Band-Gap Landscape Engineering in Large-Scale 2D Semiconductor van der Waals Heterostructures

We present a growth process relying on pulsed laser deposition for the elaboration of complex van der Waals heterostructures on large scales, at a 400 °C CMOS-compatible temperature. Illustratively, we define a multilayer quantum well geometry through successive in situ growths, leading to WSe2 bein...

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Veröffentlicht in:ACS nano 2021-04, Vol.15 (4), p.7279-7289
Hauptverfasser: Zatko, Victor, Dubois, Simon Mutien-Marie, Godel, Florian, Carrétéro, Cécile, Sander, Anke, Collin, Sophie, Galbiati, Marta, Peiro, Julian, Panciera, Federico, Patriarche, Gilles, Brus, Pierre, Servet, Bernard, Charlier, Jean-Christophe, Martin, Marie-Blandine, Dlubak, Bruno, Seneor, Pierre
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Sprache:eng
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Zusammenfassung:We present a growth process relying on pulsed laser deposition for the elaboration of complex van der Waals heterostructures on large scales, at a 400 °C CMOS-compatible temperature. Illustratively, we define a multilayer quantum well geometry through successive in situ growths, leading to WSe2 being encapsulated into WS2 layers. The structural constitution of the quantum well geometry is confirmed by Raman spectroscopy combined with transmission electron microscopy. The large-scale high homogeneity of the resulting 2D van der Waals heterostructure is also validated by macro- and microscale Raman mappings. We illustrate the benefit of this integrative in situ approach by showing the structural preservation of even the most fragile 2D layers once encapsulated in a van der Waals heterostructure. Finally, we fabricate a vertical tunneling device based on these large-scale layers and discuss the clear signature of electronic transport controlled by the quantum well configuration with ab initio calculations in support. The flexibility of this direct growth approach, with multilayer stacks being built in a single run, allows for the definition of complex 2D heterostructures barely accessible with usual exfoliation or transfer techniques of 2D materials. Reminiscent of the III–V semiconductors’ successful exploitation, our approach unlocks virtually infinite combinations of large 2D material families in any complex van der Waals heterostructure design.
ISSN:1936-0851
1936-086X
DOI:10.1021/acsnano.1c00544