Sodium-Induced Reordering of Atomic Stacks in Black Phosphorus

Yingchun Cheng; Yihan Zhu; Yu Han; Zhongyuan Liu; Bingchao Yang; Anmin Nie; Wei Huang; Reza Shahbazian-Yassar; Farzad Mashayek

doi:10.1021/acs.chemmater.6b05052

Sodium-Induced Reordering of Atomic Stacks in Black Phosphorus

Yingchun Cheng, Yihan Zhu, Yu Han, Zhongyuan Liu, Bingchao Yang, Anmin Nie, Wei Huang, Reza Shahbazian-Yassar, Farzad Mashayek

Research output: Contribution to journal › Article › peer-review

56 Scopus citations

Abstract

While theoretical simulations predict contradictory results about how the intercalation of foreign metal atoms affects the order of atomic layers in black phosphorus (BP), no direct experimental visualization work has yet clarified this ambiguity. By in situ electrochemical sodiation of BP inside a high-resolution transmission electron microscope and first-principles calculations, we found that sodium intercalation induces a relative glide of¹/₂ ⟨010⟩ {001}, resulting in reordering of atomic stacks from AB to AC in BP. The observed local amorphization in our experiments is triggered by lattice constraints. We predict that intercalation of sodium or other metal atoms introduces n-type carriers in BP. This potentially opens a new field for two-dimensional electronics based on BP.

Original language	English
Pages (from-to)	1350-1356
Number of pages	7
Journal	Chemistry of Materials
Volume	29
Issue number	3
DOIs	https://doi.org/10.1021/acs.chemmater.6b05052
State	Published - 14 Feb 2017
Externally published	Yes

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title = "Sodium-Induced Reordering of Atomic Stacks in Black Phosphorus",

abstract = "While theoretical simulations predict contradictory results about how the intercalation of foreign metal atoms affects the order of atomic layers in black phosphorus (BP), no direct experimental visualization work has yet clarified this ambiguity. By in situ electrochemical sodiation of BP inside a high-resolution transmission electron microscope and first-principles calculations, we found that sodium intercalation induces a relative glide of1/2 ⟨010⟩ {001}, resulting in reordering of atomic stacks from AB to AC in BP. The observed local amorphization in our experiments is triggered by lattice constraints. We predict that intercalation of sodium or other metal atoms introduces n-type carriers in BP. This potentially opens a new field for two-dimensional electronics based on BP.",

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AU - Cheng, Yingchun

AU - Zhu, Yihan

AU - Han, Yu

AU - Liu, Zhongyuan

AU - Yang, Bingchao

AU - Nie, Anmin

AU - Huang, Wei

AU - Shahbazian-Yassar, Reza

AU - Mashayek, Farzad

PY - 2017/2/14

Y1 - 2017/2/14

N2 - While theoretical simulations predict contradictory results about how the intercalation of foreign metal atoms affects the order of atomic layers in black phosphorus (BP), no direct experimental visualization work has yet clarified this ambiguity. By in situ electrochemical sodiation of BP inside a high-resolution transmission electron microscope and first-principles calculations, we found that sodium intercalation induces a relative glide of1/2 ⟨010⟩ {001}, resulting in reordering of atomic stacks from AB to AC in BP. The observed local amorphization in our experiments is triggered by lattice constraints. We predict that intercalation of sodium or other metal atoms introduces n-type carriers in BP. This potentially opens a new field for two-dimensional electronics based on BP.

AB - While theoretical simulations predict contradictory results about how the intercalation of foreign metal atoms affects the order of atomic layers in black phosphorus (BP), no direct experimental visualization work has yet clarified this ambiguity. By in situ electrochemical sodiation of BP inside a high-resolution transmission electron microscope and first-principles calculations, we found that sodium intercalation induces a relative glide of1/2 ⟨010⟩ {001}, resulting in reordering of atomic stacks from AB to AC in BP. The observed local amorphization in our experiments is triggered by lattice constraints. We predict that intercalation of sodium or other metal atoms introduces n-type carriers in BP. This potentially opens a new field for two-dimensional electronics based on BP.

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Sodium-Induced Reordering of Atomic Stacks in Black Phosphorus

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