The Role of Delocalized Chemical Bonding in Square-Net-Based Topological Semimetals

Sebastian Klemenz; Aurland K. Hay; Samuel M.L. Teicher; Andreas Topp; Jennifer Cano; Leslie M. Schoop

doi:10.1021/jacs.0c01227

The Role of Delocalized Chemical Bonding in Square-Net-Based Topological Semimetals

Sebastian Klemenz
, Aurland K. Hay
, Samuel M.L. Teicher
, Andreas Topp
, Jennifer Cano
, Leslie M. Schoop

Physics and Astronomy

Princeton University
Wellesley College
University of California at Santa Barbara
Max Planck Institute for Solid State Research

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

77 Scopus citations

Abstract

Principles that predict reactions or properties of materials define the discipline of chemistry. In this work, we derive chemical rules, based on atomic distances and chemical bond character, which predict topological materials in compounds that feature the structural motif of a square-net. Using these rules, we identify over 300 potential new topological materials. We show that simple chemical heuristics can be a powerful tool to characterize topological matter. In contrast to previous database-driven materials' categorization, our approach allows us to identify candidates that are alloys, solid-solutions, or compounds with statistical vacancies. While previous material searches relied on density functional theory, our approach is not limited by this method and could also be used to discover magnetic and statistically disordered topological semimetals.

Original language	English
Pages (from-to)	6350-6359
Number of pages	10
Journal	Journal of the American Chemical Society
Volume	142
Issue number	13
DOIs	https://doi.org/10.1021/jacs.0c01227
State	Published - Apr 1 2020

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title = "The Role of Delocalized Chemical Bonding in Square-Net-Based Topological Semimetals",

abstract = "Principles that predict reactions or properties of materials define the discipline of chemistry. In this work, we derive chemical rules, based on atomic distances and chemical bond character, which predict topological materials in compounds that feature the structural motif of a square-net. Using these rules, we identify over 300 potential new topological materials. We show that simple chemical heuristics can be a powerful tool to characterize topological matter. In contrast to previous database-driven materials' categorization, our approach allows us to identify candidates that are alloys, solid-solutions, or compounds with statistical vacancies. While previous material searches relied on density functional theory, our approach is not limited by this method and could also be used to discover magnetic and statistically disordered topological semimetals.",

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AU - Topp, Andreas

AU - Cano, Jennifer

AU - Schoop, Leslie M.

PY - 2020/4/1

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N2 - Principles that predict reactions or properties of materials define the discipline of chemistry. In this work, we derive chemical rules, based on atomic distances and chemical bond character, which predict topological materials in compounds that feature the structural motif of a square-net. Using these rules, we identify over 300 potential new topological materials. We show that simple chemical heuristics can be a powerful tool to characterize topological matter. In contrast to previous database-driven materials' categorization, our approach allows us to identify candidates that are alloys, solid-solutions, or compounds with statistical vacancies. While previous material searches relied on density functional theory, our approach is not limited by this method and could also be used to discover magnetic and statistically disordered topological semimetals.

AB - Principles that predict reactions or properties of materials define the discipline of chemistry. In this work, we derive chemical rules, based on atomic distances and chemical bond character, which predict topological materials in compounds that feature the structural motif of a square-net. Using these rules, we identify over 300 potential new topological materials. We show that simple chemical heuristics can be a powerful tool to characterize topological matter. In contrast to previous database-driven materials' categorization, our approach allows us to identify candidates that are alloys, solid-solutions, or compounds with statistical vacancies. While previous material searches relied on density functional theory, our approach is not limited by this method and could also be used to discover magnetic and statistically disordered topological semimetals.

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The Role of Delocalized Chemical Bonding in Square-Net-Based Topological Semimetals

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