Bulk transport paths through defects in floating zone and Al flux grown SmB6

Yun Suk Eo; Alexa Rakoski; Shriya Sinha; Dmitri Mihaliov; Wesley T. Fuhrman; Shanta R. Saha; Priscila F.S. Rosa; Zachary Fisk; Monica Ciomaga Hatnean; Geetha Balakrishnan; Juan R. Chamorro; W. Adam Phelan; Seyed M. Koohpayeh; Tyrel M. McQueen; Boyoun Kang; Myung Suk Song; Beongki Cho; Michael S. Fuhrer; Johnpierre Paglione; Çaǧllyan Kurdak

doi:10.1103/PhysRevMaterials.5.055001

Bulk transport paths through defects in floating zone and Al flux grown SmB6

Yun Suk Eo, Alexa Rakoski, Shriya Sinha, Dmitri Mihaliov, Wesley T. Fuhrman, Shanta R. Saha, Priscila F.S. Rosa, Zachary Fisk, Monica Ciomaga Hatnean, Geetha Balakrishnan, Juan R. Chamorro, W. Adam Phelan, Seyed M. Koohpayeh, Tyrel M. McQueen, Boyoun Kang, Myung Suk Song, Beongki Cho, Michael S. Fuhrer, Johnpierre Paglione, Çaǧllyan Kurdak

School of Physics and Astronomy

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

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Abstract

We investigate the roles of disorder on low-temperature transport in SmB6 crystals grown by both the Al flux and floating zone methods. We used the inverted resistance method with Corbino geometry to investigate whether low-temperature variations in the standard resistance plateau arise from a surface or a bulk channel in floating zone samples. The results show significant sample-dependent residual bulk conduction, in contrast to smaller amounts of residual bulk conduction previously observed in Al flux grown samples with Sm vacancies. We consider hopping in an activated impurity band as a possible source for the observed bulk conduction, but it is unlikely that the large residual bulk conduction seen in floating zone samples is solely due to Sm vacancies. We therefore propose that one-dimensional defects, or dislocations, contribute as well. Using chemical etching, we find evidence for dislocations in both flux and floating zone samples, with higher dislocation density in floating zone samples than in Al flux grown samples. In addition to the possibility of transport through one-dimensional dislocations, we also discuss our results in the context of recent theoretical models of SmB6.

Original language	English
Article number	055001
Number of pages	9
Journal	Physical Review Materials
Volume	5
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevMaterials.5.055001
Publication status	Published - May 2021

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10.1103/PhysRevMaterials.5.055001

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Eo, Y. S., Rakoski, A., Sinha, S., Mihaliov, D., Fuhrman, W. T., Saha, S. R., Rosa, P. F. S., Fisk, Z., Hatnean, M. C., Balakrishnan, G., Chamorro, J. R., Phelan, W. A., Koohpayeh, S. M., McQueen, T. M., Kang, B., Song, M. S., Cho, B., Fuhrer, M. S., Paglione, J., & Kurdak, Ç. (2021). Bulk transport paths through defects in floating zone and Al flux grown SmB6. Physical Review Materials, 5(5), Article 055001. https://doi.org/10.1103/PhysRevMaterials.5.055001

@article{26438cc473dc416c8458170763361dab,

title = "Bulk transport paths through defects in floating zone and Al flux grown SmB6",

abstract = "We investigate the roles of disorder on low-temperature transport in SmB6 crystals grown by both the Al flux and floating zone methods. We used the inverted resistance method with Corbino geometry to investigate whether low-temperature variations in the standard resistance plateau arise from a surface or a bulk channel in floating zone samples. The results show significant sample-dependent residual bulk conduction, in contrast to smaller amounts of residual bulk conduction previously observed in Al flux grown samples with Sm vacancies. We consider hopping in an activated impurity band as a possible source for the observed bulk conduction, but it is unlikely that the large residual bulk conduction seen in floating zone samples is solely due to Sm vacancies. We therefore propose that one-dimensional defects, or dislocations, contribute as well. Using chemical etching, we find evidence for dislocations in both flux and floating zone samples, with higher dislocation density in floating zone samples than in Al flux grown samples. In addition to the possibility of transport through one-dimensional dislocations, we also discuss our results in the context of recent theoretical models of SmB6.",

author = "Eo, {Yun Suk} and Alexa Rakoski and Shriya Sinha and Dmitri Mihaliov and Fuhrman, {Wesley T.} and Saha, {Shanta R.} and Rosa, {Priscila F.S.} and Zachary Fisk and Hatnean, {Monica Ciomaga} and Geetha Balakrishnan and Chamorro, {Juan R.} and Phelan, {W. Adam} and Koohpayeh, {Seyed M.} and McQueen, {Tyrel M.} and Boyoun Kang and Song, {Myung Suk} and Beongki Cho and Fuhrer, {Michael S.} and Johnpierre Paglione and {\c C}aǧllyan Kurdak",

note = "Funding Information: A.R. would like to acknowledge funding support from NSF Grant No. DGE-1256260. W.T.F. is grateful to the Schmidt Science Fellows program, in partnership with the Rhodes Trust, for support of this work. M.S.F. and Y.S.E. were supported by Australian Research Council Grant No. CE170100039. Work at the University of Maryland was supported by NSF Award No. DMR-1905891 and the Gordon and Betty Moore Foundation's EPiQS Initiative through Grant No. GBMF9071. The work at Los Alamos National Laboratory was performed under the auspices of the U.S. Department of Energy, Office of Basic Energy Sciences, Division of Materials Sciences and Engineering. The work at the University of Warwick was supported by EPSRC, United Kingdom, through Grant No. EP/T005963/1. The work at Johns Hopkins University was supported as part of the Institute for Quantum Matter, an Energy Frontier Research Center funded by the U.S. Department of Energy, Office of Science, Basic Energy Sciences, under Award No. DE-SC0019331. Device fabrication was performed in part at the University of Michigan Lurie Nanofabrication Facility. The authors acknowledge the financial support of the University of Michigan College of Engineering and NSF Grant No. DMR-0320740 and technical support from the Michigan Center for Materials Characterization. Publisher Copyright: {\textcopyright} 2021 American Physical Society. Copyright: Copyright 2021 Elsevier B.V., All rights reserved.",

year = "2021",

month = may,

doi = "10.1103/PhysRevMaterials.5.055001",

language = "English",

volume = "5",

journal = "Physical Review Materials",

issn = "2475-9953",

publisher = "American Physical Society",

number = "5",

}

Eo, YS, Rakoski, A, Sinha, S, Mihaliov, D, Fuhrman, WT, Saha, SR, Rosa, PFS, Fisk, Z, Hatnean, MC, Balakrishnan, G, Chamorro, JR, Phelan, WA, Koohpayeh, SM, McQueen, TM, Kang, B, Song, MS, Cho, B, Fuhrer, MS, Paglione, J & Kurdak, Ç 2021, 'Bulk transport paths through defects in floating zone and Al flux grown SmB6', Physical Review Materials, vol. 5, no. 5, 055001. https://doi.org/10.1103/PhysRevMaterials.5.055001

TY - JOUR

T1 - Bulk transport paths through defects in floating zone and Al flux grown SmB6

AU - Eo, Yun Suk

AU - Rakoski, Alexa

AU - Sinha, Shriya

AU - Mihaliov, Dmitri

AU - Fuhrman, Wesley T.

AU - Saha, Shanta R.

AU - Rosa, Priscila F.S.

AU - Fisk, Zachary

AU - Hatnean, Monica Ciomaga

AU - Balakrishnan, Geetha

AU - Chamorro, Juan R.

AU - Phelan, W. Adam

AU - Koohpayeh, Seyed M.

AU - McQueen, Tyrel M.

AU - Kang, Boyoun

AU - Song, Myung Suk

AU - Cho, Beongki

AU - Fuhrer, Michael S.

AU - Paglione, Johnpierre

AU - Kurdak, Çaǧllyan

N1 - Funding Information: A.R. would like to acknowledge funding support from NSF Grant No. DGE-1256260. W.T.F. is grateful to the Schmidt Science Fellows program, in partnership with the Rhodes Trust, for support of this work. M.S.F. and Y.S.E. were supported by Australian Research Council Grant No. CE170100039. Work at the University of Maryland was supported by NSF Award No. DMR-1905891 and the Gordon and Betty Moore Foundation's EPiQS Initiative through Grant No. GBMF9071. The work at Los Alamos National Laboratory was performed under the auspices of the U.S. Department of Energy, Office of Basic Energy Sciences, Division of Materials Sciences and Engineering. The work at the University of Warwick was supported by EPSRC, United Kingdom, through Grant No. EP/T005963/1. The work at Johns Hopkins University was supported as part of the Institute for Quantum Matter, an Energy Frontier Research Center funded by the U.S. Department of Energy, Office of Science, Basic Energy Sciences, under Award No. DE-SC0019331. Device fabrication was performed in part at the University of Michigan Lurie Nanofabrication Facility. The authors acknowledge the financial support of the University of Michigan College of Engineering and NSF Grant No. DMR-0320740 and technical support from the Michigan Center for Materials Characterization. Publisher Copyright: © 2021 American Physical Society. Copyright: Copyright 2021 Elsevier B.V., All rights reserved.

PY - 2021/5

Y1 - 2021/5

N2 - We investigate the roles of disorder on low-temperature transport in SmB6 crystals grown by both the Al flux and floating zone methods. We used the inverted resistance method with Corbino geometry to investigate whether low-temperature variations in the standard resistance plateau arise from a surface or a bulk channel in floating zone samples. The results show significant sample-dependent residual bulk conduction, in contrast to smaller amounts of residual bulk conduction previously observed in Al flux grown samples with Sm vacancies. We consider hopping in an activated impurity band as a possible source for the observed bulk conduction, but it is unlikely that the large residual bulk conduction seen in floating zone samples is solely due to Sm vacancies. We therefore propose that one-dimensional defects, or dislocations, contribute as well. Using chemical etching, we find evidence for dislocations in both flux and floating zone samples, with higher dislocation density in floating zone samples than in Al flux grown samples. In addition to the possibility of transport through one-dimensional dislocations, we also discuss our results in the context of recent theoretical models of SmB6.

AB - We investigate the roles of disorder on low-temperature transport in SmB6 crystals grown by both the Al flux and floating zone methods. We used the inverted resistance method with Corbino geometry to investigate whether low-temperature variations in the standard resistance plateau arise from a surface or a bulk channel in floating zone samples. The results show significant sample-dependent residual bulk conduction, in contrast to smaller amounts of residual bulk conduction previously observed in Al flux grown samples with Sm vacancies. We consider hopping in an activated impurity band as a possible source for the observed bulk conduction, but it is unlikely that the large residual bulk conduction seen in floating zone samples is solely due to Sm vacancies. We therefore propose that one-dimensional defects, or dislocations, contribute as well. Using chemical etching, we find evidence for dislocations in both flux and floating zone samples, with higher dislocation density in floating zone samples than in Al flux grown samples. In addition to the possibility of transport through one-dimensional dislocations, we also discuss our results in the context of recent theoretical models of SmB6.

UR - http://www.scopus.com/inward/record.url?scp=85106387746&partnerID=8YFLogxK

U2 - 10.1103/PhysRevMaterials.5.055001

DO - 10.1103/PhysRevMaterials.5.055001

M3 - Article

AN - SCOPUS:85106387746

SN - 2475-9953

VL - 5

JO - Physical Review Materials

JF - Physical Review Materials

IS - 5

M1 - 055001

ER -

Bulk transport paths through defects in floating zone and Al flux grown SmB6

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Bulk transport paths through defects in floating zone and Al flux grown SmB6

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