Ferroaxial density wave from intertwined charge and orbital order in rare-earth tritellurides

Birender Singh; Grant McNamara; Kyung Mo Kim; Saif Siddique; Stephen D. Funni; Weizhe Zhang; Xiangpeng Luo; Piyush Sakrikar; Eric M. Kenney; Ratnadwip Singha; Sergey Alekseev; Sayed Ali Akbar Ghorashi; Thomas J. Hicken; Christopher Baines; Hubertus Luetkens; Yiping Wang; Vincent M. Plisson; Michael Geiwitz; Connor A. Occhialini; Riccardo Comin; Michael J. Graf; Liuyan Zhao; Jennifer Cano; Rafael M. Fernandes; Judy J. Cha; Leslie M. Schoop; Kenneth S. Burch

doi:10.1038/s41567-025-03008-2

Ferroaxial density wave from intertwined charge and orbital order in rare-earth tritellurides

Birender Singh
, Grant McNamara
, Kyung Mo Kim
, Saif Siddique
, Stephen D. Funni
, Weizhe Zhang
, Xiangpeng Luo
, Piyush Sakrikar
, Eric M. Kenney
, Ratnadwip Singha
, Sergey Alekseev
, Sayed Ali Akbar Ghorashi
, Thomas J. Hicken
, Christopher Baines
, Hubertus Luetkens
, Yiping Wang
, Vincent M. Plisson
, Michael Geiwitz
, Connor A. Occhialini
, Riccardo Comin

Michael J. Graf, Liuyan Zhao, Jennifer Cano, Rafael M. Fernandes, Judy J. Cha, Leslie M. Schoop, Kenneth S. Burch

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

9 Scopus citations

Abstract

The discovery of the axial amplitude mode—commonly referred to as the Higgs mode—in charge density wave systems, such as rare-earth tritellurides, indicates the presence of a hidden order. A theoretical study proposed that this axial Higgs mode arises from a hidden orbital texture of the charge density wave, which produces a ferroaxial charge order. However, experimental evidence for the specific hidden order has been lacking. Here, we demonstrate a ferroaxial order of electronic origin throughout the rare-earth tritellurides. In ErTe₃ and HoTe₃, which exhibit two distinct charge density waves with different ordering temperatures, a detailed investigation shows that the high-temperature charge order phase breaks translational, rotational and all vertical as well as diagonal mirror symmetries. Furthermore, this phase produces an axial Higgs mode and an axial electronic gap. By contrast, the low-temperature phase breaks only translational symmetry and gives rise to a scalar Higgs mode. Notably, both phases preserve the space inversion and time-reversal symmetries. These findings are consistent with a ferroaxial phase driven by coupled orbital and charge orders, highlighting the role of Higgs modes in revealing hidden orders in systems with intertwined charge density waves.

Original language	English (US)
Pages (from-to)	1578-1586
Number of pages	9
Journal	Nature Physics
Volume	21
Issue number	10
DOIs	https://doi.org/10.1038/s41567-025-03008-2
State	Published - Oct 2025

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1038/s41567-025-03008-2

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Singh, B., McNamara, G., Kim, K. M., Siddique, S., Funni, S. D., Zhang, W., Luo, X., Sakrikar, P., Kenney, E. M., Singha, R., Alekseev, S., Ghorashi, S. A. A., Hicken, T. J., Baines, C., Luetkens, H., Wang, Y., Plisson, V. M., Geiwitz, M., Occhialini, C. A., ... Burch, K. S. (2025). Ferroaxial density wave from intertwined charge and orbital order in rare-earth tritellurides. Nature Physics, 21(10), 1578-1586. https://doi.org/10.1038/s41567-025-03008-2

@article{037e36c52ac44ca9aee2b4dc3fd65d87,

title = "Ferroaxial density wave from intertwined charge and orbital order in rare-earth tritellurides",

abstract = "The discovery of the axial amplitude mode—commonly referred to as the Higgs mode—in charge density wave systems, such as rare-earth tritellurides, indicates the presence of a hidden order. A theoretical study proposed that this axial Higgs mode arises from a hidden orbital texture of the charge density wave, which produces a ferroaxial charge order. However, experimental evidence for the specific hidden order has been lacking. Here, we demonstrate a ferroaxial order of electronic origin throughout the rare-earth tritellurides. In ErTe3 and HoTe3, which exhibit two distinct charge density waves with different ordering temperatures, a detailed investigation shows that the high-temperature charge order phase breaks translational, rotational and all vertical as well as diagonal mirror symmetries. Furthermore, this phase produces an axial Higgs mode and an axial electronic gap. By contrast, the low-temperature phase breaks only translational symmetry and gives rise to a scalar Higgs mode. Notably, both phases preserve the space inversion and time-reversal symmetries. These findings are consistent with a ferroaxial phase driven by coupled orbital and charge orders, highlighting the role of Higgs modes in revealing hidden orders in systems with intertwined charge density waves.",

author = "Birender Singh and Grant McNamara and Kim, \{Kyung Mo\} and Saif Siddique and Funni, \{Stephen D.\} and Weizhe Zhang and Xiangpeng Luo and Piyush Sakrikar and Kenney, \{Eric M.\} and Ratnadwip Singha and Sergey Alekseev and Ghorashi, \{Sayed Ali Akbar\} and Hicken, \{Thomas J.\} and Christopher Baines and Hubertus Luetkens and Yiping Wang and Plisson, \{Vincent M.\} and Michael Geiwitz and Occhialini, \{Connor A.\} and Riccardo Comin and Graf, \{Michael J.\} and Liuyan Zhao and Jennifer Cano and Fernandes, \{Rafael M.\} and Cha, \{Judy J.\} and Schoop, \{Leslie M.\} and Burch, \{Kenneth S.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = oct,

doi = "10.1038/s41567-025-03008-2",

language = "English (US)",

volume = "21",

pages = "1578--1586",

journal = "Nature Physics",

issn = "1745-2473",

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Singh, B, McNamara, G, Kim, KM, Siddique, S, Funni, SD, Zhang, W, Luo, X, Sakrikar, P, Kenney, EM, Singha, R, Alekseev, S, Ghorashi, SAA, Hicken, TJ, Baines, C, Luetkens, H, Wang, Y, Plisson, VM, Geiwitz, M, Occhialini, CA, Comin, R, Graf, MJ, Zhao, L, Cano, J, Fernandes, RM, Cha, JJ, Schoop, LM & Burch, KS 2025, 'Ferroaxial density wave from intertwined charge and orbital order in rare-earth tritellurides', Nature Physics, vol. 21, no. 10, pp. 1578-1586. https://doi.org/10.1038/s41567-025-03008-2

TY - JOUR

T1 - Ferroaxial density wave from intertwined charge and orbital order in rare-earth tritellurides

AU - Singh, Birender

AU - McNamara, Grant

AU - Kim, Kyung Mo

AU - Siddique, Saif

AU - Funni, Stephen D.

AU - Zhang, Weizhe

AU - Luo, Xiangpeng

AU - Sakrikar, Piyush

AU - Kenney, Eric M.

AU - Singha, Ratnadwip

AU - Alekseev, Sergey

AU - Ghorashi, Sayed Ali Akbar

AU - Hicken, Thomas J.

AU - Baines, Christopher

AU - Luetkens, Hubertus

AU - Wang, Yiping

AU - Plisson, Vincent M.

AU - Geiwitz, Michael

AU - Occhialini, Connor A.

AU - Comin, Riccardo

AU - Graf, Michael J.

AU - Zhao, Liuyan

AU - Cano, Jennifer

AU - Fernandes, Rafael M.

AU - Cha, Judy J.

AU - Schoop, Leslie M.

AU - Burch, Kenneth S.

PY - 2025/10

Y1 - 2025/10

N2 - The discovery of the axial amplitude mode—commonly referred to as the Higgs mode—in charge density wave systems, such as rare-earth tritellurides, indicates the presence of a hidden order. A theoretical study proposed that this axial Higgs mode arises from a hidden orbital texture of the charge density wave, which produces a ferroaxial charge order. However, experimental evidence for the specific hidden order has been lacking. Here, we demonstrate a ferroaxial order of electronic origin throughout the rare-earth tritellurides. In ErTe3 and HoTe3, which exhibit two distinct charge density waves with different ordering temperatures, a detailed investigation shows that the high-temperature charge order phase breaks translational, rotational and all vertical as well as diagonal mirror symmetries. Furthermore, this phase produces an axial Higgs mode and an axial electronic gap. By contrast, the low-temperature phase breaks only translational symmetry and gives rise to a scalar Higgs mode. Notably, both phases preserve the space inversion and time-reversal symmetries. These findings are consistent with a ferroaxial phase driven by coupled orbital and charge orders, highlighting the role of Higgs modes in revealing hidden orders in systems with intertwined charge density waves.

AB - The discovery of the axial amplitude mode—commonly referred to as the Higgs mode—in charge density wave systems, such as rare-earth tritellurides, indicates the presence of a hidden order. A theoretical study proposed that this axial Higgs mode arises from a hidden orbital texture of the charge density wave, which produces a ferroaxial charge order. However, experimental evidence for the specific hidden order has been lacking. Here, we demonstrate a ferroaxial order of electronic origin throughout the rare-earth tritellurides. In ErTe3 and HoTe3, which exhibit two distinct charge density waves with different ordering temperatures, a detailed investigation shows that the high-temperature charge order phase breaks translational, rotational and all vertical as well as diagonal mirror symmetries. Furthermore, this phase produces an axial Higgs mode and an axial electronic gap. By contrast, the low-temperature phase breaks only translational symmetry and gives rise to a scalar Higgs mode. Notably, both phases preserve the space inversion and time-reversal symmetries. These findings are consistent with a ferroaxial phase driven by coupled orbital and charge orders, highlighting the role of Higgs modes in revealing hidden orders in systems with intertwined charge density waves.

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UR - https://www.scopus.com/pages/publications/105014886796#tab=citedBy

U2 - 10.1038/s41567-025-03008-2

DO - 10.1038/s41567-025-03008-2

M3 - Article

AN - SCOPUS:105014886796

SN - 1745-2473

VL - 21

SP - 1578

EP - 1586

JO - Nature Physics

JF - Nature Physics

IS - 10

ER -

Ferroaxial density wave from intertwined charge and orbital order in rare-earth tritellurides

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