Large-area integration of two-dimensional materials and their heterostructures by wafer bonding
Citation:
Quellmalz, A. and Wang, X. and Sawallich, S. and Uzlu, B. and Otto, M. and Wagner, S. and Wang, Z. and Prechtl, M. and Hartwig, O. and Luo, S. and Duesberg, G.S. and Lemme, M.C. and Gylfason, K.B. and Roxhed, N. and Stemme, G. and Niklaus, F., Large-area integration of two-dimensional materials and their heterostructures by wafer bonding, Nature Communications, 12, 1, 2021Download Item:
Abstract:
Integrating two-dimensional (2D) materials into semiconductor manufacturing lines is essential to exploit their material properties in a wide range of application areas. However, current approaches are not compatible with high-volume manufacturing on wafer level. Here, we report a generic methodology for large-area integration of 2D materials by adhesive wafer bonding. Our approach avoids manual handling and uses equipment, processes, and materials that are readily available in large-scale semiconductor manufacturing lines. We demonstrate the transfer of CVD graphene from copper foils (100-mm diameter) and molybdenum disulfide (MoS2) from SiO2/Si chips (centimeter-sized) to silicon wafers (100-mm diameter). Furthermore, we stack graphene with CVD hexagonal boron nitride and MoS2 layers to heterostructures, and fabricate encapsulated field-effect graphene devices, with high carrier mobilities of up to 4520cm2V−1s−1. Thus, our approach is suited for backend of the line integration of 2D materials on top of integrated circuits, with potential to accelerate progress in electronics, photonics, and sensing. © 2021, The Author(s).
Author's Homepage:
http://people.tcd.ie/duesberg
Author: Duesberg, Georg
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Nature Communications12
1
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Full text availableDOI:
http://dx.doi.org/10.1038/s41467-021-21136-0Metadata
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