Non-Local and Non-Markovian Effects of a Microscopic Two-Level Defect in Superconducting Quantum Circuits

Fei Yan; Feiyu Li; Haifeng Yu; He Wang; Huikai Xu; Jiayu Ding; Pan Shi; Ruixia Wang; Weijie Sun; Yang Gao

arxiv: 2605.23385 · v1 · pith:26QL547Enew · submitted 2026-05-22 · 🪐 quant-ph

Non-Local and Non-Markovian Effects of a Microscopic Two-Level Defect in Superconducting Quantum Circuits

Yang Gao , Yujia Zhang , Huikai Xu , Pan Shi , Feiyu Li , Yaqing Feng , Weijie Sun , Jiayu Ding

show 7 more authors

Yang Liu He Wang Ruixia Wang Zhen Yang Yirong Jin Haifeng Yu Fei Yan

This is my paper

Pith reviewed 2026-05-25 04:53 UTC · model grok-4.3

classification 🪐 quant-ph

keywords superconducting qubitstwo-level systemstunable couplernon-Markovian decoherence1/f noisequantum process tomographycorrelated errorsTLS-qubit coupling

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The pith

A coherent two-level defect inside a tunable coupler couples simultaneously to two distant superconducting qubits.

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

The paper reports the observation of a microscopic two-level system that sits inside the tunable coupler linking two superconducting qubits and interacts coherently with both at the same time. Because the coupler frequency can be adjusted, the strength of this interaction can be turned up or down on demand. This control lets the authors watch how the defect warps the qubits' time evolution and reconstruct the defect's frequency noise spectrum over more than ten orders of magnitude, from 0.1 mHz to 1 MHz. Quantum process tomography shows that the same defect produces correlated changes in the two qubits, acting as a source of non-Markovian noise. The results indicate that defects located in coupling elements can influence multiple qubits across a chip in ways that purely local decoherence models miss.

Core claim

We report the observation of a coherent TLS that couples simultaneously to two spatially distant superconducting qubits. The TLS is identified to reside within the tunable coupler linking the qubits, enabling controllability of the TLS-qubit coupling strength via coupler frequency. This tunability allows systematic probing of how the TLS distorts qubit dynamics, including reconstruction of the TLS frequency fluctuation spectrum as 1/f noise spanning more than ten orders of magnitude. Quantum process tomography further reveals TLS-induced correlated qubit dynamics, establishing the long-lived TLS as an effective source of non-Markovianity in the system.

What carries the argument

The tunable coupler that hosts the TLS, whose frequency sets the TLS-qubit coupling strength and thereby controls the non-local interaction.

If this is right

Defects embedded in coupling elements can simultaneously affect multiple qubits with variable impact.
System characterization and calibration must account for non-local TLS effects.
The tunable coupler provides a controllable testbed for studying defect-driven quantum dynamics.
Error suppression strategies and architecture design for scalable processors need to address non-local, non-Markovian contributions from couplers.

Where Pith is reading between the lines

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

Larger processors may contain hidden coupler defects that create unexpected long-range correlated errors not captured by local noise models.
Routine calibration sequences could be extended to sweep coupler frequencies and isolate individual TLS signatures in situ.
The same hardware could serve as an experimental platform for testing multi-qubit non-Markovian noise mitigation techniques.
Architecture layouts may need to treat couplers as potential multi-qubit noise hubs rather than passive connectors.

Load-bearing premise

The observed coherent coupling, tunability, and correlated dynamics all arise from one TLS located inside the tunable coupler rather than from other defects or mechanisms.

What would settle it

If the strength of the observed TLS-qubit interaction showed no dependence on the coupler frequency, or if process tomography found no correlated evolution between the two qubits, the claim that a single controllable TLS resides in the coupler would be ruled out.

Figures

Figures reproduced from arXiv: 2605.23385 by Fei Yan, Feiyu Li, Haifeng Yu, He Wang, Huikai Xu, Jiayu Ding, Pan Shi, Ruixia Wang, Weijie Sun, Yang Gao, Yang Liu, Yaqing Feng, Yirong Jin, Yujia Zhang, Zhen Yang.

**Figure 2.** Figure 2: FIG. 2 [PITH_FULL_IMAGE:figures/full_fig_p004_2.png] view at source ↗

**Figure 3.** Figure 3: FIG. 3 [PITH_FULL_IMAGE:figures/full_fig_p006_3.png] view at source ↗

**Figure 4.** Figure 4: FIG. 4 [PITH_FULL_IMAGE:figures/full_fig_p007_4.png] view at source ↗

read the original abstract

Microscopic two-level systems (TLS) -- ubiquitous atomic-scale defects in solid-state quantum devices -- are a dominant source of qubit decoherence, yet their role is often considered local and short-memoried. Here, we report the observation of a coherent TLS that couples simultaneously to two spatially distant superconducting qubits. The TLS is identified to reside within the tunable coupler linking the qubits, enabling controllability of the TLS-qubit coupling strength via coupler frequency -- a capability absent in earlier studies. This tunability allows us to systematically probe how TLS distorts qubit dynamics, revisiting the decoherence model in the presence of non-Markovian TLS dephasing noise. This is corroborated by the reconstructed $1/f$ noise spectrum of TLS frequency fluctuation spanning more than ten orders of magnitude (0.1\,mHz -- 1\,MHz) that reveals discrete fluctuator signatures. Quantum process tomography further unveils TLS-induced correlated qubit dynamics, highlighting the long-lived TLS as an effective source of non-Markovianity. Our findings expose a previously overlooked interaction mechanism in scalable quantum architectures: defects embedded in coupling elements can simultaneously affect multiple qubits with variable impact. Beyond immediate implications for system characterization and calibration, this situation provides a powerful testbed for studying defect-driven quantum dynamics, refining error suppression strategies, and advancing architecture design for scalable quantum technologies.

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 reports a TLS in a tunable coupler that couples two distant qubits with controllable strength, but the localization rests mainly on frequency tracking without clear exclusion of other defect sites.

read the letter

The main observation is a coherent TLS sitting in the tunable coupler between two qubits, letting them dial the coupling strength by shifting the coupler frequency. This produces simultaneous effects on both qubits and lets them map out non-Markovian signatures plus a 1/f spectrum from 0.1 mHz to 1 MHz. They also show correlated dynamics via process tomography. That combination of tunability and non-local reach is the concrete new piece; earlier TLS work in superconducting circuits has not had this kind of direct control through a coupler element. The experimental handle on the interaction is useful and the architecture implication (defects in couplers can hit multiple qubits) follows directly from the setup. The spectrum reconstruction and tomography are the parts that give the non-Markovian claim some weight, assuming the data stitching holds up. The soft spot is the TLS location. The claim that it resides inside the coupler depends on how the effective coupling changes with coupler frequency, but without independent qubit-frequency sweeps or explicit modeling that rules out a defect near one qubit whose influence is simply modulated by the coupler, other placements remain possible. The stress-test note flags exactly this, and it matters because the non-local and scalability conclusions rest on the assignment being correct. Minor issues include whether the ten-order spectrum combines different techniques without hidden assumptions or gaps, but that is secondary to the localization question. This is for people building multi-qubit devices who need to understand correlated decoherence sources. A reader focused on TLS physics or error-correction modeling would find the data worth checking. The work is grounded enough in a real device to merit referee time even if revisions are needed on the location evidence.

Referee Report

2 major / 1 minor

Summary. The paper reports the experimental observation of a coherent microscopic two-level system (TLS) that couples simultaneously to two spatially distant superconducting qubits. The TLS is identified as residing in the tunable coupler, which enables control of the TLS-qubit coupling strength by varying the coupler frequency. This setup is used to study non-Markovian TLS dephasing, reconstruct a 1/f noise spectrum of TLS frequency fluctuations over more than ten orders of magnitude (0.1 mHz to 1 MHz), and perform quantum process tomography to demonstrate TLS-induced correlated qubit dynamics.

Significance. If the single-TLS localization to the coupler and the supporting data hold, the result would be significant for exposing non-local defect effects in multi-qubit architectures and providing a controllable testbed for non-Markovian noise. The broad-band spectrum reconstruction and tomography results would strengthen the case for revisiting decoherence models in the presence of long-lived defects.

major comments (2)

[Main text (TLS identification and frequency-dependence analysis)] The central claim that the TLS resides specifically within the tunable coupler (rather than near one qubit or elsewhere) rests on the observed dependence of the effective coupling on coupler frequency. Without explicit modeling or independent variation of qubit frequencies to exclude qubit-local defects whose interaction is mediated by the coupler, alternative locations remain consistent with the data; this assignment is load-bearing for the non-local and architecture-implication conclusions.
[Spectrum reconstruction section] The reconstruction of the TLS frequency fluctuation spectrum spanning 0.1 mHz to 1 MHz is presented as revealing discrete fluctuator signatures, but the methods for combining measurements across this range, the fitting procedures, and error analysis are not detailed enough to assess whether the 1/f form and the ten-order span are robustly supported.

minor comments (1)

The abstract states the TLS is 'identified to reside within the tunable coupler' but the full manuscript should include a dedicated subsection explicitly addressing alternative defect locations and why they are ruled out.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful and constructive review. We address the two major comments point by point below, indicating revisions where the manuscript requires strengthening.

read point-by-point responses

Referee: [Main text (TLS identification and frequency-dependence analysis)] The central claim that the TLS resides specifically within the tunable coupler (rather than near one qubit or elsewhere) rests on the observed dependence of the effective coupling on coupler frequency. Without explicit modeling or independent variation of qubit frequencies to exclude qubit-local defects whose interaction is mediated by the coupler, alternative locations remain consistent with the data; this assignment is load-bearing for the non-local and architecture-implication conclusions.

Authors: We agree that the localization argument would be strengthened by explicit modeling. The manuscript shows that the effective TLS-qubit coupling varies systematically with coupler frequency while qubit frequencies remain fixed; this dependence is difficult to reconcile with a purely qubit-local TLS. Nevertheless, to exclude mediated alternatives rigorously, the revised manuscript will include a theoretical model comparing expected frequency dependence for coupler-embedded versus qubit-local TLS locations. We will also add supplementary data from independent qubit-frequency sweeps confirming that coupling changes occur only when the coupler frequency is varied. revision: yes
Referee: [Spectrum reconstruction section] The reconstruction of the TLS frequency fluctuation spectrum spanning 0.1 mHz to 1 MHz is presented as revealing discrete fluctuator signatures, but the methods for combining measurements across this range, the fitting procedures, and error analysis are not detailed enough to assess whether the 1/f form and the ten-order span are robustly supported.

Authors: We concur that the spectrum-reconstruction methods require fuller documentation. The revised manuscript will expand the relevant section to detail the procedures used to combine data from different time/frequency regimes, the fitting routines applied, and the complete error analysis. These additions will allow direct evaluation of the robustness of the reported 1/f spectrum and its span over more than ten orders of magnitude. revision: yes

Circularity Check

0 steps flagged

No circularity: experimental observation report with no derivation chain

full rationale

The paper is an experimental report of TLS observation in superconducting circuits, identifying location via frequency dependence of coupling. No mathematical derivations, fitted parameters renamed as predictions, self-citations as load-bearing uniqueness theorems, or ansatzes are present in the provided text. The central claims rest on direct measurements and process tomography rather than any reduction to inputs by construction. This is the most common honest finding for empirical observation papers, which are self-contained against external benchmarks.

Axiom & Free-Parameter Ledger

0 free parameters · 0 axioms · 0 invented entities

Abstract provides no explicit free parameters, axioms, or invented entities; the work is an experimental observation of known physical defects (TLS) with spectrum reconstruction likely involving unspecified fitting.

pith-pipeline@v0.9.0 · 5823 in / 1047 out tokens · 25638 ms · 2026-05-25T04:53:31.816455+00:00 · methodology

discussion (0)

Reference graph

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