Non-epitaxial single-crystal 2D material growth by geometric confinement.
Ki Seok KimDoyoon LeeCelesta S ChangSeunghwan SeoYaoqiao HuSoonyoung ChaHyunseok KimJiho ShinJu-Hee LeeSangho LeeJustin S KimKi Hyun KimJun Min SuhYuan MengBo-In ParkJung-Hoon LeeHyung-Sang ParkHyun S KumMoon Ho JoGeun Young YeomKyeongjae ChoJin-Hong ParkSang-Hoon BaeJeehwan KimPublished in: Nature (2023)
Two-dimensional (2D) materials and their heterostructures show a promising path for next-generation electronics 1-3 . Nevertheless, 2D-based electronics have not been commercialized, owing mainly to three critical challenges: i) precise kinetic control of layer-by-layer 2D material growth, ii) maintaining a single domain during the growth, and iii) wafer-scale controllability of layer numbers and crystallinity. Here we introduce a deterministic, confined-growth technique that can tackle these three issues simultaneously, thus obtaining wafer-scale single-domain 2D monolayer arrays and their heterostructures on arbitrary substrates. We geometrically confine the growth of the first set of nuclei by defining a selective growth area via patterning SiO 2 masks on two-inch substrates. Owing to substantial reduction of the growth duration at the micrometre-scale SiO 2 trenches, we obtain wafer-scale single-domain monolayer WSe 2 arrays on the arbitrary substrates by filling the trenches via short growth of the first set of nuclei, before the second set of nuclei is introduced, thus without requiring epitaxial seeding. Further growth of transition metal dichalcogenides with the same principle yields the formation of single-domain MoS 2 /WSe 2 heterostructures. Our achievement will lay a strong foundation for 2D materials to fit into industrial settings.