We propose a new approach to improve the quality and to reduce stress: it is necessary to modify the structure of the substrate (compliance substrate) in order to force the system to reduce the defects while increasing the thickness of the layer.

Furthermore, by using the typical bulk growth techniques used for 4H-SiC it is possible to grow bulk 3C-SiC wafers, improving considerably the quality of the material.
Currently silicon is the material of choice for power electronic applications where the inevitable power dissipation requires the use of very heavy and expensive heat sinks. The purpose of these undesirable heat sinks is to manage the device junction temperature, allowing operation in the range where Si devices are able to function. The reason is simple - the low Si band-gap.

The best alternative for these applications is 3C-SiC.

Our Workplan

our steps to sustainable wide-band-gap power devices

Compliance Substrates

Geometric design and modelling of wafer patterning, minimizing residual thermal strain and wafer bowing

Chemical Vapour Deposition

Optimization of epitaxial growth processes of 3C-SiC

Bulk Process for the Production of Wafer

Growth of real bulk size 3C-SiC crystals with a thickness of several mm

Device Demonstrators

Device concepts with potential for operation in high temperature and high radiation environments

Highlights

stay updated with the project progresses

CHALLENGE presented at the 2021 European Conference on Silicon Carbide and Related Materials!

3 CHALLENGE Researchers as invited speakers at the ESCRM 2021

READ

Technology Computer Aided Design of SiC materials growth processes

Last but not least - Fourth event of our May webinar series on 3C- SiC.

READ

Compliant and disposable substrate for 3C-SiC heteroepitaxy by deep pillar patterning

Third event of our May webinar series on 3C- SiC .

READ
more news

LATEST PUBLICATIONS

MDPI - Materials 2021

New Approaches and Understandings in the Growth of Cubic Silicon Carbide

See article

READ ABSTRACT

MDPI - Materials 2021

Effect of Nitrogen and Aluminum Doping on 3C-SiC Heteroepitaxial Layers Grown on 4° Off-Axis Si (100)

Calabretta, C.; Scuderi, V.; Anzalone, R.; Mauceri, M.; Crippa, D.; Cannizzaro, A.; Boninelli, S.; La Via, F.

READ ABSTRACT

Acta Materialia

Extended Defects in 3C-SiC: Stacking Faults, Threading Partial Dislocations, and Inverted Domain Boundaries

Massimo Zimbone, Andrey Sarikov, Corrado Bongiorno, Anna Marzegalli, Viviana Scuderi, Cristiano Calabretta, Leo Miglio, Francesco La Via

READ ABSTRACT

Crystal, Growth and Design

Overgrowth of Protrusion Defects during Sublimation Growth of Cubic Silicon Carbide Using Free-Standing Cubic Silicon Carbide Substrates

Michael Schöler, Francesco La Via, Marco Mauceri, Peter Wellmann

READ ABSTRACT
more publications

COORDINATOR

CNR

Consiglio Nazionale delle ricerche

Italy

PARTICIPANTS

Anvil

Anvil Semiconductors LTD

United Kingdom

Ascatron

Ascatron AB

Sweden

Cusic

Cusic INC.

Japan

FAU

Friedrich-Alexander University

Germany

IBS

ION Beam Services

France

L.P.E.

L.P.E. Spa

Italy

LIU

Linkopings Universitet

Sweden

Moverim

Moverim Consulting SPRL

Belgium

NOVASiC

NOVASiC SA

France

Silvaco

Silvaco Europe LTD

United Kingdom

ST

Stmicroelectronics SRL

Italy

SU

Swansea University

United Kingdom

Bicocca

Università degli studi di Milano - Bicocca

Italy

Warwick

University of Warwick

United Kingdom

follow us on

How to contact us

CHALLENGE project - 3C-SiC Hetero-epitaxiALLy grown on silicon compliancE substrates and 3C-SiC substrates for sustaiNable wide-band-Gap powEr devices - has received funding from the EU's H2020 framework programme for research and innovation under grant agreement n. 720827 from 1/1/2017 to 31/12/2020.

Funded under: H2020-EU.2.1.3. - INDUSTRIAL LEADERSHIP - Leadership in enabling and industrial technologies - Advanced materials

for more information info@h2020challenge.eu
privacy & cookies
Designed by promoscience
LEFT CONTENT WILL BE LOADED HERE
RIGHT CONTENT WILL BE LOADED HERE