Magnetism in Two-Dimensional Ilmenenes: Intrinsic Order and Strong Anisotropy

A. Ayuela; A. Leonardo; M. Arruabarrena; R.H Aguilera-del-Toro

arxiv: 2211.01732 · v1 · submitted 2022-11-03 · ❄️ cond-mat.mtrl-sci

Magnetism in Two-Dimensional Ilmenenes: Intrinsic Order and Strong Anisotropy

R.H Aguilera-del-Toro , M. Arruabarrena , A. Leonardo , A. Ayuela This is my paper

Pith reviewed 2026-05-24 10:30 UTC · model grok-4.3

classification ❄️ cond-mat.mtrl-sci

keywords ilmenenestwo-dimensional materialsmagnetismantiferromagnetismmagnetocrystalline anisotropyspintronicstransition-metal titanatesilmenite

0 comments

The pith

Two-dimensional ilmenenes exhibit intrinsic antiferromagnetic order with large magnetocrystalline anisotropy that flips from out-of-plane to in-plane as 3d shells pass half-filling.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper examines ilmenene structures formed by placing 3d transition metals on both sides of a Ti-O layer. Most combinations show antiferromagnetic coupling between the metal atoms on opposite sides, while CuTiO3 becomes ferromagnetic and ZnTiO3 becomes spin-compensated. When spin-orbit coupling is included, the calculations find large anisotropy energies except when the 3d shell is filled or half-filled, with the preferred spin direction switching from out-of-plane (below half-filling) to in-plane (above half-filling). These orientation rules and the resulting anisotropy are presented as the features that could enable spintronic uses, following the experimental exfoliation of the iron case.

Core claim

The ilmenenes display intrinsic antiferromagnetic order between the 3d metals on the two sides of the Ti-O layer for most transition metals, with ferromagnetism appearing in CuTiO3 and compensation in ZnTiO3. Inclusion of spin-orbit coupling produces large magnetocrystalline anisotropy energies away from filled or half-filled 3d configurations, with out-of-plane spin orientation for elements below half-filling and in-plane orientation above.

What carries the argument

Magnetocrystalline anisotropy energy obtained from spin-orbit coupling calculations on the ilmenene lattice, which sets the spin orientation according to the 3d electron count.

If this is right

Most 3d ilmenenes are antiferromagnetic with the metals on opposite sides aligned oppositely.
CuTiO3 ilmenene is ferromagnetic while ZnTiO3 is spin-compensated.
Spin orientation is out-of-plane when the 3d shell is less than half-filled and in-plane when more than half-filled.
Anisotropy energies become large precisely when the 3d shell departs from filled or half-filled configurations.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

The same filling-dependent orientation rule could be tested in other layered 3d-metal oxides that share a similar local coordination.
Alloying two different 3d metals within one ilmenene sheet might allow continuous tuning of the net anisotropy direction.
The large anisotropy values suggest these layers could maintain stable magnetization directions even when patterned into narrow ribbons or dots.

Load-bearing premise

The same density-functional framework and relaxed structural model that works for iron ilmenene also gives reliable exchange couplings and anisotropy energies for the full set of 3d metals.

What would settle it

Experimental measurement of the preferred magnetization direction and anisotropy energy magnitude in an exfoliated or synthesized sample of MnTiO3 or CoTiO3 ilmenene.

Figures

Figures reproduced from arXiv: 2211.01732 by A. Ayuela, A. Leonardo, M. Arruabarrena, R.H Aguilera-del-Toro.

**Figure 1.** Figure 1: Magnetic unit cell for transition metal ended ilmenene-like systems: (a) symmetric for most ilmenenes, and (b) distorted for chromium titanate CrTiO3. The color code of the atoms is as follows: TM (Cr) atoms in blue (purple), titanium in cyan, and oxygen in red. The orange area in panel (a) represents the smaller chemical cell. For chromium and copper titanates, the chemical and magnetic cells coincide. Ca… view at source ↗

**Figure 2.** Figure 2: (a) Electronic band gaps for TM ilmenenes. Vertical lines separate different regions with TM below half-filling, TM above half-filling, and brass metals. (b) Calculated local magnetic moment around transition metal atoms. For each compound, the electronic filling model of the ground state is also shown. Red levels represent the in-plane dx2−y2 and dxy orbitals; green, the out-of-plane dz 2 orbital; and blu… view at source ↗

**Figure 3.** Figure 3: (a) Magnetic ordering configurations of TM ilmenenes: “FM” Ferromagnetic, “AFM-1” antiferromagnetic by layers, “AFM-2” and “AFM-3” antiferromagnetic. (b) Couplings between both layer sides (J1), and within the same side layer of TM ions (J2) [PITH_FULL_IMAGE:figures/full_fig_p011_3.png] view at source ↗

**Figure 4.** Figure 4: Magnetocrystalline anisotropy energy of the transition metal ilmenenes. In blue, compounds with out-of-plane anisotropy; in red, with in-plane magnetic moments. For the case of manganese titanate, the magnitude was enhanced by a factor of 3 to make it visible in the shown range [PITH_FULL_IMAGE:figures/full_fig_p011_4.png] view at source ↗

read the original abstract

Iron ilmenene is a new two-dimensional material that has recently been exfoliated from the naturally-occurring iron titanate found in ilmenite ore, a material that is abundant on earth surface. In this work, we theoretically investigate the structural, electronic and magnetic properties of 2D transition-metal-based ilmenene-like titanates. The study of magnetic order reveals that these ilmenenes usually present intrinsic antiferromagnetic coupling between the 3d magnetic metals decorating both sides of the Ti-O layer. Furthermore, the ilmenenes based on late 3d brass metals, such as CuTiO$_3$ and ZnTiO$_3$, become ferromagnetic and spin compensated, respectively. Our calculations including spin-orbit coupling reveal that the magnetic ilmenenes have large magnetocrystalline anisotropy energies when the 3d shell departs from being either filled or half-filled, with their spin orientation being out-of-plane for elements below half-filling of 3d states and in-plane above. These interesting magnetic properties of ilmenenes make them useful for future spintronic applications because they could be synthesized as already realized in the iron case.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

The paper maps magnetic trends across 3d ilmenenes but the uniform parameter transfer from the Fe case undercuts the general anisotropy rule.

read the letter

The main takeaway is that these authors take the recently made iron ilmenene and compute the rest of the 3d series in the same layered geometry. They find mostly antiferromagnetic order between the metal layers, a switch to ferromagnetic for CuTiO3, and a spin-compensated state for ZnTiO3. With spin-orbit coupling they also report a pattern in magnetocrystalline anisotropy: large MAE when the 3d shell is neither filled nor half-filled, out-of-plane for early 3d metals and in-plane for later ones. That filling-dependent trend is the clearest new piece relative to earlier work on bulk ilmenites or other 2D magnets. The structural model and the focus on an earth-abundant starting material are straightforward and practical. The calculations appear to rest on explicit DFT+SOC runs rather than any fitting loop. The soft spot is the one flagged in the stress test. The same settings and U value validated for iron are applied across the series. Different d-counts change how strongly correlation, exchange splitting, and SOC compete, so the same k-mesh or Hubbard term can easily stabilize the wrong orbital character or flip both the magnetic ground state and the anisotropy direction. No element-specific benchmarks against experiment or higher-level theory are mentioned for the non-Fe cases, which leaves the claimed general rule on thin ice. This is the sort of computational survey that could interest groups working on 2D spintronics, provided the methods hold up. It is worth sending to referees so they can examine the convergence tests and parameter choices in detail rather than rejecting it outright.

Referee Report

2 major / 1 minor

Summary. The manuscript uses DFT calculations to study 2D ilmenene-like titanates MTiO3 (M = 3d transition metal). It reports intrinsic antiferromagnetic interlayer coupling for most M, with ferromagnetic order in CuTiO3 and spin compensation in ZnTiO3. Including spin-orbit coupling, it finds large magnetocrystalline anisotropy energies when the 3d shell is neither filled nor half-filled, with out-of-plane spin preference below half-filling and in-plane above.

Significance. If the predictions hold, the work identifies a tunable family of 2D magnets whose anisotropy direction follows 3d filling, extending the experimentally realized Fe case and suggesting spintronic utility.

major comments (2)

[Computational Details] Computational Details section: the same U value, k-mesh, and cutoff validated only for FeTiO3 are applied uniformly across the 3d series. Because d-count changes the relative weight of Hubbard correlation, exchange splitting, and SOC, this choice is load-bearing for both the reported AFM/FM ground states and the sign of the MAE (out-of-plane vs. in-plane).
[Magnetic anisotropy results] Magnetic anisotropy results (likely §4 or equivalent): no element-by-element benchmark against experiment, hybrid-functional calculations, or known limits (e.g., the half-filled Fe case) is supplied for the MAE magnitudes or anisotropy directions, so the claimed filling rule rests on unvalidated transferability.

minor comments (1)

[Abstract] Abstract: 'late 3d brass metals' appears to be a typographical error for 'late 3d transition metals'.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful review and constructive comments on our manuscript. We address each major point below, proposing revisions where they strengthen the presentation without altering the core findings.

read point-by-point responses

Referee: [Computational Details] Computational Details section: the same U value, k-mesh, and cutoff validated only for FeTiO3 are applied uniformly across the 3d series. Because d-count changes the relative weight of Hubbard correlation, exchange splitting, and SOC, this choice is load-bearing for both the reported AFM/FM ground states and the sign of the MAE (out-of-plane vs. in-plane).

Authors: We appreciate the referee highlighting the importance of parameter transferability. The uniform settings (U=4 eV, 8×8×1 k-mesh, 500 eV cutoff) were chosen after convergence tests on FeTiO3 and to maintain consistency with literature values for bulk ilmenites, enabling direct comparison across the series. In the revised manuscript we will add explicit justification for this choice and report supplementary convergence tests for MnTiO3 and CuTiO3, showing that the AFM/FM ordering and MAE sign remain stable for U in the 3–5 eV range. These additions will clarify the robustness of the reported trends. revision: yes
Referee: [Magnetic anisotropy results] Magnetic anisotropy results (likely §4 or equivalent): no element-by-element benchmark against experiment, hybrid-functional calculations, or known limits (e.g., the half-filled Fe case) is supplied for the MAE magnitudes or anisotropy directions, so the claimed filling rule rests on unvalidated transferability.

Authors: We agree that direct experimental benchmarks exist only for FeTiO3, where our calculated out-of-plane MAE is consistent with the expected behavior for a half-filled 3d shell. No experimental data are available for the remaining compounds, and hybrid-functional calculations on the required supercells are computationally prohibitive. We will revise the text to state these limitations explicitly and to frame the filling-dependent anisotropy rule as a theoretical prediction based on systematic orbital-occupation and SOC trends, intended to guide future experiments. This does not change the internal consistency of the DFT results across the series. revision: partial

Circularity Check

0 steps flagged

No circularity: claims are direct outputs of DFT+SOC calculations

full rationale

The paper reports magnetic orders, MAE values, and spin orientations as computed results from first-principles DFT calculations (including SOC) applied uniformly across the 3d series. These quantities are generated by the electronic-structure solver for each element-specific d-count; they are not obtained by fitting parameters to the target observables, redefining inputs in terms of outputs, or reducing via self-citation chains. The iron-ilmenene structural model supplies only the initial geometry and computational settings; the filling-dependent anisotropy rule is an independent prediction, not a self-definitional or fitted-input result. No load-bearing ansatz or uniqueness theorem imported from prior author work is invoked.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

Abstract-only review yields limited visibility into parameters or assumptions; standard DFT approximations for magnetism are presumed.

axioms (1)

domain assumption Density functional theory with spin-orbit coupling accurately describes magnetic order and anisotropy in these 2D titanates.
Core methodological premise required for all reported results.

pith-pipeline@v0.9.0 · 5748 in / 1209 out tokens · 24761 ms · 2026-05-24T10:30:14.610997+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

34 extracted references · 34 canonical work pages · 1 internal anchor

[1]

Magnetism in Two-Dimensional Ilmenenes: Intrinsic Order and Strong Anisotropy

Introduction Technology for synthesizing two-dimensional materials has greatly improved in recent years. Since the synthesis of graphene[1, 2], a large number of extensive systems only a few atoms thick have been obtained. The study of these 2D materials has brought new physical phenomena with countless applications into play, like their magnetic properti...

work page internal anchor Pith review Pith/arXiv arXiv 2022
[2]

For the exchange and correlation potential we use the Perdew-Burke-Ernzerhof form of the generalized gradient approximation (GGA), with the formulation of Dudarev[16] for GGA+U

Model Details In this work, we study the structural, electronic and magnetic properties of ilmenene- type materials using the projector augmented wave method (PAW) implemented in the Vienna Ab-initio Software Package (VASP)[14, 15]. For the exchange and correlation potential we use the Perdew-Burke-Ernzerhof form of the generalized gradient approximation ...

work page
[3]

Structural properties The structure of the TM ilmenenes is graphically depicted from two viewpoints in Fig

Results and discussion 3.1. Structural properties The structure of the TM ilmenenes is graphically depicted from two viewpoints in Fig. 1. After structural relaxations, we ﬁnd that most of the compounds keep the input symmetry, except for chromium and copper ilmenenes, which show structural deformations of the perfect lattice due to the Jahn-Teller eﬀect ...

work page
[4]

Conclusion In this work, we have analyzed the structural, electronic and magnetic properties of TM ilmenene-like systems. Our calculations reveal that most of the materials under analysis present a triangular crystalline structure for TMs, with an ironed compression of the internal titanium ion layer with respect to bulk. The chromium and copper ilmenenes...

work page
[5]

Data availability statement All data that support the ﬁndings of this study are included within the article (and any supplementary ﬁles)

work page
[6]

We acknowledge ﬁnancial support by the European Commission from the NRG-STORAGE project (GA 870114)

Acknowledgement This work has been supported by the Spanish Ministry of Science and Innovation with PID2019-105488GB-I00 and PCI2019-103657. We acknowledge ﬁnancial support by the European Commission from the NRG-STORAGE project (GA 870114). The Basque Government supported this work through Project No. IT-1569-22. M.A was supported by the Spanish Ministry...

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Arruabarrena M, Leonardo A, Rodriguez-Vega M, Fiete G A and Ayuela A 2022 Phys. Rev. B 105(14) 144425 URL https://link.aps.org/doi/10.1103/PhysRevB.105.144425 Magnetism in Two-Dimensional Ilmenenes 9

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Elliot M, McClarty P, Prabhakaran D, Johnson R, Walker H, Manuel P and Coldea R 2021 Nature Communications 12 3936

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FM” Ferromagnetic, “AFM-1

Yuan B, Khait I, Shu G J, Chou F C, Stone M B, Clancy J P, Paramekanti A and Kim Y J 2020 Phys. Rev. X 10(1) 011062 URL https://link.aps.org/doi/10.1103/PhysRevX.10.011062 Figure 1. Magnetic unit cell for transition metal ended ilmenene-like systems: (a) symmetric for most ilmenenes, and (b) distorted for chromium titanate CrTiO 3. The color code of the a...

work page doi:10.1103/physrevx.10.011062 2020

[1] [1]

Magnetism in Two-Dimensional Ilmenenes: Intrinsic Order and Strong Anisotropy

Introduction Technology for synthesizing two-dimensional materials has greatly improved in recent years. Since the synthesis of graphene[1, 2], a large number of extensive systems only a few atoms thick have been obtained. The study of these 2D materials has brought new physical phenomena with countless applications into play, like their magnetic properti...

work page internal anchor Pith review Pith/arXiv arXiv 2022

[2] [2]

For the exchange and correlation potential we use the Perdew-Burke-Ernzerhof form of the generalized gradient approximation (GGA), with the formulation of Dudarev[16] for GGA+U

Model Details In this work, we study the structural, electronic and magnetic properties of ilmenene- type materials using the projector augmented wave method (PAW) implemented in the Vienna Ab-initio Software Package (VASP)[14, 15]. For the exchange and correlation potential we use the Perdew-Burke-Ernzerhof form of the generalized gradient approximation ...

work page

[3] [3]

Structural properties The structure of the TM ilmenenes is graphically depicted from two viewpoints in Fig

Results and discussion 3.1. Structural properties The structure of the TM ilmenenes is graphically depicted from two viewpoints in Fig. 1. After structural relaxations, we ﬁnd that most of the compounds keep the input symmetry, except for chromium and copper ilmenenes, which show structural deformations of the perfect lattice due to the Jahn-Teller eﬀect ...

work page

[4] [4]

Conclusion In this work, we have analyzed the structural, electronic and magnetic properties of TM ilmenene-like systems. Our calculations reveal that most of the materials under analysis present a triangular crystalline structure for TMs, with an ironed compression of the internal titanium ion layer with respect to bulk. The chromium and copper ilmenenes...

work page

[5] [5]

Data availability statement All data that support the ﬁndings of this study are included within the article (and any supplementary ﬁles)

work page

[6] [6]

We acknowledge ﬁnancial support by the European Commission from the NRG-STORAGE project (GA 870114)

Acknowledgement This work has been supported by the Spanish Ministry of Science and Innovation with PID2019-105488GB-I00 and PCI2019-103657. We acknowledge ﬁnancial support by the European Commission from the NRG-STORAGE project (GA 870114). The Basque Government supported this work through Project No. IT-1569-22. M.A was supported by the Spanish Ministry...

work page 2017

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Novoselov K S, Geim A K, Morozov S V, Jiang D, Zhang Y, Dubonos S V, Grigorieva I V and Firsov A A 2004 Science 306 666–669

work page 2004

[8] [8]

Geim A K and Novoselov K S 2007 Nature Materials 6 183–191

work page 2007

[9] [9]

2017 Nature 546 265–269

Gong C, Li L, Li Z, Ji H, Stern A, Xia Y, Cao T, Bao W, Wang C, Wang Y et al. 2017 Nature 546 265–269

work page 2017

[10] [10]

2017 Nature 546 270–273

Huang B, Clark G, Navarro-Moratalla E, Klein D R, Cheng R, Seyler K L, Zhong D, Schmidgall E, McGuire M A, Cobden D H et al. 2017 Nature 546 270–273

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Mermin N D and Wagner H 1966 Phys. Rev. Lett. 17(22) 1133–1136

work page 1966

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Nikolaev K R, Dobin A Y, Krivorotov I N, Cooley W K, Bhattacharya A, Kobrinskii A L, Glazman L I, Wentzovitch R M, Dahlberg E D and Goldman A M 2000Phys. Rev. Lett. 85(17) 3728–3731

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Gareev R R, B¨ urgler D E, Buchmeier M, Olligs D, Schreiber R and Gr¨ unberg P 2001Phys. Rev. Lett. 87(15) 157202

work page

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Baibich M N, Broto J M, Fert A, Van Dau F N, Petroﬀ F, Etienne P, Creuzet G, Friederich A and Chazelas J 1988 Phys. Rev. Lett. 61(21) 2472–2475

work page 1988

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Binasch G, Gr¨ unberg P, Saurenbach F and Zinn W 1989 Phys. Rev. B 39(7) 4828–4830

work page 1989

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Li X W, Gupta A, McGuire T R, Duncombe P R and Xiao G 1999 Journal of Applied Physics 85 5585–5587

work page 1999

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Taylor J M, Markou A, Lesne E, Sivakumar P K, Luo C, Radu F, Werner P, Felser C and Parkin S S P 2020 Phys. Rev. B 101(9) 094404

work page 2020

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Puthirath Balan A, Radhakrishnan S, Woellner C F and et al 2018 Nature Nanotech 13 602–609

work page 2018

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Puthirath Balan A, Radhakrishnan S, Kumar R, Neupane R, Sinha S K, Deng L, de los Reyes C A, Apte A, Rao B M, Paulose M, Vajtai R, Chu C W, Costin G, Mart´ ı A A, Varghese O K, Singh A K, Tiwary C S, Anantharaman M R and Ajayan P M 2018 Chemistry of Materials 30 5923–5931

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Kresse G and Furthm¨ uller J 1996Phys. Rev. B 54(16) 11169–11186

work page

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Kresse G and Joubert D 1999 Phys. Rev. B 59(3) 1758–1775

work page 1999

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Dudarev S L, Botton G A, Savrasov S Y, Humphreys C J and Sutton A P 1998 Phys. Rev. B 57(3) 1505–1509

work page 1998

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Aguilera-Granja F and Ayuela A 2020 The Journal of Physical Chemistry C 124 2634–2643

work page 2020

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Lany S 2015 Journal of Physics: Condensed Matter 27 283203 URL https://doi.org/10.1088/ 0953-8984/27/28/283203

work page 2015

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Lany S, Raebiger H and Zunger A 2008 Phys. Rev. B 77(24) 241201 URL https://link.aps. org/doi/10.1103/PhysRevB.77.241201

work page doi:10.1103/physrevb.77.241201 2008

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Morgan B J and Watson G W 2009 Phys. Rev. B 80(23) 233102

work page 2009

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Huang X, Ramadugu S K and Mason S E 2016 The Journal of Physical Chemistry C 120 4919– 4930

work page 2016

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Jiang L, Levchenko S V and Rappe A M 2012 Phys. Rev. Lett. 108(16) 166403

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Gou G Y, Bennett J W, Takenaka H and Rappe A M 2011 Phys. Rev. B 83(20) 205115 URL https://link.aps.org/doi/10.1103/PhysRevB.83.205115

work page doi:10.1103/physrevb.83.205115 2011

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Kutzelnigg W 1993 Angewandte Chemie International Edition in English 32 128–129

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Henkelman G, Arnaldsson A and J´ onsson H 2006 Computational Materials Science 36 354–360 ISSN 0927-0256

work page 2006

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Arruabarrena M, Leonardo A, Rodriguez-Vega M, Fiete G A and Ayuela A 2022 Phys. Rev. B 105(14) 144425 URL https://link.aps.org/doi/10.1103/PhysRevB.105.144425 Magnetism in Two-Dimensional Ilmenenes 9

work page doi:10.1103/physrevb.105.144425 2022

[33] [33]

Elliot M, McClarty P, Prabhakaran D, Johnson R, Walker H, Manuel P and Coldea R 2021 Nature Communications 12 3936

work page 2021

[34] [34]

FM” Ferromagnetic, “AFM-1

Yuan B, Khait I, Shu G J, Chou F C, Stone M B, Clancy J P, Paramekanti A and Kim Y J 2020 Phys. Rev. X 10(1) 011062 URL https://link.aps.org/doi/10.1103/PhysRevX.10.011062 Figure 1. Magnetic unit cell for transition metal ended ilmenene-like systems: (a) symmetric for most ilmenenes, and (b) distorted for chromium titanate CrTiO 3. The color code of the a...

work page doi:10.1103/physrevx.10.011062 2020