Abstract
A common characteristic of borophene polymorphs is the presence of hollow hexagons (HHs) in an otherwise triangular lattice. The vast number of possible HH arrangements underlies the polymorphic nature of borophene, and necessitates direct HH imaging to definitively identify its atomic structure. While borophene has been imaged with scanning tunneling microscopy using conventional metal probes, the convolution of topographic and electronic features hinders unambiguous identification of the atomic lattice. Here, we overcome these limitations by employing CO-functionalized atomic force microscopy to visualize structures corresponding to boron-boron covalent bonds. Additionally, we show that CO-functionalized scanning tunneling microscopy is an equivalent and more accessible technique for HH imaging, confirming the v1/5 and v1/6 borophene models as unifying structures for all observed phases. Using this methodology, a borophene phase diagram is assembled, including a transition from rotationally commensurate to incommensurate phases at high growth temperatures, thus corroborating the chemically discrete nature of borophene.
Highlights
A common characteristic of borophene polymorphs is the presence of hollow hexagons (HHs) in an otherwise triangular lattice
In an extension of this methodology, we show here that cryogenic ultrahigh vacuum non-contact CO-functionalized atomic force microscopy (CO-AFM) geometrically resolves features that are consistent with boron-boron covalent bonds
We further demonstrate that CO-functionalized scanning tunneling microscopy (STM) (CO-STM)[22] resolves borophene HHs and provides equivalently unambiguous geometric identification of borophene atomic lattice structures in a manner that is experimentally less demanding
Summary
A common characteristic of borophene polymorphs is the presence of hollow hexagons (HHs) in an otherwise triangular lattice. We further demonstrate that CO-functionalized STM (CO-STM)[22] resolves borophene HHs and provides equivalently unambiguous geometric identification of borophene atomic lattice structures in a manner that is experimentally less demanding.
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