Roughness-robust surface altermagnetism in $PT$ antiferromagnets

K. D. Belashchenko

arxiv: 2606.11128 · v1 · pith:LYH27TWOnew · submitted 2026-06-09 · ❄️ cond-mat.mtrl-sci · cond-mat.mes-hall

Roughness-robust surface altermagnetism in PT antiferromagnets

K. D. Belashchenko This is my paper

Pith reviewed 2026-06-27 12:16 UTC · model grok-4.3

classification ❄️ cond-mat.mtrl-sci cond-mat.mes-hall

keywords surface altermagnetismPT-symmetric antiferromagnetsrough surfacesspin-momentum correlationsLaue point groupspintronic functionalityantisymmetry space group

0 comments

The pith

PT-symmetric antiferromagnets retain surface altermagnetism after roughness averaging via the surface antisymmetry Laue point group.

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

The paper establishes that macroscopic spin-momentum correlations on rough surfaces of antiferromagnets are set by the surface antisymmetry Laue point group rather than local flat-terrace symmetry. This principle applies only to PT-symmetric antiferromagnets because any antisymmetry space group containing antitranslations forbids rough-surface altermagnetism. A sympathetic reader would care because the result indicates that realistic rough surfaces can still host altermagnetic transport while preserving bulk switchability, offering a practical path to spintronic devices. Roughness can itself generate compensated altermagnets, raise surface symmetry, or suppress splitting by restoring invariant symmetries.

Core claim

Surface altermagnetism extends spin splitting through symmetry reduction at surfaces. On rough surfaces the surviving macroscopic spin-momentum correlations are governed by the surface antisymmetry Laue point group. Rough-surface altermagnetism is forbidden wherever the antisymmetry space group contains antitranslations, so the classification reduces to PT-symmetric antiferromagnets. Roughness can restore symmetries leaving the surface normal invariant, thereby generating compensated surface altermagnets from uncompensated flat terminations, increasing surface symmetry, or suppressing spin splitting.

What carries the argument

surface antisymmetry Laue point group, which fixes the allowed spin-momentum correlations after averaging over compensated rough surfaces

If this is right

Rough-surface altermagnetism is allowed exclusively in PT-symmetric antiferromagnets.
Roughness can convert uncompensated flat terminations into compensated surface altermagnets.
Roughness can raise surface symmetry and thereby suppress spin splitting.
Bulk switchability can be combined with altermagnetic surface transport even on realistic surfaces.

Where Pith is reading between the lines

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

Practical spintronic devices may not require atomically flat surfaces if the material is PT-symmetric.
Averaging arguments of this type could be applied to other surface-protected transport effects in magnetic systems.
Direct comparison of spin-resolved photoemission on deliberately roughened versus flat samples of a PT antiferromagnet would test the claim.

Load-bearing premise

The macroscopic spin-momentum correlations on rough surfaces are governed by the surface antisymmetry Laue point group after averaging over compensated rough surfaces.

What would settle it

Observation of spin-momentum splitting on a rough surface of an antiferromagnet whose antisymmetry space group contains antitranslations, or absence of splitting on a rough surface of a PT-symmetric antiferromagnet.

read the original abstract

Surface altermagnetism extends spin splitting beyond bulk altermagnets through symmetry reduction at surfaces and interfaces. An existing classification applies to the local symmetry of atomically flat surface terraces. The present paper addresses the symmetry of macroscopic spin-momentum correlations that survive averaging over compensated rough surfaces. These correlations are governed by the surface antisymmetry Laue point group. Rough-surface altermagnetism is forbidden at any surface of a magnet whose antisymmetry space group contains antitranslations, and the classification therefore reduces to $PT$-symmetric antiferromagnets. By restoring all symmetries leaving the surface normal invariant, roughness can generate compensated surface altermagnets from uncompensated flat terminations, increase the surface symmetry, or suppress spin splitting. By combining bulk switchability with altermagnetic surface transport properties, roughness-robust surface altermagnetism in $PT$-symmetric antiferromagnets provides a route toward spintronic functionality.

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 classifies roughness-robust surface altermagnetism as surviving only in PT antiferromagnets, controlled by the surface antisymmetry Laue point group after roughness averaging.

read the letter

This paper's core contribution is a symmetry classification showing that macroscopic spin-momentum correlations on rough surfaces of antiferromagnets are governed by the surface antisymmetry Laue point group. It reduces the problem to PT-symmetric cases because antitranslations forbid the effect, and it explains how roughness averaging can generate compensated altermagnets from uncompensated flat terminations or suppress splitting while preserving bulk switchability.

The work does a straightforward job applying standard point-group and space-group ideas to extend the existing flat-terrace classification. No free parameters or fitted quantities appear, and the logic stays internal to symmetry selection rules.

The main soft spot is the central assumption that averaging over compensated roughness leaves only the Laue group in charge of the surviving correlations. The abstract states this clearly, but without the explicit symmetry tables or worked examples from the full text it is difficult to judge how general the rules are or whether specific roughness statistics introduce extra constraints. If those derivations are careful, the claim holds; if they rest on unstated averaging details, the generality narrows.

This is for theorists and experimentalists working on altermagnetic spintronics who need design rules for real, non-ideal surfaces. A reader focused on symmetry classifications of magnetic surfaces will extract concrete selection rules from it.

It deserves peer review so the group-theory steps can be checked in detail.

Referee Report

1 major / 0 minor

Summary. The manuscript claims that macroscopic spin-momentum correlations on rough surfaces of PT antiferromagnets are controlled by the surface antisymmetry Laue point group after averaging over compensated roughness. This forbids roughness-robust surface altermagnetism whenever the antisymmetry space group contains antitranslations, reducing the classification to PT-symmetric antiferromagnets. Roughness is shown to restore or suppress surface spin splitting while preserving bulk switchability, thereby offering a symmetry-based route to spintronic functionality.

Significance. If the symmetry classification holds, the work supplies a parameter-free, group-theoretic framework that extends altermagnetism to realistic (rough) surfaces without sacrificing bulk properties. This is a clear strength: the result is falsifiable via Laue-group selection rules and directly testable in candidate PT antiferromagnets.

major comments (1)

[Abstract] The central claim rests on the assertion that averaging over compensated rough surfaces leaves only the surface antisymmetry Laue point group. No explicit derivation, character table, or example mapping from a PT space group to the resulting Laue group is visible in the provided text, making it impossible to confirm that the stated selection rules (forbidding the effect with antitranslations) follow from the averaging procedure.

Simulated Author's Rebuttal

1 responses · 0 unresolved

We thank the referee for their careful reading of the manuscript. We address the single major comment below.

read point-by-point responses

Referee: [Abstract] The central claim rests on the assertion that averaging over compensated rough surfaces leaves only the surface antisymmetry Laue point group. No explicit derivation, character table, or example mapping from a PT space group to the resulting Laue group is visible in the provided text, making it impossible to confirm that the stated selection rules (forbidding the effect with antitranslations) follow from the averaging procedure.

Authors: We agree that an explicit derivation of the averaging procedure and its projection onto the surface antisymmetry Laue point group is not sufficiently detailed in the current text. In the revised manuscript we will add a dedicated appendix containing the step-by-step group-theoretic derivation, the relevant character tables, and a concrete mapping from a representative PT space group (e.g., one containing antitranslations) to the resulting Laue group. This will make the selection rules and the prohibition on roughness-robust surface altermagnetism fully traceable. revision: yes

Circularity Check

0 steps flagged

Symmetry classification is self-contained with no circular reductions

full rationale

The paper presents a symmetry classification for macroscopic spin-momentum correlations on rough surfaces of PT antiferromagnets, governed by the surface antisymmetry Laue point group after averaging. This follows directly from standard application of point-group and space-group symmetry to forbid or allow effects based on the presence of antitranslations, with no free parameters, numerical fits, or equations that reduce predictions to inputs by construction. No load-bearing self-citations or ansatzes are invoked in the provided derivation chain; the result is internally derived from symmetry principles and remains independent of any prior fitted quantities.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

Based on abstract only; the central claim rests on the domain assumption that the surface antisymmetry Laue point group controls averaged correlations. No free parameters or invented entities are mentioned.

axioms (1)

domain assumption Surface antisymmetry Laue point group governs the macroscopic spin-momentum correlations that survive averaging over compensated rough surfaces.
Invoked in the abstract as the principle that determines which correlations remain after roughness averaging.

pith-pipeline@v0.9.1-grok · 5695 in / 1234 out tokens · 19493 ms · 2026-06-27T12:16:38.090471+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

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[3]

2mz 1m[1¯10] 2m[110] SD-SAM [hk0] 22∥/2m d-wave [0kl] 22∥/2m d-wave 2¯3z 2my 0 [001] 1¯3z 2my i′-wave [h0l] 22∥/2m d-wave 2¯3z 1my 16[010] 22⊥/2mSD-SAM 16z/2m1[hk0] 22∥/2m d-wave 26z/1m1 [001] 26z/2mz SD-SAM 16z/2m2my 2mx 0 [001] 16z/1m2my 2mx i-wave
[4]

2mz 2mx 1my d-wave [hk0] 22∥/2m d-wave [h0l] 22∥/2m d-wave [0kl] 22∥/2m d-wave 16z/2mz 1my 1mx 0[100] 2mz 1my 2mx SD-SAM [hk0] 22∥/2m d-wave 26z/1mz 1my 2mx 0 [001] 26z/2mz 1my 2mx SD-SAM
[5]

1mz 2mx 2my SD-SAM [0kl] 22∥/2m d-wave 2mx 2¯3[111] 0[001] 2mx 2my 1mz d-wave [hk0] 22∥/2m d-wave 2mx 2¯3[111] 2md 0[001] 14z/1mz 2mx 2md g-wave
[6]

1¯3[111] 2md i′-wave
[7]

2mz 2m[1¯10] 1m[110] d-wave [hk0] 22∥/2m d-wave [hhl] 22∥/2m d-wave 2mx 2¯3[111] 1md 7[001] 24z/1mz 2mx 1md d-wave
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2mz 1m[1¯10] 2m[110] SD-SAM [hk0] 22∥/2m d-wave IV. DISCUSSION In contrast to the classification of Ref. [12] describ- ing local electronic structure on a single atomically flat terrace, the SALPGs listed in Table I describe macro- scopic spin-momentum correlations measured by probes that average over many terraces and terminations. This averaging has two...
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2mz 2m[1¯10] 1m[110] d-wave [hk0] 22∥/2m d-wave [h0l] 22∥/2m d-wave [hhl] 22∥/2m d-wave 14z/2m1mx 1md 17[100] 2mz 1my 2mx SD-SAM

[2] [2]

2mz 1m[1¯10] 2m[110] SD-SAM [hk0] 22∥/2m d-wave 24z/2m2mx 1md 67 [001] 24z/1m2mx 1md d-wave

[3] [3]

2mz 1m[1¯10] 2m[110] SD-SAM [hk0] 22∥/2m d-wave [0kl] 22∥/2m d-wave 2¯3z 2my 0 [001] 1¯3z 2my i′-wave [h0l] 22∥/2m d-wave 2¯3z 1my 16[010] 22⊥/2mSD-SAM 16z/2m1[hk0] 22∥/2m d-wave 26z/1m1 [001] 26z/2mz SD-SAM 16z/2m2my 2mx 0 [001] 16z/1m2my 2mx i-wave

[4] [4]

2mz 2mx 1my d-wave [hk0] 22∥/2m d-wave [h0l] 22∥/2m d-wave [0kl] 22∥/2m d-wave 16z/2mz 1my 1mx 0[100] 2mz 1my 2mx SD-SAM [hk0] 22∥/2m d-wave 26z/1mz 1my 2mx 0 [001] 26z/2mz 1my 2mx SD-SAM

[5] [5]

1mz 2mx 2my SD-SAM [0kl] 22∥/2m d-wave 2mx 2¯3[111] 0[001] 2mx 2my 1mz d-wave [hk0] 22∥/2m d-wave 2mx 2¯3[111] 2md 0[001] 14z/1mz 2mx 2md g-wave

[6] [6]

1¯3[111] 2md i′-wave

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2mz 2m[1¯10] 1m[110] d-wave [hk0] 22∥/2m d-wave [hhl] 22∥/2m d-wave 2mx 2¯3[111] 1md 7[001] 24z/1mz 2mx 1md d-wave

[8] [8]

DISCUSSION In contrast to the classification of Ref

2mz 1m[1¯10] 2m[110] SD-SAM [hk0] 22∥/2m d-wave IV. DISCUSSION In contrast to the classification of Ref. [12] describ- ing local electronic structure on a single atomically flat terrace, the SALPGs listed in Table I describe macro- scopic spin-momentum correlations measured by probes that average over many terraces and terminations. This averaging has two...

[9] [9]

Šmejkal, J

L. Šmejkal, J. Sinova, and T. Jungwirth, Emerging re- search landscape of altermagnetism, Phys. Rev. X12, 040501 (2022)

2022

[10] [10]

Mazin (The PRX Editors), Editorial: Altermagnetism—a new punch line of fundamental magnetism, Phys

I. Mazin (The PRX Editors), Editorial: Altermagnetism—a new punch line of fundamental magnetism, Phys. Rev. X12, 040002 (2022)

2022

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L. Bai, W. Feng, S. Liu, L. Šmejkal, Y. Mokrousov, and Y.Yao,Altermagnetism: Exploringnewfrontiersinmag- netism and spintronics, Advanced Functional Materials 34, 2409327 (2024)

2024

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work page doi:10.3390/magnetism5030017 2025

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2025

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Jungwirth, J

T. Jungwirth, J. Sinova, P. Wadley, D. Kriegner, H. Re- ichlova, F. Krizek, H. Ohno, and L. Smejkal, Altermag- netic spintronics (2025), arXiv:2508.09748

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2021

[16] [16]

H.-Y. Ma, M. Hu, N. Li, J. Liu, W. Yao, J.-F. Jia, and J. Liu, Multifunctional antiferromagnetic materials with giant piezomagnetism and noncollinear spin current, Nat. Commun.12, 2846 (2021)

2021

[17] [17]

H. Bai, L. Han, X. Y. Feng, Y. J. Zhou, R. X. Su, Q. Wang, L. Y. Liao, W. X. Zhu, X. Z. Chen, F. Pan, X. L. Fan, and C. Song, Observation of spin splitting torque in a collinear antiferromagnet RuO2, Phys. Rev. Lett.128, 197202 (2022)

2022

[18] [18]

Karube, T

S. Karube, T. Tanaka, D. Sugawara, N. Kadoguchi, M. Kohda, and J. Nitta, Observation of spin-splitter torque in collinear antiferromagneticRuO2, Phys. Rev. Lett.129, 137201 (2022)

2022

[19] [19]

Šmejkal, R

L. Šmejkal, R. González-Hernández, T. Jungwirth, and J. Sinova, Crystal time-reversal symmetry breaking and spontaneous Hall effect in collinear antiferromagnets, Sci. Adv.6, eaaz8809 (2020)

2020

[20] [20]

Lange, R

C. Lange, R. Jaeschke-Ubiergo, A. Chakraborty, X. H. Verbeek, L. Šmejkal, J. Sinova, and A. Mook, Emergent altermagnetism at surfaces of antiferromagnets: full sym- metry classification and material identification (2026), arXiv:2602.08773

Pith/arXiv arXiv 2026

[21] [21]

Sasioglu, I

E. Sasioglu, I. Mertig, and S. Lounis,d-wave surface al- termagnetism in centrosymmetric collinear antiferromag- nets (2026), arXiv:2602.08790

Pith/arXiv arXiv 2026

[22] [22]

Mencos, A

J. Mencos, A. Badura, E. Dolan, S. Beckert, R. Gonzalez- Hernandez, I. Kounta, M. Petit, C. Guillemard, A. B. Hellenes, W. Campos, J. Rial, D. Kriegner, V. Baltz, L. E. Hueso, J. Sinova, O. Gomonay, T. Jung- wirth, L. Smejkal, L. Michez, H. Reichlova, and F. Casanova, Direct demonstration of time-reversal- symmetry-breaking spin injection from a compensat...

arXiv 2025

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K. D. Belashchenko, Equilibrium magnetization at the boundary of a magnetoelectric antiferromagnet, Phys. Rev. Lett.105, 147204 (2010)

2010

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K. D. Belashchenko, Deterministic electrical switching in altermagnets via surface antisymmetry groups (2026), arXiv:2603.06537

Pith/arXiv arXiv 2026

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Heesch, Über die vierdimensionalen Gruppen des drei- dimensionalen Raumes, Z

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1930

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A. V. Shubnikov,Symmetry and Antisymmetry of Finite Figures(Izd. AN SSSR, Moscow, 1951) [Engl. transl. in Colored Symmetry, edited by W. T. Holser (MacMillan, New York, 1964)]

1951

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E. A. Turov, Can the magnetoelectric effect coexist with weak piezomagnetism and ferromagnetism?, Physics- Uspekhi37, 303 (1994)

1994

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Turek, Altermagnetism and magnetic groups with pseudoscalar electron spin, Phys

I. Turek, Altermagnetism and magnetic groups with pseudoscalar electron spin, Phys. Rev. B106, 094432 (2022)

2022

[29] [29]

Litvin and W

D. Litvin and W. Opechowski, Spin groups, Physica76, 538 (1974)

1974

[30] [30]

Šmejkal, J

L. Šmejkal, J. Sinova, and T. Jungwirth, Beyond conven- tional ferromagnetism and antiferromagnetism: A phase with nonrelativistic spin and crystal rotation symmetry, 5 Phys. Rev. X12, 031042 (2022)

2022

[31] [31]

S. V. Gallego, J. M. Perez-Mato, L. Elcoro, E. S. Tasci, R. M. Hanson, K. Momma, M. I. Aroyo, and G. Madariaga,MAGNDATA: towards a database of mag- neticstructures.I.Thecommensuratecase,J.Appl.Crys- tallogr.49, 1750 (2016)

2016

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Mazin, R

I. Mazin, R. González-Hernández, and L. Šmejkal, In- duced monolayer altermagnetism in mnp(s,se)3 and fese (2023), arXiv:2309.02355

arXiv 2023

[33] [33]

X. Chen, J. Ren, Y. Zhu, Y. Yu, A. Zhang, P. Liu, J. Li, Y. Liu, C. Li, and Q. Liu, Enumeration and representa- tion theory of spin space groups, Phys. Rev. X14, 031038 (2024)

2024

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