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Main Authors: Tsuji, Takeyuki, Harada, Shunta, Teraji, Tokuyuki
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.00261
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author Tsuji, Takeyuki
Harada, Shunta
Teraji, Tokuyuki
author_facet Tsuji, Takeyuki
Harada, Shunta
Teraji, Tokuyuki
contents Dislocations are fundamental crystal defects whose stress fields govern a wide range of material properties. The analytical form of the stress tensor around single dislocation was established by elasticity theory more than 80 years ago and has provided a theoretical basis for evaluating essential characteristics of dislocations. However, direct experimental verification has long remained out of reach because it has been difficult to measure the components of the stress tensor with conventional methods. Here, we present the experimental visualization of the stress tensor around single dislocation in diamond. Using quantum sensors based on nitrogen-vacancy (NV) centers, we mapped the shear components ($σ_{xy}$, $σ_{yz}$, $σ_{zx}$) together with the trace of the stress tensor ($σ_{xx}+σ_{yy}+σ_{zz}$) around single 45° dislocation. The observed distributions exhibited good agreement with predictions from elasticity theory, thus providing experimental validation of this theoretical framework.
format Preprint
id arxiv_https___arxiv_org_abs_2601_00261
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Direct imaging of stress tensor around single dislocation in diamond
Tsuji, Takeyuki
Harada, Shunta
Teraji, Tokuyuki
Materials Science
Dislocations are fundamental crystal defects whose stress fields govern a wide range of material properties. The analytical form of the stress tensor around single dislocation was established by elasticity theory more than 80 years ago and has provided a theoretical basis for evaluating essential characteristics of dislocations. However, direct experimental verification has long remained out of reach because it has been difficult to measure the components of the stress tensor with conventional methods. Here, we present the experimental visualization of the stress tensor around single dislocation in diamond. Using quantum sensors based on nitrogen-vacancy (NV) centers, we mapped the shear components ($σ_{xy}$, $σ_{yz}$, $σ_{zx}$) together with the trace of the stress tensor ($σ_{xx}+σ_{yy}+σ_{zz}$) around single 45° dislocation. The observed distributions exhibited good agreement with predictions from elasticity theory, thus providing experimental validation of this theoretical framework.
title Direct imaging of stress tensor around single dislocation in diamond
topic Materials Science
url https://arxiv.org/abs/2601.00261