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Fysik & material 3.3

Scientists map path to better graphene chips for power electronics

Researchers have identified how to control the electrical barrier at graphene-silicon carbide interfaces, a key step toward commercial high-power electronics. The breakthrough could enable a single material to perform multiple roles in future devices, reducing manufacturing complexity and costs for industries from automotive to renewable energy.

Originaltitel: Role of the Potential Barrier in the Electrical Performance of the Graphene/SiC Interface

Abstrakt

<p>In spite of the great expectations for epitaxial graphene (EG) on silicon carbide (SiC) to be used as a next-generation high-performance component in high-power nano- and micro-electronics, there are still many technological challenges and fundamental problems that hinder the full potential of EG/SiC structures and that must be overcome. Among the existing problems, the quality of the graphene/SiC interface is one of the most critical factors that determines the electroactive behavior of this heterostructure. This paper reviews the relevant studies on the carrier transport through the graphene/SiC, discusses qualitatively the possibility of controllable tuning the potential barrier height at the heterointerface and analyses how the buffer layer formation affects the electronic properties of the combined EG/SiC system. The correlation between the sp(2)/sp(3) hybridization ratio at the interface and the barrier height is discussed. We expect that the barrier height modulation will allow realizing a monolithic electronic platform comprising different graphene interfaces including ohmic contact, Schottky contact, gate dielectric, the electrically-active counterpart in p-n junctions and quantum wells.</p>

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