pith. sign in

arxiv: 2605.18277 · v1 · pith:YLYJAZUFnew · submitted 2026-05-18 · ❄️ cond-mat.str-el · cond-mat.supr-con

Quantum geometry induced anomalous chiral transport and hidden symmetry breaking in centrosymmetric 2M-WS2

Hang Cui , Shao-Bo Liu , Erqing Wang , Mingxiang Pan , Yuqiang Fang , Ning Ma , Wenlong Liu , Di Chen
show 11 more authors
Yu Zhang Yuanjun Song Tingting Hao Jiankun Li Jian Cui Ya Feng Haiwen Liu Fuqiang Huang Huaqing Huang X.-C. Xie Jian-Hao Chen
This is my paper

Pith reviewed 2026-05-20 00:30 UTC · model grok-4.3

classification ❄️ cond-mat.str-el cond-mat.supr-con
keywords quantum geometrychiral transportelectronic magnetochiral anisotropystrange metal transitionNernst effect2M-WS2layer slidingcentrosymmetric materials
0
0 comments X

The pith

Nontrivial quantum geometry from thick-layer sliding produces chiral transport in centrosymmetric 2M-WS2

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

The paper establishes that a centrosymmetric material can display electronic magnetochiral anisotropy through nontrivial quantum geometry effects. Observations show this chiral transport signal strengthens near the crossover from Fermi-liquid to strange-metal behavior around 25 K and aligns with a large Nernst response in the bulk. The authors link both phenomena to orbital magnetic moment contributions that grow at the Fermi surface during the transition. They propose that a thick-layer-sliding mechanism with low energy cost generates the required quantum geometry without conventional inversion symmetry breaking. A reader would care because the result connects nonlinear transport, thermoelectric responses, and the strange-metal regime in one system that may relate to high-temperature superconductivity.

Core claim

Theoretical analysis indicates that nontrivial quantum geometry is behind the simultaneous response of eMChA and Nernst effects in 2M-WS2 and the contribution from the orbital magnetic moment at the Fermi surface becomes significant during the FL-SM transition. Based on first-principles calculations, a thick-layer-sliding mechanism with minimal energy gain in 2M-WS2 provides one possibility for the generation of such nontrivial quantum geometry.

What carries the argument

Thick-layer-sliding mechanism that generates nontrivial quantum geometry without breaking inversion symmetry in the conventional sense.

If this is right

  • The eMChA signal intensifies around the FL-SM crossover temperature of roughly 25 K.
  • The same quantum geometry accounts for the anomalously large Nernst response at that same temperature.
  • Orbital magnetic moment effects at the Fermi surface grow dominant once the system enters the strange-metal regime.
  • 2M-WS2 becomes a platform where chiral transport, Nernst response, and the strange-metal state are directly intertwined.

Where Pith is reading between the lines

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

  • Similar layer-sliding mechanisms could produce hidden quantum geometry and chiral responses in other centrosymmetric layered compounds with weak interlayer bonding.
  • Structural fluctuations that slide layers might represent a general route to effective symmetry breaking in topological materials that appear inversion-symmetric on average.
  • Low-temperature diffraction or scanning probes sensitive to interlayer registry could test whether sliding actually occurs near 25 K.

Load-bearing premise

The observed eMChA and its temperature dependence arise from quantum geometry generated by a thick-layer-sliding mechanism rather than from extrinsic effects, disorder, or conventional symmetry breaking.

What would settle it

First-principles calculations that remove the possibility of thick-layer sliding while still reproducing the observed eMChA and Nernst signals, or structural measurements showing no layer displacement at the relevant temperatures, would falsify the proposed origin.

read the original abstract

Chirality, a widely existing material property in nature involving the breaking of the left-right symmetry, has profound influences in various fields of natural sciences. Nonlinear response, such as electronic magnetochiral anisotropy (eMChA), has been recognized as a sensitive probe for the effects of symmetry breaking and nontrivial quantum geometries in solids. So far, observations of eMChA have primarily been limited to inversion-symmetry broken materials. Here, we report a remarkable chiral transport in centrosymmetric candidate topological superconductor 2M-WS2 flakes observed via second-harmonic generation under an out-of-plane magnetic field. More importantly, the eMChA becomes significant around the crossover temperature TFL ~ 25 K from the Fermi liquid (FL) to strange metal (SM) in the normal state, which interestingly echoes with the anomalously large Nernst response at the same temperature in bulk 2M-WS2. These observations reveal a direct correspondence between the nonlinear response, Nernst response, and FL-SM transition in 2M-WS2. Theoretical analysis indicates that nontrivial quantum geometry is behind the simultaneous response of eMChA and Nernst effects in 2M-WS2 and the contribution from the orbital magnetic moment at the Fermi surface becomes significant during the FL-SM transition. Based on first-principles calculations, a thick-layer-sliding mechanism with minimal energy gain in 2M-WS2 provides one possibility for the generation of such nontrivial quantum geometry. The intertwined physics of remarkable eMChA, Nernst response, and FL-SM transition make 2M-WS2 a rare quantum platform to study the chiral transport and unexplored phenomena in strange metals, which may shed light on the trans-century, unresolved scientific issue in unconventional high-temperature superconductivity.

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.

Referee Report

2 major / 2 minor

Summary. The manuscript reports observation of electronic magnetochiral anisotropy (eMChA) via second-harmonic generation in centrosymmetric 2M-WS2 flakes under out-of-plane magnetic field. The eMChA signal strengthens around the Fermi-liquid to strange-metal crossover at T_FL ≈ 25 K and correlates with the anomalously large Nernst response seen in bulk samples at the same temperature. Theoretical analysis attributes both responses to nontrivial quantum geometry, specifically the orbital magnetic moment contribution at the Fermi surface that grows during the FL-SM transition. First-principles calculations are presented as indicating that a thick-layer-sliding mechanism, despite minimal energy gain, offers one possible route to generating the required quantum geometry and hidden symmetry breaking in this centrosymmetric material.

Significance. If the quantitative connection between the computed quantum geometry and the measured transport amplitudes is established, the work would identify 2M-WS2 as a rare platform in which chiral nonlinear transport, thermoelectric anomalies, and strange-metal physics coexist without inversion-symmetry breaking. The experimental correlation between eMChA temperature dependence and the FL-SM crossover constitutes a concrete observation that could stimulate further studies of quantum-geometry effects in candidate topological superconductors.

major comments (2)
  1. [Theoretical analysis] Theoretical analysis section: the assertion that nontrivial quantum geometry underlies the simultaneous eMChA and Nernst responses is not supported by an explicit Kubo-formula evaluation or Fermi-surface integral that converts the first-principles orbital magnetic moment into the observed second-harmonic voltage amplitude or its temperature dependence.
  2. [First-principles calculations] First-principles calculations and discussion of layer sliding: the thick-layer-sliding mechanism is introduced only as 'one possibility' with minimal energy gain, yet no quantitative mapping is provided showing that the resulting Berry curvature dipole or orbital moment reproduces the measured eMChA magnitude or its peak near 25 K, leaving open whether extrinsic effects or conventional mechanisms could account for the data.
minor comments (2)
  1. [Abstract] Abstract and experimental section: error bars, raw data traces, and fitting procedures for the second-harmonic voltage versus magnetic field are not described, making it difficult to assess the statistical significance of the reported temperature dependence.
  2. [Theoretical analysis] Notation: the distinction between the orbital magnetic moment contribution and the Berry curvature dipole is not always clearly separated when discussing the Nernst and eMChA responses.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful reading of our manuscript and the constructive comments. We address each major comment below and indicate the revisions planned for the next version.

read point-by-point responses

  1. Referee: [Theoretical analysis] Theoretical analysis section: the assertion that nontrivial quantum geometry underlies the simultaneous eMChA and Nernst responses is not supported by an explicit Kubo-formula evaluation or Fermi-surface integral that converts the first-principles orbital magnetic moment into the observed second-harmonic voltage amplitude or its temperature dependence.

    Authors: We agree that the current theoretical discussion remains at a qualitative level, linking the growth of the orbital magnetic moment during the FL-SM crossover to both responses on the basis of first-principles results and the observed temperature correlation. A full numerical Kubo-formula evaluation that converts the computed orbital moment directly into the measured second-harmonic amplitude is not performed in the manuscript. In the revision we will add an expanded subsection that explicitly writes the relevant nonlinear conductivity expression in terms of the orbital magnetic moment and Fermi-surface integrals, citing the appropriate literature formulas, thereby clarifying the theoretical pathway without performing the complete numerical integration. revision: partial

  2. Referee: [First-principles calculations] First-principles calculations and discussion of layer sliding: the thick-layer-sliding mechanism is introduced only as 'one possibility' with minimal energy gain, yet no quantitative mapping is provided showing that the resulting Berry curvature dipole or orbital moment reproduces the measured eMChA magnitude or its peak near 25 K, leaving open whether extrinsic effects or conventional mechanisms could account for the data.

    Authors: The layer-sliding scenario is presented precisely as one energetically accessible route that can generate the required hidden symmetry breaking and orbital-moment enhancement in a centrosymmetric structure. The manuscript does not contain a quantitative Fermi-surface integral that maps the computed orbital moment onto the absolute eMChA voltage or its precise peak position at 25 K. We will revise the first-principles section to include a more detailed temperature-dependent plot of the orbital moment extracted from the calculations and a rough order-of-magnitude estimate connecting this moment to the scale of the observed nonlinear signal, while explicitly noting that extrinsic contributions cannot be ruled out on the basis of the present data alone. revision: yes

Circularity Check

0 steps flagged

No significant circularity in derivation chain

full rationale

The paper states that 'theoretical analysis indicates that nontrivial quantum geometry is behind the simultaneous response of eMChA and Nernst effects' and that 'a thick-layer-sliding mechanism with minimal energy gain in 2M-WS2 provides one possibility for the generation of such nontrivial quantum geometry.' This framing treats the sliding mechanism as an independent first-principles proposal rather than a quantity fitted to or defined by the transport data. No equations or sections in the provided text reduce a claimed prediction (e.g., second-harmonic voltage or temperature-dependent orbital moment) to a self-consistent fit or self-citation that is itself unverified. The link between geometry and observed responses is presented as an indication, not a closed derivation loop, leaving the central claim with independent content from the calculations.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 1 invented entities

The central claim rests on the domain assumption that quantum geometry can produce chiral transport in centrosymmetric crystals and on the ad-hoc proposal of a thick-layer-sliding mechanism whose independent falsifiability is not demonstrated in the abstract.

axioms (1)
  • domain assumption Nontrivial quantum geometry at the Fermi surface can generate orbital magnetic moment contributions that produce observable eMChA even when global inversion symmetry is preserved.
    Invoked to explain why eMChA appears in a centrosymmetric material and why it strengthens during the FL-SM transition.
invented entities (1)
  • thick-layer-sliding mechanism no independent evidence
    purpose: To generate the nontrivial quantum geometry responsible for the observed chiral transport.
    Introduced via first-principles calculations as one possible microscopic origin; no independent experimental signature is provided in the abstract.

pith-pipeline@v0.9.0 · 5937 in / 1542 out tokens · 50994 ms · 2026-05-20T00:30:52.265366+00:00 · methodology

discussion (0)

Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.