Modulated crystal structure of the atypical charge density wave state of single-crystal Lu2Ir3Si5

Sitaram Ramakrishnan; Andreas Schönleber; Jin Ke Bao; Toms Rekis; Surya Rohith Kotla; Achim M. Schaller; Sander Van Smaalen; Leila Noohinejad; Martin Tolkiehn; Carsten Paulmann; N. S. Sangeetha; Dilip Pal; Arumugam Thamizhavel; Srinivasan Ramakrishnan

doi:10.1103/PhysRevB.104.054116

Modulated crystal structure of the atypical charge density wave state of single-crystal Lu2Ir3Si5

Sitaram Ramakrishnan
, Andreas Schönleber
, Jin Ke Bao
, Toms Rekis
, Surya Rohith Kotla
, Achim M. Schaller
, Sander Van Smaalen
, Leila Noohinejad
, Martin Tolkiehn
, Carsten Paulmann
, N. S. Sangeetha
, Dilip Pal
, Arumugam Thamizhavel
, Srinivasan Ramakrishnan

University of Bayreuth
Hiroshima University
German Electron Synchrotron
University of Hamburg
Indian Institute of Technology Guwahati
Karlsruhe Institute of Technology
Tata Institute of Fundamental Research

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

12 Citations (Scopus)

Abstract

The three-dimensional charge density wave (CDW) compound Lu2Ir3Si5 undergoes a first-order CDW phase transition at around 200 K. An atypical CDW state is found, that is characterized by an incommensurate CDW with q=[0.2499(3),0.4843(4),0.2386(2)] at 60 K, and a large orthorhombic-to-triclinic lattice distortion with β=91.945(2). We present the modulated crystal structure of the incommensurate CDW state. Structural analysis shows that the CDW resides on the zigzag chains of iridium atoms along c. The structural distortions are completely similar between nonmagnetic Lu2Ir3Si5 and previously studied isostructural magnetic Er2Ir3Si5 with the small differences explained by the different values of the atomic radii of Lu and Er. Such a similarity is unique to R2Ir3Si5 (R=rareearth). It differs from, for example, the rare-earth CDW compounds R5Ir4Si10 for which Lu5Ir4Si10 and Er5Ir4Si10 possess entirely different CDW states. We argue that the mechanism of CDW formation, thus, is different for R2Ir3Si5 and R5Ir4Si10.

Original language	English
Article number	054116
Journal	Physical Review B
Volume	104
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevB.104.054116
Publication status	Published - 1 Aug 2021
Externally published	Yes

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Ramakrishnan, S., Schönleber, A., Bao, J. K., Rekis, T., Kotla, S. R., Schaller, A. M., Van Smaalen, S., Noohinejad, L., Tolkiehn, M., Paulmann, C., Sangeetha, N. S., Pal, D., Thamizhavel, A., & Ramakrishnan, S. (2021). Modulated crystal structure of the atypical charge density wave state of single-crystal Lu2Ir3Si5. Physical Review B, 104(5), Article 054116. https://doi.org/10.1103/PhysRevB.104.054116

@article{78ad76d863a24bd29f029763ca0defa5,

title = "Modulated crystal structure of the atypical charge density wave state of single-crystal Lu2Ir3Si5",

abstract = "The three-dimensional charge density wave (CDW) compound Lu2Ir3Si5 undergoes a first-order CDW phase transition at around 200 K. An atypical CDW state is found, that is characterized by an incommensurate CDW with q=[0.2499(3),0.4843(4),0.2386(2)] at 60 K, and a large orthorhombic-to-triclinic lattice distortion with β=91.945(2). We present the modulated crystal structure of the incommensurate CDW state. Structural analysis shows that the CDW resides on the zigzag chains of iridium atoms along c. The structural distortions are completely similar between nonmagnetic Lu2Ir3Si5 and previously studied isostructural magnetic Er2Ir3Si5 with the small differences explained by the different values of the atomic radii of Lu and Er. Such a similarity is unique to R2Ir3Si5 (R=rareearth). It differs from, for example, the rare-earth CDW compounds R5Ir4Si10 for which Lu5Ir4Si10 and Er5Ir4Si10 possess entirely different CDW states. We argue that the mechanism of CDW formation, thus, is different for R2Ir3Si5 and R5Ir4Si10.",

author = "Sitaram Ramakrishnan and Andreas Sch{\"o}nleber and Bao, \{Jin Ke\} and Toms Rekis and Kotla, \{Surya Rohith\} and Schaller, \{Achim M.\} and \{Van Smaalen\}, Sander and Leila Noohinejad and Martin Tolkiehn and Carsten Paulmann and Sangeetha, \{N. S.\} and Dilip Pal and Arumugam Thamizhavel and Srinivasan Ramakrishnan",

note = "Publisher Copyright: {\textcopyright} 2021 American Physical Society.",

year = "2021",

month = aug,

day = "1",

doi = "10.1103/PhysRevB.104.054116",

language = "English",

volume = "104",

journal = "Physical Review B",

issn = "2469-9950",

publisher = "American Physical Society",

number = "5",

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Ramakrishnan, S, Schönleber, A, Bao, JK, Rekis, T, Kotla, SR, Schaller, AM, Van Smaalen, S, Noohinejad, L, Tolkiehn, M, Paulmann, C, Sangeetha, NS, Pal, D, Thamizhavel, A & Ramakrishnan, S 2021, 'Modulated crystal structure of the atypical charge density wave state of single-crystal Lu2Ir3Si5', Physical Review B, vol. 104, no. 5, 054116. https://doi.org/10.1103/PhysRevB.104.054116

TY - JOUR

T1 - Modulated crystal structure of the atypical charge density wave state of single-crystal Lu2Ir3Si5

AU - Ramakrishnan, Sitaram

AU - Schönleber, Andreas

AU - Bao, Jin Ke

AU - Rekis, Toms

AU - Kotla, Surya Rohith

AU - Schaller, Achim M.

AU - Van Smaalen, Sander

AU - Noohinejad, Leila

AU - Tolkiehn, Martin

AU - Paulmann, Carsten

AU - Sangeetha, N. S.

AU - Pal, Dilip

AU - Thamizhavel, Arumugam

AU - Ramakrishnan, Srinivasan

PY - 2021/8/1

Y1 - 2021/8/1

N2 - The three-dimensional charge density wave (CDW) compound Lu2Ir3Si5 undergoes a first-order CDW phase transition at around 200 K. An atypical CDW state is found, that is characterized by an incommensurate CDW with q=[0.2499(3),0.4843(4),0.2386(2)] at 60 K, and a large orthorhombic-to-triclinic lattice distortion with β=91.945(2). We present the modulated crystal structure of the incommensurate CDW state. Structural analysis shows that the CDW resides on the zigzag chains of iridium atoms along c. The structural distortions are completely similar between nonmagnetic Lu2Ir3Si5 and previously studied isostructural magnetic Er2Ir3Si5 with the small differences explained by the different values of the atomic radii of Lu and Er. Such a similarity is unique to R2Ir3Si5 (R=rareearth). It differs from, for example, the rare-earth CDW compounds R5Ir4Si10 for which Lu5Ir4Si10 and Er5Ir4Si10 possess entirely different CDW states. We argue that the mechanism of CDW formation, thus, is different for R2Ir3Si5 and R5Ir4Si10.

AB - The three-dimensional charge density wave (CDW) compound Lu2Ir3Si5 undergoes a first-order CDW phase transition at around 200 K. An atypical CDW state is found, that is characterized by an incommensurate CDW with q=[0.2499(3),0.4843(4),0.2386(2)] at 60 K, and a large orthorhombic-to-triclinic lattice distortion with β=91.945(2). We present the modulated crystal structure of the incommensurate CDW state. Structural analysis shows that the CDW resides on the zigzag chains of iridium atoms along c. The structural distortions are completely similar between nonmagnetic Lu2Ir3Si5 and previously studied isostructural magnetic Er2Ir3Si5 with the small differences explained by the different values of the atomic radii of Lu and Er. Such a similarity is unique to R2Ir3Si5 (R=rareearth). It differs from, for example, the rare-earth CDW compounds R5Ir4Si10 for which Lu5Ir4Si10 and Er5Ir4Si10 possess entirely different CDW states. We argue that the mechanism of CDW formation, thus, is different for R2Ir3Si5 and R5Ir4Si10.

UR - https://www.scopus.com/pages/publications/85113802057

U2 - 10.1103/PhysRevB.104.054116

DO - 10.1103/PhysRevB.104.054116

M3 - Article

AN - SCOPUS:85113802057

SN - 2469-9950

VL - 104

JO - Physical Review B

JF - Physical Review B

IS - 5

M1 - 054116

ER -

Modulated crystal structure of the atypical charge density wave state of single-crystal Lu2Ir3Si5

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