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Main Authors: Gallardo, Valentina, Arce, Barbara, Muñoz, Francisco, Martín, Rodolfo San, Zubritskaya, Irina, Giraldo-Gallo, Paula, Manoharan, Hari, Parra, Carolina
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.10280
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author Gallardo, Valentina
Arce, Barbara
Muñoz, Francisco
Martín, Rodolfo San
Zubritskaya, Irina
Giraldo-Gallo, Paula
Manoharan, Hari
Parra, Carolina
author_facet Gallardo, Valentina
Arce, Barbara
Muñoz, Francisco
Martín, Rodolfo San
Zubritskaya, Irina
Giraldo-Gallo, Paula
Manoharan, Hari
Parra, Carolina
contents There is great interest in the study of topological insulator-based heterostructures due to expected emerging phenomena. However, a challenge of topological insulator (TI) research is the contribution of the bulk conduction to the TI surface states. Both strain engineering and thickness control routes, which have been proposed to compensate for bulk doping, can be accessed through the use of nano-heterostructures consisting of topological insulator nanostructures grown on 2D materials. In this work, we report the synthesis of TI/graphene nano-heterostructures based on Bi2Te3 and Sb2Te3 nanoplatelets (NPs) grown on single-layer graphene. Various techniques were used to characterize this system in terms of morphology, thickness, composition, and crystal quality. We found that most of the obtained NPs are mainly < 20 [nm] thick with thickness-dependent crystal quality, observed by Raman measurements. Thinner NPs (1 or 2 QL) tend to replicate the topography of the underlying SLG, according to roughness analysis, and observed buckling features. Finally, we show preliminary studies of their band structure obtained by LT-STM (STS) and by DFT. We observe a highly negative doping which can be attributed to the presence of defects.
format Preprint
id arxiv_https___arxiv_org_abs_2312_10280
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Exploring Structural and Electronic Properties of Topological Insulator/Graphene Nano-heterostructures
Gallardo, Valentina
Arce, Barbara
Muñoz, Francisco
Martín, Rodolfo San
Zubritskaya, Irina
Giraldo-Gallo, Paula
Manoharan, Hari
Parra, Carolina
Mesoscale and Nanoscale Physics
There is great interest in the study of topological insulator-based heterostructures due to expected emerging phenomena. However, a challenge of topological insulator (TI) research is the contribution of the bulk conduction to the TI surface states. Both strain engineering and thickness control routes, which have been proposed to compensate for bulk doping, can be accessed through the use of nano-heterostructures consisting of topological insulator nanostructures grown on 2D materials. In this work, we report the synthesis of TI/graphene nano-heterostructures based on Bi2Te3 and Sb2Te3 nanoplatelets (NPs) grown on single-layer graphene. Various techniques were used to characterize this system in terms of morphology, thickness, composition, and crystal quality. We found that most of the obtained NPs are mainly < 20 [nm] thick with thickness-dependent crystal quality, observed by Raman measurements. Thinner NPs (1 or 2 QL) tend to replicate the topography of the underlying SLG, according to roughness analysis, and observed buckling features. Finally, we show preliminary studies of their band structure obtained by LT-STM (STS) and by DFT. We observe a highly negative doping which can be attributed to the presence of defects.
title Exploring Structural and Electronic Properties of Topological Insulator/Graphene Nano-heterostructures
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2312.10280