From ferromagnetic semiconductor to antiferromagnetic metal in epitaxial CrxTey monolayers

Naina Kushwaha; Olivia Armitage; Brendan Edwards; Liam Trzaska; Jennifer Rigden; Peter Bencok; Deepnarayan Biswas; Tien-Lin Lee; Charlotte Sanders; Gerrit van der Laan; Peter Wahl; Phil D. C. King; Akhil Rajan

doi:10.1038/S41535-025-00772-5

From ferromagnetic semiconductor to antiferromagnetic metal in epitaxial Cr_xTe_y monolayers

Naina Kushwaha, Olivia Armitage, Brendan Edwards, Liam Trzaska, Jennifer Rigden, Peter Bencok, Deepnarayan Biswas, Tien-Lin Lee, Charlotte Sanders, Gerrit van der Laan, Peter Wahl^*, Phil D. C. King^*, Akhil Rajan

^*Corresponding author for this work

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

Abstract

Chromium ditelluride, CrTe₂, is an attractive candidate van der Waals material for hosting 2D magnetism. However, how the room-temperature ferromagnetism of the bulk evolves as the sample is thinned to the single-layer limit has proved controversial. This, in part, reflects its metastable nature, vs. a series of more stable self-intercalation compounds with higher relative Cr:Te stoichiometry. Here, exploiting a recently developed method for enhancing nucleation in molecular-beam epitaxy growth of transition-metal chalcogenides, we demonstrate the selective stabilisation of high-coverage CrTe₂ and Cr_2+εTe₃ epitaxial monolayers. Combining X-ray magnetic circular dichroism, scanning tunnelling microscopy, and temperature-dependent angle-resolved photoemission, we demonstrate that both compounds order magnetically with a similar T_C. We find, however, that monolayer CrTe₂ forms as an antiferromagnetic metal, while monolayer Cr_2+εTe₃ hosts an intrinsic ferromagnetic semiconducting state. This work thus demonstrates that control over the self-intercalation of metastable Cr-based chalcogenides provides a powerful route for tuning both their metallicity and magnetic structure, establishing the Cr_xTe_y system as a flexible materials class for future 2D spintronics.

Original language	English
Article number	50
Number of pages	7
Journal	npj Quantum Materials
Volume	10
DOIs	https://doi.org/10.1038/S41535-025-00772-5
Publication status	Published - 24 May 2025

Access to Document

10.1038/S41535-025-00772-5Licence: CC BY

Kushwaha_2025_npjQM_From-ferromagnetic-semiconductor-CrxTey-monolayers_CC
© The Author(s) 2025. This article is licensed under a Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made.
Final published version, 2.71 MBLicence: CC BY

Cite this

@article{23c21a9f86fb4ca1a11f1ba398cdda4a,

title = "From ferromagnetic semiconductor to antiferromagnetic metal in epitaxial CrxTey monolayers",

abstract = "Chromium ditelluride, CrTe2, is an attractive candidate van der Waals material for hosting 2D magnetism. However, how the room-temperature ferromagnetism of the bulk evolves as the sample is thinned to the single-layer limit has proved controversial. This, in part, reflects its metastable nature, vs. a series of more stable self-intercalation compounds with higher relative Cr:Te stoichiometry. Here, exploiting a recently developed method for enhancing nucleation in molecular-beam epitaxy growth of transition-metal chalcogenides, we demonstrate the selective stabilisation of high-coverage CrTe2 and Cr2+εTe3 epitaxial monolayers. Combining X-ray magnetic circular dichroism, scanning tunnelling microscopy, and temperature-dependent angle-resolved photoemission, we demonstrate that both compounds order magnetically with a similar TC. We find, however, that monolayer CrTe2 forms as an antiferromagnetic metal, while monolayer Cr2+εTe3 hosts an intrinsic ferromagnetic semiconducting state. This work thus demonstrates that control over the self-intercalation of metastable Cr-based chalcogenides provides a powerful route for tuning both their metallicity and magnetic structure, establishing the CrxTey system as a flexible materials class for future 2D spintronics.",

author = "Naina Kushwaha and Olivia Armitage and Brendan Edwards and Liam Trzaska and Jennifer Rigden and Peter Bencok and Deepnarayan Biswas and Tien-Lin Lee and Charlotte Sanders and \{van der Laan\}, Gerrit and Peter Wahl and King, \{Phil D. C.\} and Akhil Rajan",

note = "Funding: The authors gratefully acknowledge support from the Engineering and Physical Sciences Research Council (Grant Nos. EP/X015556/1, EP/X015599/1, and EP/M023958/1) and the Leverhulme Trust (Grant no. RL-2016-006).",

year = "2025",

month = may,

day = "24",

doi = "10.1038/S41535-025-00772-5",

language = "English",

volume = "10",

journal = "npj Quantum Materials",

issn = "2397-4648",

publisher = "Nature publishing group",

}

TY - JOUR

T1 - From ferromagnetic semiconductor to antiferromagnetic metal in epitaxial CrxTey monolayers

AU - Kushwaha, Naina

AU - Armitage, Olivia

AU - Edwards, Brendan

AU - Trzaska, Liam

AU - Rigden, Jennifer

AU - Bencok, Peter

AU - Biswas, Deepnarayan

AU - Lee, Tien-Lin

AU - Sanders, Charlotte

AU - van der Laan, Gerrit

AU - Wahl, Peter

AU - King, Phil D. C.

AU - Rajan, Akhil

N1 - Funding: The authors gratefully acknowledge support from the Engineering and Physical Sciences Research Council (Grant Nos. EP/X015556/1, EP/X015599/1, and EP/M023958/1) and the Leverhulme Trust (Grant no. RL-2016-006).

PY - 2025/5/24

Y1 - 2025/5/24

N2 - Chromium ditelluride, CrTe2, is an attractive candidate van der Waals material for hosting 2D magnetism. However, how the room-temperature ferromagnetism of the bulk evolves as the sample is thinned to the single-layer limit has proved controversial. This, in part, reflects its metastable nature, vs. a series of more stable self-intercalation compounds with higher relative Cr:Te stoichiometry. Here, exploiting a recently developed method for enhancing nucleation in molecular-beam epitaxy growth of transition-metal chalcogenides, we demonstrate the selective stabilisation of high-coverage CrTe2 and Cr2+εTe3 epitaxial monolayers. Combining X-ray magnetic circular dichroism, scanning tunnelling microscopy, and temperature-dependent angle-resolved photoemission, we demonstrate that both compounds order magnetically with a similar TC. We find, however, that monolayer CrTe2 forms as an antiferromagnetic metal, while monolayer Cr2+εTe3 hosts an intrinsic ferromagnetic semiconducting state. This work thus demonstrates that control over the self-intercalation of metastable Cr-based chalcogenides provides a powerful route for tuning both their metallicity and magnetic structure, establishing the CrxTey system as a flexible materials class for future 2D spintronics.

AB - Chromium ditelluride, CrTe2, is an attractive candidate van der Waals material for hosting 2D magnetism. However, how the room-temperature ferromagnetism of the bulk evolves as the sample is thinned to the single-layer limit has proved controversial. This, in part, reflects its metastable nature, vs. a series of more stable self-intercalation compounds with higher relative Cr:Te stoichiometry. Here, exploiting a recently developed method for enhancing nucleation in molecular-beam epitaxy growth of transition-metal chalcogenides, we demonstrate the selective stabilisation of high-coverage CrTe2 and Cr2+εTe3 epitaxial monolayers. Combining X-ray magnetic circular dichroism, scanning tunnelling microscopy, and temperature-dependent angle-resolved photoemission, we demonstrate that both compounds order magnetically with a similar TC. We find, however, that monolayer CrTe2 forms as an antiferromagnetic metal, while monolayer Cr2+εTe3 hosts an intrinsic ferromagnetic semiconducting state. This work thus demonstrates that control over the self-intercalation of metastable Cr-based chalcogenides provides a powerful route for tuning both their metallicity and magnetic structure, establishing the CrxTey system as a flexible materials class for future 2D spintronics.

UR - https://www.scopus.com/pages/publications/105005794136

U2 - 10.1038/S41535-025-00772-5

DO - 10.1038/S41535-025-00772-5

M3 - Article

SN - 2397-4648

VL - 10

JO - npj Quantum Materials

JF - npj Quantum Materials

M1 - 50

ER -

From ferromagnetic semiconductor to antiferromagnetic metal in epitaxial Cr_xTe_y monolayers

Abstract

Access to Document

Other files and links

Fingerprint

Controlling and integrating 2D magnetism: Controlling and integrating 2D magnetism in epitaxial van der Waals heterostructures

Engineered Quantum States: Engineered quantum states via atmoic-scale assembly of artificial 2D heterostructures

Designer Oxides: Designer Oxides: Reactive-Oxide Molecular Beam Epitaxy System