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| Format: | Preprint |
| Published: |
2021
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2112.05424 |
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| _version_ | 1866914128202825728 |
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| author | Wang, Yang |
| author_facet | Wang, Yang |
| contents | Large-area, single-crystalline antimonene polygonal domains self-assemble on Al(111) at room temperature without forming an interfacial alloy layer by MBE. Beyond the beta-Sb phase,with increasing deposition, once the beta-Sb coverage surpasses a threshold, we observe a previously unreported kagome-Sb overlayer. STM height maps and line profiles track a phase evolution from an enlarged-period honeycomb to a close-packed layer and ultimately a kagome lattice. XPS peak not only shows resolves a time-dependent redistribution of Sb-related components that quantitatively mirrors the STM-observed phase sequence, but also revals the substrate core levels remain unchanged, ruling out interfacial alloying throughout growth. ARPES of beta-Sb resolves a Dirac-like crossing at Gamma around -1.4 eV, in agreement with first-principles calculations. Although beta-Sb is Z2-trivial and the heterostructure is metallic, Wannier-based calculations reveal valley-contrasting Berry-curvature hotspots, yielding an intrinsic spin Hall conductivity that is strongly Fermi-level dependent. These results demonstrate a reproducible kagome-Sb/beta-Sb heterophase interface and uncover a controllable spin-orbit-driven response in a homoelemental 2D system. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2112_05424 |
| institution | arXiv |
| publishDate | 2021 |
| record_format | arxiv |
| spellingShingle | Kagome on beta-Sb with valley-hot Berry curvature and tunable intrinsic SHC Wang, Yang Materials Science Large-area, single-crystalline antimonene polygonal domains self-assemble on Al(111) at room temperature without forming an interfacial alloy layer by MBE. Beyond the beta-Sb phase,with increasing deposition, once the beta-Sb coverage surpasses a threshold, we observe a previously unreported kagome-Sb overlayer. STM height maps and line profiles track a phase evolution from an enlarged-period honeycomb to a close-packed layer and ultimately a kagome lattice. XPS peak not only shows resolves a time-dependent redistribution of Sb-related components that quantitatively mirrors the STM-observed phase sequence, but also revals the substrate core levels remain unchanged, ruling out interfacial alloying throughout growth. ARPES of beta-Sb resolves a Dirac-like crossing at Gamma around -1.4 eV, in agreement with first-principles calculations. Although beta-Sb is Z2-trivial and the heterostructure is metallic, Wannier-based calculations reveal valley-contrasting Berry-curvature hotspots, yielding an intrinsic spin Hall conductivity that is strongly Fermi-level dependent. These results demonstrate a reproducible kagome-Sb/beta-Sb heterophase interface and uncover a controllable spin-orbit-driven response in a homoelemental 2D system. |
| title | Kagome on beta-Sb with valley-hot Berry curvature and tunable intrinsic SHC |
| topic | Materials Science |
| url | https://arxiv.org/abs/2112.05424 |