Plasma Treatment after NiSi-Based Ohmic Contact Formation on 4H-SiC to Enhance Adhesion of Subsequent Backside Metallization

Tom Becker; Carsten Hellinger; Alesa Fuchs; Julien Koerfer; Oleg Rusch

doi:10.4028/p-t2sWXi

Paper Titles

Prediction of Contact Resistance of 4H–SiC by Machine Learning Using Optical Microscope Images after Laser Doping
p.53

The Effect of Nitrogen Plasma Treatment Process on Ohmic Contact Formation to N-Type 4H-SiC
p.59

Ni/4H-SiC Ohmic Contact Formation Using Multipulse Nanosecond Laser Annealing
p.65

Lift-Off Process for Patterning of a Sputter-Deposited Thick Metal Stack for High Temperature Applications on 4H-SiC
p.71

Plasma Treatment after NiSi-Based Ohmic Contact Formation on 4H-SiC to Enhance Adhesion of Subsequent Backside Metallization
p.79

Effect of Substrate Heating on Low Contact-Resistance Formation by Excimer Laser Doping for 4H-SiC
p.85

Nickel Ohmic Contacts Formed on 4H-SiC by UV Laser Annealing
p.91

Electrical and Structural Properties of Ohmic Contacts of SiC Diodes Fabricated on Thin Wafers
p.97

Empirical Model of Low-Ohmic Nickel-Based Contact Formation on N-Type 4H-SiC Depending on Thermal Budget
p.105

HomeSolid State PhenomenaSolid State Phenomena Vol. 359Plasma Treatment after NiSi-Based Ohmic Contact...

Plasma Treatment after NiSi-Based Ohmic Contact Formation on 4H-SiC to Enhance Adhesion of Subsequent Backside Metallization

Abstract:

To achieve low on-resistance in any vertical 4H-SiC semiconductor power device, it is essential to create a suitable ohmic contact on the corresponding n-doped SiC substrate. In particular after wafer thinning, a common technology to reduce substrate resistivity, laser annealing for ohmic contact formation on the wafer backside is the only option due to temperature sensitive materials (such as Titanium or Aluminum) on the partially or fully processed wafer frontside. In this work, to solve adhesion issues of the backside metallization, plasma treatments, as easy to integrate process steps, were examined. By stripping obstructive carbon layers, formed after ohmic contact laser annealing, and without damaging the wafer frontside, an enhanced adhesion of following metallization layers was achieved. Both O₂- and H₂-plasma processes were investigated and demonstrated significant improvements to the adhesion of metallization stacks on the wafer backside compared to untreated surfaces and without drawbacks in the ohmic contact quality.

By email View Pdf

You might also be interested in these eBooks

20th International Conference on Silicon Carbide and Related Materials (ICSCRM 2023)

View Preview

View Preview

Info:

Periodical:

Solid State Phenomena (Volume 359)

Pages:

79-84

DOI:

https://doi.org/10.4028/p-t2sWXi

Citation:

Cite this paper

Online since:

August 2024

Authors:

Tom Becker*, Carsten Hellinger, Alesa Fuchs, Julien Koerfer, Oleg Rusch

Keywords:

4H-SiC, Adhesion, Laser Annealing, Nickel Silicide Metallization, Ohmic Contact

Export:

RIS, BibTeX

Permissions:

Creative Commons CC BY 4.0

Citation:

* - Corresponding Author

References

[1] F. Roccaforte, F. La Via, V. Raineri, Ohmic Contacs to SiC, Int. J. Hi. Spe. Ele. Syst. 15 (2005) 781–820.

DOI: 10.1142/s0129156405003429

Google Scholar

[2] T. Kimoto, J.A. Cooper, Fundamentals of silicon carbide technology: Growth, characterization, devices and applications, Wiley, Singapore, 2014.

Google Scholar

[3] C. Hellinger, Empirisches Modell zur Bildung von nickelbasierten Ohmkontakten auf n-Typ 4H-SiC durch Laserbearbeitung. Doctoralthesis, 2023.

Google Scholar

[4] C. Hellinger, et al., Empirical model of backside low-ohmic nickel contact formation on n-type 4H-SiC, submitted to Material Science Forum 2024 (2023).

Google Scholar

[5] C. Hellinger, et al., Laser annealing induced formation of low-ohmic nickel contacts on n-type 4H-SiC by surface roughness dependent laser fluence optimization, submitted to Material Science Forum 2024 (2023).

Google Scholar

[6] G. Li, M. Xu, D. Zou, Y. Cui, Y. Zhong, P. Cui, K.Y. Cheong et al., Fabrication of Ohmic Contact on N-Type SiC by Laser Annealed Process: A Review, Crystals 13 (2023) 1106.

DOI: 10.3390/cryst13071106

Google Scholar

[7] A. May, et al., A 4H-SiC CMOS Technology enabling Sensor and Circuit Operation above 500 °C, submitted to IEEE Sensors 2023 (2023).

Google Scholar