Graphene-assisted spontaneous relaxation towards dislocation-free heteroepitaxy.
Sang-Hoon BaeKuangye LuYimo HanSungkyu KimKuan QiaoChanyeol ChoiYifan NieHyunseok KimHyun S KumPeng ChenWei KongBeom-Seok KangChansoo KimJaeyong LeeYongmin BaekJaewoo ShimJinhee ParkMinho JooDavid A MullerKyusang LeeJeehwan KimPublished in: Nature nanotechnology (2020)
Although conventional homoepitaxy forms high-quality epitaxial layers1-5, the limited set of material systems for commercially available wafers restricts the range of materials that can be grown homoepitaxially. At the same time, conventional heteroepitaxy of lattice-mismatched systems produces dislocations above a critical strain energy to release the accumulated strain energy as the film thickness increases. The formation of dislocations, which severely degrade electronic/photonic device performances6-8, is fundamentally unavoidable in highly lattice-mismatched epitaxy9-11. Here, we introduce a unique mechanism of relaxing misfit strain in heteroepitaxial films that can enable effective lattice engineering. We have observed that heteroepitaxy on graphene-coated substrates allows for spontaneous relaxation of misfit strain owing to the slippery graphene surface while achieving single-crystalline films by reading the atomic potential from the substrate. This spontaneous relaxation technique could transform the monolithic integration of largely lattice-mismatched systems by covering a wide range of the misfit spectrum to enhance and broaden the functionality of semiconductor devices for advanced electronics and photonics.