Superconductivity and non-Fermi liquid metals in a charge-1/3 anyon fluid

T. Senthil; Zhengyan Darius Shi

arxiv: 2606.20403 · v1 · pith:24PMAM3Xnew · submitted 2026-06-18 · ❄️ cond-mat.str-el · cond-mat.stat-mech· hep-th

Superconductivity and non-Fermi liquid metals in a charge-1/3 anyon fluid

Zhengyan Darius Shi , T. Senthil This is my paper

Pith reviewed 2026-06-26 15:24 UTC · model grok-4.3

classification ❄️ cond-mat.str-el cond-mat.stat-mechhep-th

keywords superconductivityanyon fluidfractional Chern insulatorcomposite fermionstopological ordernon-Fermi liquidorthogonal metalmoire materials

0 comments

The pith

Doping the 2/3 Jain fractional Chern insulator yields an SC* state with charge-2e condensation coexisting with residual Z2 topological order.

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

The paper examines the charge-1/3 anyon fluid created by doping the nu=2/3 Jain fractional Chern insulator. Secondary composite fermions appear in three translation-related flavors whose gauge-mediated interactions produce a robust inter-flavor pairing. The authors analyze the flavor-symmetric pairing channel and show that it realizes an SC* phase in which a charge-2e condensate sits alongside Z2 topological order. Weak and strong pairing versions share the same intrinsic topological order yet differ in chiral central charge. At low doping an approximate SU(3) regime instead produces a non-Fermi liquid Z3 orthogonal metal consisting of three charge-1/3 fermion pockets with no sharp electron quasiparticle.

Core claim

We revisit the charge-1/3 anyon fluid obtained by doping the nu = 2/3 Jain fractional Chern insulator. In the standard composite fermion description the doped anyons fractionalize into three translation-related flavors of secondary composite fermions whose gauge-mediated interactions drive a robust inter-flavor pairing instability. We consider an alternative flavor-symmetric paired state and show that it is an SC* state: a charge-2e condensate that coexists with residual Z2 topological order. The weak and strong pairing regimes share the same intrinsic topological order but differ in chiral central charge, giving c_- = 7/2 and c_- = 2. We further show how other proposed effective field theor

What carries the argument

Flavor-symmetric inter-flavor pairing instability among three translation-related flavors of secondary composite fermions, driven by gauge-mediated interactions.

If this is right

Across the doping-driven FCI-to-superconductor transition localized anyons evolve into Bogoliubov quasiparticles rather than vortices.
The SC* state maintains the same intrinsic topological order in both weak and strong pairing limits while the chiral central charge changes from 7/2 to 2.
Other proposed effective field theories for the doped system can be incorporated into the same composite fermion framework.
An approximate SU(3)-symmetric non-Fermi liquid Z3 Orthogonal Metal with three charge-1/3 pockets appears at low doping.

Where Pith is reading between the lines

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

Transport or thermodynamic measurements in moire materials could search for the coexistence of superconductivity and residual Z2 order as a signature of the SC* phase.
The absence of sharp electron quasiparticles in the low-doping orthogonal metal offers a concrete way to distinguish it from conventional Fermi liquids.
The composite-fermion organization may allow quantitative comparison of the energetics of the SC* state against competing charge-ordered or flavor-asymmetric phases.

Load-bearing premise

The gauge-mediated interactions between the three flavors of secondary composite fermions drive a robust inter-flavor pairing instability that selects the flavor-symmetric channel.

What would settle it

Observation of sharp electron quasiparticles persisting into the low-doping regime would rule out the Z3 Orthogonal Metal description.

Figures

Figures reproduced from arXiv: 2606.20403 by T. Senthil, Zhengyan Darius Shi.

read the original abstract

We revisit the charge-1/3 anyon fluid obtained by doping the $\nu = 2/3$ Jain fractional Chern insulator (FCI). In the standard composite fermion description, the doped anyons fractionalize into three translation-related flavors of secondary composite fermions, whose gauge-mediated interactions drive a robust inter-flavor pairing instability. In our previous work, we analyzed a flavor-asymmetric paired state and obtained a charge-ordered Fermi liquid. Inspired by a recent paper, we consider an alternative flavor-symmetric paired state and show that it is an SC* state: a charge-$2e$ condensate that coexists with residual $\mathbb{Z}_2$ topological order. The weak and strong pairing regimes share the same intrinsic topological order but differ in chiral central charge, giving $c_- = 7/2$ and $c_- = 2$. We further show how other proposed effective field theories fit within the same composite fermion description, and argue that across the doping driven FCI-to-superconductor transition, localized anyons evolve into Bogoliubov quasiparticles rather than vortices. At low doping, we identify an approximate SU(3)-symmetric regime in which the system instead realizes a non-Fermi liquid $\mathbb{Z}_3$ Orthogonal Metal with three charge-1/3 fermion pockets and no sharp electron quasiparticle. Finally, we comment on the energetics of various possible ground states and discuss implications for experiments in moire materials.

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 builds a flavor-symmetric SC* state and Z3 Orthogonal Metal on top of the composite-fermion description, but the key claim that gauge interactions select the symmetric pairing channel rests on an assertion without explicit calculation.

read the letter

The main new pieces are the construction of the flavor-symmetric paired state as an SC* superconductor (charge-2e condensate plus residual Z2 order) with two regimes differing only in chiral central charge (7/2 vs 2), plus the identification of the low-doping SU(3)-symmetric regime as a Z3 Orthogonal Metal with three charge-1/3 pockets and no sharp electron quasiparticle. The authors also embed other effective theories into the same framework and argue that doped anyons become Bogoliubov quasiparticles rather than vortices across the FCI-to-SC transition.

This organizes doping-driven transitions in a concrete way and gives clear experimental implications for moire materials. The composite-fermion starting point is consistent with their earlier flavor-asymmetric work, so the extension is a natural next step.

The soft spot is exactly the one flagged in the stress test. The abstract states that gauge-mediated interactions between the three flavors drive a robust inter-flavor pairing instability that selects the symmetric channel, but no pairing kernel, eigenvalue comparison, or RG analysis is supplied to back that selection. Without that step the SC* identification, the shared topological order, the central-charge values, and the Orthogonal Metal all rest on an unverified assumption. If asymmetric channels or other cutoffs win, the rest of the story does not follow.

This is for people already inside the fractional Chern insulator and composite-fermion literature. It deserves a serious referee because the proposals are specific enough to be checked and the framework is internally coherent, even though the pairing instability needs explicit work.

Referee Report

2 major / 2 minor

Summary. The paper claims that doping the ν=2/3 Jain FCI produces a charge-1/3 anyon fluid in which three flavors of secondary composite fermions undergo gauge-mediated inter-flavor pairing. The flavor-symmetric channel yields an SC* state (charge-2e condensate coexisting with residual Z₂ topological order). Weak- and strong-pairing regimes share the same intrinsic topological order but differ in chiral central charge (c₋=7/2 and c₋=2). Localized anyons evolve into Bogoliubov quasiparticles across the FCI-to-superconductor transition. At low doping an approximate SU(3)-symmetric regime realizes a non-Fermi-liquid Z₃ Orthogonal Metal with three charge-1/3 fermion pockets. The work also embeds other proposed EFTs in the same CF framework and comments on energetics and moiré-material implications.

Significance. If the pairing-channel selection and topological identifications hold, the manuscript supplies a unified composite-fermion route from doped FCIs to SC* states and NFL metals, extending the authors’ prior flavor-asymmetric analysis and incorporating alternative EFTs. The explicit statements on anyon-to-quasiparticle evolution and the two values of c₋ constitute concrete, falsifiable content relevant to moiré experiments.

major comments (2)

[Abstract and introductory discussion of pairing instability] Abstract and the paragraph introducing the three flavors of secondary composite fermions: the claim that gauge-mediated interactions 'drive a robust inter-flavor pairing instability' that selects the flavor-symmetric channel is asserted without an explicit pairing kernel, RG flow, or eigenvalue comparison against asymmetric channels. This selection is load-bearing for the subsequent identification of the SC* state, the shared intrinsic topological order, the two values of c₋, and the Z₃ Orthogonal Metal.
[SC* state and topological order derivation] The section deriving the SC* state: the statement that weak- and strong-pairing regimes share the same intrinsic topological order while differing only in c₋ requires an explicit accounting of how the residual Z₂ order is preserved under the flavor-symmetric pairing and how the central charges are obtained from the composite-fermion spectrum.

minor comments (2)

[Throughout] Notation for topological orders (Z₂ versus ℤ_{2}) and newly introduced terms (SC*, Z₃ Orthogonal Metal) should be defined at first use and used consistently.
[Energetics and experimental implications] The final comments on energetics would be strengthened by at least qualitative comparison of energy scales between the proposed states and the flavor-asymmetric Fermi liquid of the authors’ prior work.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful reading and for highlighting the significance of the work. We address the two major comments below and indicate the revisions that will be made.

read point-by-point responses

Referee: [Abstract and introductory discussion of pairing instability] Abstract and the paragraph introducing the three flavors of secondary composite fermions: the claim that gauge-mediated interactions 'drive a robust inter-flavor pairing instability' that selects the flavor-symmetric channel is asserted without an explicit pairing kernel, RG flow, or eigenvalue comparison against asymmetric channels. This selection is load-bearing for the subsequent identification of the SC* state, the shared intrinsic topological order, the two values of c₋, and the Z₃ Orthogonal Metal.

Authors: We agree that the manuscript asserts the selection of the flavor-symmetric channel without a new explicit pairing kernel or RG eigenvalue analysis. This choice is motivated by the flavor-blind nature of the gauge-mediated interactions in the composite-fermion framework together with the topological requirements of the SC* state (as inspired by the referenced recent paper). We will revise the introductory discussion to state explicitly that a full microscopic channel comparison lies outside the present scope, while clarifying the symmetry-based rationale for focusing on the symmetric channel and its consequences for the subsequent constructions. revision: partial
Referee: [SC* state and topological order derivation] The section deriving the SC* state: the statement that weak- and strong-pairing regimes share the same intrinsic topological order while differing only in c₋ requires an explicit accounting of how the residual Z₂ order is preserved under the flavor-symmetric pairing and how the central charges are obtained from the composite-fermion spectrum.

Authors: We will expand the SC* derivation section to supply the requested step-by-step accounting. The residual Z₂ order follows from the fact that the flavor-symmetric pairing condenses charge-2e pairs while the underlying anyonic braiding phases of the charge-1/3 particles remain unbroken; the two values of c₋ are obtained by counting the chiral edge modes contributed by the three flavors of composite fermions in the weak-pairing (c₋=7/2) versus strong-pairing (c₋=2) regimes. The revised text will make this counting and the preservation of Z₂ explicit. revision: yes

Circularity Check

0 steps flagged

No significant circularity; derivation chain remains self-contained.

full rationale

The paper presents the flavor-symmetric paired state as a new construction analyzed within the standard composite-fermion framework, distinct from the authors' prior flavor-asymmetric analysis. Assertions regarding gauge-mediated pairing instability and resulting SC* topological order follow from the setup without reducing to self-definition, fitted inputs renamed as predictions, or load-bearing self-citations that substitute for independent content. No equations or steps exhibit the specific reductions required for circularity flags under the enumerated patterns.

Axiom & Free-Parameter Ledger

0 free parameters · 2 axioms · 2 invented entities

The analysis rests on standard domain assumptions of composite-fermion theory applied to doped Jain states and on the existence of robust gauge-mediated pairing; no explicit free parameters or new particles are introduced, only new phase identifications.

axioms (2)

domain assumption The composite fermion description applies to the doped anyon fluid obtained from the ν=2/3 Jain FCI.
Invoked to fractionalize anyons into three flavors whose interactions drive pairing.
domain assumption Gauge-mediated interactions between flavors produce a robust inter-flavor pairing instability.
Used to select the paired states analyzed.

invented entities (2)

SC* state no independent evidence
purpose: Describes coexistence of charge-2e superconductivity and residual Z2 topological order.
New phase label and properties proposed for the flavor-symmetric paired regime.
Z3 Orthogonal Metal no independent evidence
purpose: Describes the low-doping non-Fermi liquid with three charge-1/3 fermion pockets.
New identification under approximate SU(3) symmetry.

pith-pipeline@v0.9.1-grok · 5808 in / 1560 out tokens · 32835 ms · 2026-06-26T15:24:30.933147+00:00 · methodology

discussion (0)

Reference graph

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arXiv 2025
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In this regime, the pair fields prefer to preserve theZ 3 flavor symmetry

Forv <2u, the repulsion between different pair fields is weak. In this regime, the pair fields prefer to preserve theZ 3 flavor symmetry
[73]

This fully polarized limit is the maximally flavor-symmetry breaking state

Forv >2u, the repulsion between pair fields is so strong that once one of them onsets, the other two prefer to vanish. This fully polarized limit is the maximally flavor-symmetry breaking state. From this analysis, we see that up to quartic order, there is no parameter regime in which the pair fields partially polarize. Partial polarization can arise when...

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Comments on energetics In both tMoTe 2 and the multilayer rhombohedral graphene platform, several Jain states as well as the Com- posite Fermi Liquid are seen. This experimental input suggests 7 that upon doping from 2/3 filling toward 1/2, the standard CF formalism is likely an excellent starting point in describing the energetics of existing experimen- ...

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In the adiabatic limit of the skyrmion crystal model for twisted MoTe2, Refs

Numerics Existing numerical works [64–66] mostly focus on a bandwidth-tuned transition at fixed filling from theν= 2/3 Jain FCI to a chiral topological superconductor with c− =−1/2. In the adiabatic limit of the skyrmion crystal model for twisted MoTe2, Refs. [64, 66] provide evidence that this transition is strongly first order, and assert that it has no...

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[38], as well as in Ref

Experiments Experimentally, superconductivity has been re- ported [63] near the 2/3 FQAH state in tMoTe2, and has been interpreted by us in Ref. [38], as well as in Ref. [37], in terms of anyon-driven superconductivity. Accepting thatsomeanyonic mechanism is at play, we can ask which of the various SCs summarized in Table I is actually re- alized. Unfortu...

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Beyond superconductivity Going beyond superconductivity, it will also be interesting to look for the SU(3)-symmetric Z3OM in the vicinity of the 2/3 or 1/3 FCI. This non-Fermi liquid metal has roughly the same Hall conductivity as the parent FCI but has a metallicρ xx, despite the absence of sharp peaks in the momentum-resolved electron spectral function....

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