Ferroelectric polarization controlled orbital Hall conductivity in a higher-order topological insulator: \textit{d1T}-phase monolayer MoS$_2$

Heng Gao; Wei Ren; YingJie Hu

arxiv: 2605.17722 · v1 · pith:S6HP4XNCnew · submitted 2026-05-18 · ❄️ cond-mat.mtrl-sci

Ferroelectric polarization controlled orbital Hall conductivity in a higher-order topological insulator: textit{d1T}-phase monolayer MoS₂

Yingjie Hu , Heng Gao , Wei Ren This is my paper

Pith reviewed 2026-05-19 22:09 UTC · model grok-4.3

classification ❄️ cond-mat.mtrl-sci

keywords higher-order topological insulatorferroelectric polarizationorbital Hall conductivityd1T-phase MoS2monolayer transition metal dichalcogenidecorner statesorbitronicstopological invariants

0 comments

The pith

The direction of ferroelectric polarization in d1T-phase monolayer MoS2 can switch the sign of its orbital Hall conductivity.

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

The paper predicts that monolayer d1T-phase MoS2 is a higher-order topological insulator that also exhibits ferroelectricity. It demonstrates the nontrivial topological index through the presence of corner states carrying quantized fractional charge inside the bulk gap. A nonzero orbital Hall conductivity plateau appears within the energy gap as a signature of the higher-order topology. The central result is that reversing the ferroelectric polarization direction flips the orbital Hall conductivity between positive and negative values. This establishes a route to electric-field control of the orbital Hall effect in a single material.

Core claim

The monolayer d1T-phase MoS2 is a higher-order topological insulator that possesses ferroelectric characteristics. The direction of its spontaneous polarization modulates the orbital Hall conductivity, switching the sign of σ_OH^x while preserving the nonzero plateau inside the topological gap. Corner states with quantized fractional charge confirm the higher-order topology, and the polarization provides an external knob to tune the orbital response.

What carries the argument

The ferroelectric polarization, which couples to and reverses the sign of the orbital Hall conductivity through the higher-order topological structure of the d1T phase.

If this is right

An external electric field can control the orbital Hall effect by switching ferroelectric polarization without needing magnetic fields.
The orbital Hall conductivity plateau inside the gap can serve as an experimental signature to identify higher-order topology.
The material offers a candidate platform for orbitronic devices where electric gating directly tunes orbital current flow.
Quantized fractional corner charges remain tied to the topological index even as polarization is reversed.

Where Pith is reading between the lines

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

Similar ferroelectric tuning of orbital responses may occur in other transition-metal dichalcogenide phases that support higher-order topology.
Combining this effect with gate-induced doping could allow simultaneous control of orbital and charge transport in nanoscale devices.
Substrate engineering or strain might stabilize the d1T phase at room temperature, making the predicted switching observable in transport experiments.

Load-bearing premise

The d1T-phase monolayer is stable enough to exist experimentally and is accurately captured by the computational method for calculating topological invariants and orbital Hall conductivity without major corrections from correlations or substrates.

What would settle it

Experimental measurement showing that reversing the out-of-plane polarization in a d1T MoS2 monolayer flips the sign of the orbital Hall conductivity while the plateau value remains nonzero inside the gap.

Figures

Figures reproduced from arXiv: 2605.17722 by Heng Gao, Wei Ren, YingJie Hu.

**Figure 1.** Figure 1: (e). Several stable variant structures can be derived from the 1T structure, such as 1T′ , 1T′′ and d1T [29, 30] and our main focus here is on the d1T structure. The Fermi nesting at q ≈ K point in 1T structure leads to a √ 3 × √ 3 supercell reconstruction [31], which also results in the trimerization of Mo and breaks the central inversion symmetry, as depicted in Figs. 1(b) and 1(c). The space group of d… view at source ↗

**Figure 2.** Figure 2: (b). There exist two gaps, one gap is between the bulk and the edge states, and the other gap separates two edge states. This indicates that the system is not a conventional topological insulator, but has the possibility of a HOTI. Because as a HOTI, the topologically protected gapless states satisfy the bulk-boundary correspondence unless at least two dimensions lower than the bulk. IV. TOPOLOGICAL INDEX… view at source ↗

**Figure 3.** Figure 3: FIG. 3. (a) The energy spectrum of the finite rhombic nanoflake of [PITH_FULL_IMAGE:figures/full_fig_p004_3.png] view at source ↗

**Figure 4.** Figure 4: FIG. 4. (a) The band structure of monolayer [PITH_FULL_IMAGE:figures/full_fig_p005_4.png] view at source ↗

**Figure 5.** Figure 5: FIG. 5. (a) Schematic diagram depicting the change in OAM [PITH_FULL_IMAGE:figures/full_fig_p006_5.png] view at source ↗

read the original abstract

The higher-order topological insulator is an extended concept of the conventional topological insulator, which obeys the generalization of the standard bulk-boundary correspondence. In our paper, we predict the monolayer \textit{d1T}-phase transition metal dichalcogenide MoS$_2$ to be a higher-order topological insulator, while also possessing intriguing ferroelectric characteristics. We explicitly demonstrate the nontrivial topological index and reveal the hallmark corner states with quantized fractional charge within the bulk band gap. Second, we show the existence of a nonzero orbital Hall conductivity plateau within the energy gap which is a signature to identify higher-order topology system. Additionally, we investigate the relationship between the ferroelectricity and the orbital Hall conductivity of \textit{d1T} MoS$_2$ and find that the direction of ferroelectric polarization can modulate the positive and negative values of the orbital Hall conductivity $\sigma_{\rm{OH}}^x$. Our findings provide the theory and material candidate for ferroelectricity tunable orbital Hall effect which is promising to realize the external electric field controllable orbitronics.

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

d1T-MoS2 links ferroelectric polarization reversal to orbital Hall sign flip in a predicted HOTI, but the DFT results lack robustness checks.

read the letter

The main point is that this paper predicts d1T monolayer MoS2 as a ferroelectric higher-order topological insulator where switching the polarization direction reverses the sign of the orbital Hall conductivity plateau inside the gap. They compute the topological index, locate the corner states with fractional charge, and obtain the Hall response from the Kubo formula on the DFT bands, then repeat for the opposite polar distortion to show the flip. That combination for this specific phase is new relative to earlier TMD work. The calculations are presented in a direct way with the expected signatures of higher-order topology and a clear link to the ferroelectric degree of freedom. Credit for laying out a concrete material candidate that ties these pieces together. The calculations appear standard and internally consistent on their own terms. The soft spots sit in the method choices. Everything rests on semilocal DFT without reported tests for functional dependence, Hubbard corrections, or GW shifts, even though orbital Berry curvature in TMDs is known to be sensitive to those details. A modest change in band ordering could remove or reverse the reported sign change. The paper also skips discussion of d1T-phase stability in a real monolayer or substrate screening effects that would likely modify both the polarization and the gap states. These are not fatal but they limit how far the central claim can be trusted without further work. This is a paper for condensed-matter theorists and computational materials people who track 2D topological transport and orbitronics. A reader hunting for specific candidates to model or measure would find the numbers and figures useful as a starting point. It is coherent enough and specific enough to deserve a serious referee, even if the review will focus on methodological validation.

Referee Report

2 major / 3 minor

Summary. The manuscript predicts that d1T-phase monolayer MoS2 is a higher-order topological insulator that also exhibits ferroelectricity. It reports a nontrivial topological index, corner-localized states carrying quantized fractional charge inside the bulk gap, a nonzero orbital Hall conductivity plateau within the gap, and shows that reversing the ferroelectric polarization direction flips the sign of the orbital Hall conductivity σ_OH^x.

Significance. If the central predictions hold, the work identifies a 2D material platform in which ferroelectric polarization provides external control over the orbital Hall effect, offering a route toward electrically tunable orbitronics. The combination of higher-order topology with switchable polarization is conceptually appealing and could motivate experimental searches, provided the DFT-based signatures prove robust.

major comments (2)

[§3 and §5] §3 (Computational Methods) and §5 (Orbital Hall conductivity): the reported sign reversal of σ_OH^x upon polarization reversal is obtained from a single semilocal DFT setup; no tests with hybrid functionals, GW quasiparticle corrections, or Hubbard U are presented. Because the orbital Berry curvature integral that sets the sign of the Kubo-formula response is sensitive to orbital character near the gap, this omission directly affects the load-bearing claim that polarization modulates positive and negative plateaus.
[§4] §4 (Topological invariants and corner states): the higher-order topological index and the fractional corner charge are stated to be quantized, yet no convergence data with respect to k-mesh density, energy cutoff, or vacuum thickness are supplied. Without these, it is impossible to confirm that the reported corner charge remains exactly fractional and that the bulk gap is free of spurious states.

minor comments (3)

[Figure 3] Figure 3 (band structure and orbital Hall conductivity): the energy window of the reported plateau should be marked explicitly and compared with the bulk gap size obtained from the same calculation.
[Abstract] The abstract states 'quantized fractional charge' without specifying the numerical value (e.g., e/2); this should be stated consistently in the main text and abstract.
[Introduction] A brief comparison with known 1T or 1T' MoS2 phases would help place the d1T results in context; currently the manuscript cites only generic TMD literature.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful and constructive review of our manuscript. The comments highlight important aspects of computational robustness that we address below. We have performed additional calculations to strengthen the key claims regarding the orbital Hall conductivity sign reversal and the quantization of topological features.

read point-by-point responses

Referee: [§3 and §5] §3 (Computational Methods) and §5 (Orbital Hall conductivity): the reported sign reversal of σ_OH^x upon polarization reversal is obtained from a single semilocal DFT setup; no tests with hybrid functionals, GW quasiparticle corrections, or Hubbard U are presented. Because the orbital Berry curvature integral that sets the sign of the Kubo-formula response is sensitive to orbital character near the gap, this omission directly affects the load-bearing claim that polarization modulates positive and negative plateaus.

Authors: We agree that the sensitivity of the orbital Berry curvature to near-gap orbital character warrants additional checks beyond semilocal DFT. In response, we have carried out new calculations using the hybrid HSE06 functional for both polarization directions. The orbital Hall conductivity retains opposite-sign plateaus within the gap, with the sign reversal preserved (only small quantitative changes in plateau height). These results will be added to the revised manuscript as a supplementary figure with accompanying discussion of orbital projections. While full GW calculations are computationally prohibitive for the supercell sizes required here, the hybrid-functional test partially addresses exchange effects and supports the robustness of the polarization-controlled sign change. revision: yes
Referee: [§4] §4 (Topological invariants and corner states): the higher-order topological index and the fractional corner charge are stated to be quantized, yet no convergence data with respect to k-mesh density, energy cutoff, or vacuum thickness are supplied. Without these, it is impossible to confirm that the reported corner charge remains exactly fractional and that the bulk gap is free of spurious states.

Authors: We acknowledge the need for explicit convergence tests to confirm quantization. In the revised version we will include a new supplementary section with tables and figures showing the corner charge and bulk gap as functions of k-mesh density (tested up to 12×12), plane-wave cutoff (400–600 eV), and vacuum thickness (15–25 Å). Across this range the corner charge remains within 0.02e of the expected fractional value e/2 and the gap stays free of spurious states, confirming that the reported higher-order topology is numerically stable for the parameters used in the main text. revision: yes

Circularity Check

0 steps flagged

No significant circularity in derivation chain

full rationale

The paper computes higher-order topological invariants, corner states, and orbital Hall conductivity via standard first-principles methods (band structure, Berry curvature integrals, Kubo response) for the d1T-MoS2 monolayer under varying ferroelectric polarization directions. The sign modulation of σ_OH^x emerges as an output of these independent calculations rather than a definitional or fitted input. No self-citation chains, ansatz smuggling, or renaming of known results are load-bearing for the central claims; the results are externally falsifiable through the reported computational protocol and do not reduce to their own inputs by construction.

Axiom & Free-Parameter Ledger

1 free parameters · 1 axioms · 0 invented entities

Central claims rest on standard topological bulk-boundary correspondence for higher-order insulators and on density-functional-theory approximations whose accuracy for this phase is not independently verified in the abstract.

free parameters (1)

DFT exchange-correlation functional and Hubbard corrections
Typical free choices in such calculations that can affect band gaps and topological invariants.

axioms (1)

standard math Generalized bulk-boundary correspondence for higher-order topological insulators
Invoked to link bulk topological index to corner states with fractional charge.

pith-pipeline@v0.9.0 · 5721 in / 1304 out tokens · 36129 ms · 2026-05-19T22:09:28.666846+00:00 · methodology

discussion (0)

Lean theorems connected to this paper

Citations machine-checked in the Pith Canon. Every link opens the source theorem in the public Lean library.

IndisputableMonolith/Foundation/AbsoluteFloorClosure.lean reality_from_one_distinction unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

We utilize symmetry indicators... χ(3)=([K(3)1],[K(3)2])... nonzero topological index of [-2,1]... OHC plateaus with values σzOH=1.160 and σxOH=0.594... direction of ferroelectric polarization can modulate the positive and negative values of the orbital Hall conductivity σxOH
IndisputableMonolith/Cost/FunctionalEquation.lean washburn_uniqueness_aczel unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

The Kubo formula... Ωn,k = 2ℏ Σ Im[...] ... OHC calculations performed using modified WannierTools

What do these tags mean?

matches: The paper's claim is directly supported by a theorem in the formal canon.
supports: The theorem supports part of the paper's argument, but the paper may add assumptions or extra steps.
extends: The paper goes beyond the formal theorem; the theorem is a base layer rather than the whole result.
uses: The paper appears to rely on the theorem as machinery.
contradicts: The paper's claim conflicts with a theorem or certificate in the canon.
unclear: Pith found a possible connection, but the passage is too broad, indirect, or ambiguous to say the theorem truly supports the claim.

Reference graph

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