 3 PO structure which can act as a carbon absorber [48,49] For the Si interstitial (Si i ), it should be noted that this defect has a complex structure consisting of several electrically active centers: two Si-Si bonds, one threefold oxygen, and one five-fold Si [15].…”

Section: Resultsmentioning

confidence: 99%

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Mechanism of phosphorus passivation of near-interface oxide traps in 4H–SiC MOS devices investigated by CCDLTS and DFT calculation

Jayawardena

Shen

Mooney

et al. 2018

Semicond. Sci. Technol.

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Interfacial charge trapping in 4H-SiC MOS capacitors with P doped SiO 2 or phospho-silicate glass (PSG) as a gate dielectric has been investigated with temperature dependent capacitance-voltage measurements and constant capacitance deep level transient spectroscopy (CCDLTS) measurements. The measurements indicate that P doping in the dielectric results in significant reduction of near-interface electron traps that have energy levels within 0.5 eV of the 4H-SiC conduction band edge. Extracted trap densities confirm that the phosphorus induced near-interface trap reduction is significantly more effective than interfacial nitridation, which is typically used for 4H-SiC MOSFET processing. The CCDLTS measurements reveal that the two broad near-interface trap peaks, named 'O1' and 'O2', with activation energies around 0.15 eV and 0.4 eV below the 4H-SiC conduction band that are typically observed in thermal oxides on 4H-SiC, are also present in PSG devices. Previous atomic scale ab initio calculations suggested these O1 and O2 traps to be carbon dimers substituted for oxygen dimers (C O =C O ) and interstitial Si (Si i ) in SiO 2 , respectively. Theoretical considerations in this work suggest that the presence of P in the near-interfacial region reduces the stability of the C O =C O defects and reduces the density of Si i defects through the network restructuring. Qualitative comparison of results in this work and reported work suggest that the O1 and O2 traps in SiO 2 /4H-SiC MOS system negatively impact channel mobility in 4H-SiC MOSFETs.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Mechanism of phosphorus passivation of near-interface oxide traps in 4H–SiC MOS devices investigated by CCDLTS and DFT calculation

Jayawardena

Shen

Mooney

et al. 2018

Semicond. Sci. Technol.

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“…Nitrogen (N) acts as an n-type dopant in SiC, and after N 2 O annealing there may be some counter doping of the pdoped regions (created by aluminium dopants) by N [15,16] . These p regions are used underneath the Schottky contact in the termination region.…”

Section: Resultsmentioning

confidence: 99%

Impact of design and process variation on the fabrication of SiC diodes

et al. 2018

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We have studied the influence of design and process variations on the electrical performance of SiC Schottky diodes. On the design side, two design variations are used in the active cell of the diode (segment design and stripe design). In addition, there are two more design variations employed for the edge termination layout of the diodes, namely, field limiting ring (FLR) and junction termination extension (JTE). On the process side, some diodes have gone through an N 2 O annealing step. The segment design resulted in a lower forward voltage drop (V F ) in the diodes and the FLR design turned out to be a better choice for blocking voltages, in the reverse bias. Also, N 2 O annealing has shown a detrimental effect on the diodes' blocking performance, which have JTE as their termination design. It degrades the blocking capability of the diodes significantly.

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“…For example, this polarize charge can change a "normally-off" device to a "normally-on" device. X-ray photoelectron spectroscopy (XPS) results [34,35] reveal that PSG layers cannot be removed completely by etching in BOE if is grown on 4H-SiC while opposite is true for the layer grown on Si. After BOE etching in the case of SiC, a 2-3-nm Si-C-O-P interfacial layer can still be seen which is equivalent to a phosphorous areal density of 2 × 10 .…”

Section: Etched Psg Processmentioning

confidence: 99%

Advanced SiC/Oxide Interface Passivation

Sharma¹

2017

New Research on Silicon - Structure, Properties, Technology

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To save energy on an electric power grid, the idea of redesigned 'micro-grids' has been proposed. Implementation of this concept needs power devices that can operate at higher switching speeds and block voltages of up to 20 kV. Out of SiC and GaN wide band gap semiconductors, the former is more suitable for low-as well as high-voltage ranges. SiC exists in different polytypes 3C-, 4H-and 6H-. 4H-SiC due to its wider band gap, 3.26 eV has higher critical electric field of breakdown (E c ) and electron bulk mobility compared to 6H-SiC. Even with all these benefits 4H-SiC full potential has not yet been realized. This is due to high trap densities (D it ) at the interface. In addition to 4H-polytype, in recent years, there is a reignited interest on cubic silicon carbide (3C-SiC), which can be potentially grown heteroepitaxially on 12″ Si substrates, as it would result in a drastic cost reduction of semiconductor devices compared to the successful but exorbitantly expensive SiC hexagonal polytype technology (4H-SiC). In this chapter, we discuss and summarize all different interface passivation techniques or processes that have led to a vast improvement of these (4H-or 3C-SiC/SiO 2 ) interfaces electrically.

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Concentration, chemical bonding, and etching behavior of P and N at the SiO2/SiC(0001) interface

Cited by 8 publications

References 38 publications

Mechanism of phosphorus passivation of near-interface oxide traps in 4H–SiC MOS devices investigated by CCDLTS and DFT calculation

Mechanism of phosphorus passivation of near-interface oxide traps in 4H–SiC MOS devices investigated by CCDLTS and DFT calculation

Impact of design and process variation on the fabrication of SiC diodes

Advanced SiC/Oxide Interface Passivation

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