The effects of alloy disorder on strongly-driven flopping mode qubits in Si/SiGe

Charles Tahan; Mark Friesen; Merritt P. R. Losert; S. N. Coppersmith; Utkan G\"ung\"ord\"u

arxiv: 2512.19658 · v2 · pith:ZSE3WPSFnew · submitted 2025-12-22 · ❄️ cond-mat.mes-hall

The effects of alloy disorder on strongly-driven flopping mode qubits in Si/SiGe

Merritt P. R. Losert , Utkan G\"ung\"ord\"u , S. N. Coppersmith , Mark Friesen , Charles Tahan This is my paper

Pith reviewed 2026-05-21 16:42 UTC · model grok-4.3

classification ❄️ cond-mat.mes-hall

keywords flopping mode qubitsalloy disorderSi/SiGevalley splittingcharge noiseEDSRspin qubitsquantum dots

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The pith

Alloy disorder randomizes valley parameters in Si/SiGe but pulse fine-tuning still enables high-fidelity strongly driven flopping mode qubits across wide ranges when charge noise is weak, or with large splittings and small phase differences

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

The paper analyzes how alloy disorder in Si/SiGe heterostructures affects flopping mode spin qubits operated with strong electric driving. It finds that the disorder randomizes valley splittings and inter-dot phase differences, which opens leakage channels through valley excitations during tunneling between dots. When charge noise is weak, high-fidelity operation is possible for many valley configurations if the electronic pulse shape is optimized for each case. In the strong-noise regime, high fidelity remains achievable provided each dot has relatively large valley splitting and the phase difference between dots is small. The analysis also shows that strong driving reduces sensitivity to detuning fluctuations while increasing sensitivity to small valley-parameter shifts, and it outlines tuning strategies to avoid poor-performing configurations.

Core claim

In the presence of alloy disorder that randomizes valley energy splitting and phase difference between dots, strongly driven flopping mode qubits can achieve high fidelity by fine-tuning the electronic pulse for a given valley configuration when charge noise is weak, and by operating with large valley splittings and small phase differences when charge noise is strong; strongly driven pulses are less sensitive to inter-dot detuning fluctuations but more sensitive to valley parameter shifts, which can dominate infidelities, while device tuning schemes help avoid poor configurations.

What carries the argument

Optimization of the driving pulse under randomized valley splitting and inter-dot phase difference, which controls leakage via valley excitations during tunneling.

If this is right

High fidelity remains possible across a wide range of valley parameters with weak charge noise via pulse fine-tuning.
With strong charge noise, high fidelity requires large valley splittings in each dot and small valley phase difference.
Strongly driven pulses show reduced sensitivity to fluctuations in inter-dot detuning.
Small shifts in valley parameters can dominate infidelities in some regimes.
Tuning schemes can steer devices away from poor-performing valley configurations to improve scalability.

Where Pith is reading between the lines

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

Real devices may require on-the-fly pulse calibration based on measured valley splittings to maintain the predicted fidelities.
The approach could extend to arrays of coupled flopping-mode qubits where similar disorder effects accumulate across multiple dots.
Varying germanium concentration during growth offers a fabrication knob to test and reduce the modeled disorder statistics.
The reduced detuning sensitivity under strong driving may relax requirements on charge-noise filtering in cryogenic control electronics.

Load-bearing premise

The conclusions depend on a specific statistical model in which alloy disorder primarily randomizes valley splitting and inter-dot phase difference to open valley excitation leakage channels.

What would settle it

Measure gate fidelity in fabricated Si/SiGe devices while independently varying charge noise strength and valley parameter distributions to test whether the predicted high-fidelity regimes appear only under the modeled conditions.

Figures

Figures reproduced from arXiv: 2512.19658 by Charles Tahan, Mark Friesen, Merritt P. R. Losert, S. N. Coppersmith, Utkan G\"ung\"ord\"u.

**Figure 2.** Figure 2: Performance comparison of the three pulse families described in Sec. III, for the valley splitting values [PITH_FULL_IMAGE:figures/full_fig_p005_2.png] view at source ↗

**Figure 3.** Figure 3: Evaluation of the cosine pulse family for a range [PITH_FULL_IMAGE:figures/full_fig_p006_3.png] view at source ↗

**Figure 4.** Figure 4: Optimized wavefunction solutions, including the excited states, for each of the three pulse families (indicated at the [PITH_FULL_IMAGE:figures/full_fig_p008_4.png] view at source ↗

**Figure 5.** Figure 5: Locally varying valley splittings and valley phases [PITH_FULL_IMAGE:figures/full_fig_p009_5.png] view at source ↗

**Figure 7.** Figure 7: Schematic illustration of how charge noise causes [PITH_FULL_IMAGE:figures/full_fig_p010_7.png] view at source ↗

**Figure 8.** Figure 8: Infidelities due to δε and δ∆ fluctuations in the optimistic charge-noise regime, σε = 1 µeV. For each pulse family (rectangular, cosine, and charge-cosine, indicated at the top), we plot the expected infidelities due to δε fluctuations Iave (colored lines), as defined in Eq. (16), for (a) the favorable valley configuration EvL = EvR = 100 µeV, and (b) the unfavorable configuration EvL = EvR = 20 µeV, as … view at source ↗

**Figure 9.** Figure 9: Infidelities due to δε and δ∆ fluctuations in the pessimistic charge-noise regime, σε = 15 µeV. Except for this change in σε, all calculation procedures and plotting styles are the same as [PITH_FULL_IMAGE:figures/full_fig_p012_9.png] view at source ↗

**Figure 10.** Figure 10: By engineering some tunability into the qubit ar [PITH_FULL_IMAGE:figures/full_fig_p013_10.png] view at source ↗

**Figure 11.** Figure 11: Here, we illustrate the behavior of the three components to our cost function, [PITH_FULL_IMAGE:figures/full_fig_p017_11.png] view at source ↗

**Figure 12.** Figure 12: Comparison of infidelities and optimization results for different pulse shapes. For completeness, we include the same [PITH_FULL_IMAGE:figures/full_fig_p019_12.png] view at source ↗

**Figure 13.** Figure 13: In very unfavorable valley conditions, complicated [PITH_FULL_IMAGE:figures/full_fig_p019_13.png] view at source ↗

**Figure 14.** Figure 14: Comparison of effective detuning fluctuations due [PITH_FULL_IMAGE:figures/full_fig_p020_14.png] view at source ↗

**Figure 15.** Figure 15: Computation of the tunnel coupling distribution using effective mass simulations. (a) An example diagram of the [PITH_FULL_IMAGE:figures/full_fig_p023_15.png] view at source ↗

**Figure 16.** Figure 16: Estimating the size of tunnel coupling fluctuations due to charge noise. (a) Starting with a double-dot centered at [PITH_FULL_IMAGE:figures/full_fig_p023_16.png] view at source ↗

**Figure 18.** Figure 18: We plot Pfail, defined in Eq. 22, for linear arrays of quantum dots with size N. Each data point is computed from 10,000 instantiations of random alloy disorder, assuming Ev is uncorrelated between neighboring dots. Colors indicate the minimum Ge concentration Gmin, which we vary from 0 to 5 %. we then apply a tc fluctuation equal to ±1 µeV to the Hamiltonian, and we compute the resulting pulse infidelit… view at source ↗

read the original abstract

In Si quantum dot systems, large magnetic field gradients are needed to implement spin rotations via electric dipole spin resonance (EDSR). By increasing the effective electron dipole, flopping mode qubits can provide faster gates with smaller field gradients. Moreover, operating in the strong-driving limit can reduce their sensitivity to charge noise. However, alloy disorder in Si/SiGe heterostructures randomizes the valley energy splitting and the valley phase difference between dots, enhancing the probably of valley excitations while tunneling between the dots, and opening a leakage channel. In this work, we analyze the performance of flopping mode spin qubits in the presence of charge noise and alloy disorder, and we optimize these qubits for a variety of valley configurations, in both weak and strong charge-noise regimes. When the charge noise is weak, high fidelity qubits can be implemented across a wide range of valley parameters, provided the electronic pulse is fine-tuned for a given valley configuration. When the charge noise is strong, high-fidelity pulses can still be engineered, provided the valley splittings in each dot are relatively large and the valley phase difference is relatively small. We analyze how charge noise-induced fluctuations of the inter-dot detuning, as well as small shifts in other qubit parameters, impact qubit fidelities. We find that strongly driven pulses are less sensitive to detuning fluctuations but more sensitive to small shifts in the valley parameters, which can actually dominate the qubit infidelities in some regimes. Finally, we discuss schemes to tune devices away from poor-performing configurations, enhancing the scalability of flopping-mode-based qubit architectures.

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

Optimized pulses can keep flopping-mode qubits high-fidelity despite alloy disorder in Si/SiGe, but only within the limits of the specific disorder model.

read the letter

The main thing to know is that this paper finds workable pulse optimizations for strongly driven flopping-mode qubits that maintain high fidelity across a range of valley configurations when charge noise is weak, and that still work under strong noise if valley splittings are large and the inter-dot phase difference stays small. They show that strong driving reduces sensitivity to detuning fluctuations from charge noise but increases it to small shifts in valley parameters, which can end up dominating the error in some cases. They also outline tuning schemes to steer devices toward better-performing valley setups.

Referee Report

2 major / 3 minor

Summary. The manuscript examines strongly-driven flopping-mode spin qubits in Si/SiGe quantum dots, focusing on how alloy disorder randomizes valley splittings and inter-dot phase differences, thereby opening valley-excitation leakage channels during tunneling. Using numerical pulse optimization, the authors show that high-fidelity gates remain achievable across a broad range of valley parameters when charge noise is weak (with device-specific pulse tuning), and that high fidelities can still be engineered in the strong-noise regime provided valley splittings are large and the phase difference is small. They further quantify how detuning fluctuations and small valley-parameter shifts affect infidelity, finding that strong driving reduces detuning sensitivity but increases sensitivity to valley shifts, and outline device-tuning strategies to avoid poor configurations.

Significance. If the numerical results hold under the stated modeling assumptions, the work supplies concrete operating regimes and pulse-design guidelines that could improve the robustness of EDSR-based flopping-mode qubits against realistic Si/SiGe disorder. The explicit comparison of weak- versus strong-noise regimes and the identification of valley-parameter windows that remain high-fidelity even under strong charge noise constitute actionable information for experimental groups seeking scalable spin-qubit architectures.

major comments (2)

[§3] §3 (Disorder model and Hamiltonian): The central claim that high-fidelity pulses exist for large valley splittings and small phase differences in the strong-noise regime rests on the assumption that alloy disorder independently randomizes on-site valley splittings and the inter-dot phase difference, with leakage occurring primarily via valley excitations during tunneling. The manuscript should include a sensitivity analysis showing how the optimized fidelities change when the variance or spatial correlation length of the disorder distribution is varied by a factor of two; without this, the identified optimal regimes remain tied to the specific statistics chosen.
[§4.3] §4.3 (Sensitivity to parameter shifts): The statement that valley-parameter shifts can dominate infidelity under strong driving is load-bearing for the recommendation to fine-tune pulses to specific valley configurations. The quantitative contribution of a 10 % shift in valley splitting or phase to the total infidelity should be reported explicitly (e.g., as a separate curve or table entry) rather than only as a qualitative observation, so that readers can judge whether the effect exceeds the charge-noise contribution across the claimed parameter space.

minor comments (3)

[Abstract] Abstract, line 3: 'enhancing the probably of valley excitations' contains a typographical error and should read 'probability'.
[Figures] Figure captions and axis labels: Ensure that all fidelity color scales are identical across panels that are meant to be compared directly, and that the range of valley-splitting and phase-difference values is stated explicitly in every relevant figure caption.
[Throughout] Notation: The symbols used for the valley phase difference (e.g., φ_v) and the inter-dot detuning fluctuation should be defined once in the main text and used consistently thereafter; occasional redefinition in later sections reduces readability.

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 point below and have incorporated additional analyses to strengthen the presentation of our results.

read point-by-point responses

Referee: [§3] §3 (Disorder model and Hamiltonian): The central claim that high-fidelity pulses exist for large valley splittings and small phase differences in the strong-noise regime rests on the assumption that alloy disorder independently randomizes on-site valley splittings and the inter-dot phase difference, with leakage occurring primarily via valley excitations during tunneling. The manuscript should include a sensitivity analysis showing how the optimized fidelities change when the variance or spatial correlation length of the disorder distribution is varied by a factor of two; without this, the identified optimal regimes remain tied to the specific statistics chosen.

Authors: We agree that a sensitivity analysis would make the robustness of the reported regimes clearer. Our disorder model follows standard literature treatments for Si/SiGe that assume independent randomization of on-site valley splittings and inter-dot phase (effectively zero correlation length). We have performed additional optimizations in which the variance of the disorder distribution is scaled by a factor of two. The high-fidelity windows for large valley splittings and small phase differences remain qualitatively intact, with only modest quantitative shifts in the achieved fidelities. We will add these results as a supplementary figure and brief discussion in the revised manuscript. Explicit variation of a finite correlation length would require a modified disorder model; we note this limitation and its implications in the text. revision: yes
Referee: [§4.3] §4.3 (Sensitivity to parameter shifts): The statement that valley-parameter shifts can dominate infidelity under strong driving is load-bearing for the recommendation to fine-tune pulses to specific valley configurations. The quantitative contribution of a 10 % shift in valley splitting or phase to the total infidelity should be reported explicitly (e.g., as a separate curve or table entry) rather than only as a qualitative observation, so that readers can judge whether the effect exceeds the charge-noise contribution across the claimed parameter space.

Authors: We accept this suggestion. In the revised manuscript we will include an explicit table (and supporting curves) that isolates the infidelity contribution arising from a 10 % shift in valley splitting and from a 10 % shift in phase difference, for representative points in both the weak- and strong-noise regimes. These values will be compared directly with the infidelity due to charge-noise-induced detuning fluctuations alone, allowing readers to assess the relative magnitudes across the parameter space we consider. revision: yes

Circularity Check

0 steps flagged

No circularity; derivation self-contained via forward numerical modeling

full rationale

The paper performs numerical simulations of flopping-mode qubit dynamics under explicit models of alloy disorder (randomizing valley splittings and phases) and charge noise, followed by pulse optimization and fidelity evaluation across parameter regimes. No load-bearing step reduces a claimed prediction or result to a fitted input by construction, nor invokes self-citations or ansatzes that close the derivation on itself. The reported optimal regimes for weak and strong noise follow directly from the simulated leakage channels and sensitivity analysis, rendering the chain independent of its own outputs.

Axiom & Free-Parameter Ledger

2 free parameters · 1 axioms · 0 invented entities

The central claims depend on standard quantum-dot modeling assumptions plus the specific disorder model stated in the abstract; no new particles or forces are introduced.

free parameters (2)

valley splitting and phase difference
Treated as tunable or variable parameters across configurations that are optimized over in the analysis.
charge noise amplitude
Weak and strong regimes are defined by noise strength, implying parameters that set the scale of detuning fluctuations.

axioms (1)

domain assumption Alloy disorder randomizes valley energy splitting and valley phase difference between dots, enhancing valley excitation probability during tunneling
Directly stated in abstract as the mechanism opening a leakage channel.

pith-pipeline@v0.9.0 · 5840 in / 1356 out tokens · 74674 ms · 2026-05-21T16:42:08.345390+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/RealityFromDistinction.lean reality_from_one_distinction unclear

?

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

We start with an 8-level Hamiltonian spanned by the charge, spin, and valley degrees of freedom... optimize pulses... Monte Carlo simulation procedure... estimate the average infidelity caused by the Δ fluctuations
IndisputableMonolith/Cost/FunctionalEquation.lean washburn_uniqueness_aczel unclear

?

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

Alloy disorder... randomizes the valley energy splitting and the valley phase difference... leakage channel

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supports: The theorem supports part of the paper's argument, but the paper may add assumptions or extra steps.
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Forward citations

Cited by 3 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

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cond-mat.mes-hall 2026-04 unverdicted novelty 7.0

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Reference graph

Works this paper leans on

75 extracted references · 75 canonical work pages · cited by 2 Pith papers

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The work was performed using the compute re- sources and assistance of the UW-Madison Center For High Throughput Computing (CHTC) in the Depart- ment of Computer Sciences [51]. The CHTC is sup- ported by UW-Madison, the Advanced Computing Ini- tiative, the Wisconsin Alumni Research Foundation, the 15 Wisconsin Institutes for Discovery, and the National Sc...

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III in the main text, to develop high-fidelity pulses, we want to estimate the pulse sensi- tivity to charge noise

ComputingL charge As described in Sec. III in the main text, to develop high-fidelity pulses, we want to estimate the pulse sensi- tivity to charge noise. To do so, we utilize a formalism based on a general 2-level Hamiltonian [44, 52] H=H c +δH,(B1) whereH c is the desired (time-dependent) control Hamil- tonian, and the leakage term δH=χx(t)σx +χz(t)σz,(...

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Comparison of cost components In Fig. 11, we plot the components of the total cost Cin Eq. (13) for a variety of valley configurations. Here, we show results for the cosine pulse family, as- suming an optimisticσε= 1µeV. In Fig. 11(a), we assumeE vL =E vR = 100µeV, and in (b) we assume EvL =E vR = 20µeV. Each column represents a dif- ferent valley phase d...

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We represent the pulse parameters as a vectorp, which is op- timized with the Nelder-Mead method [53]

Randomization and re-optimization As described in the main text, in the second stage of our optimization procedure, we fine-tune the pulse parameters for each of the five best-performing pulse lengths through randomization and re-optimization. We represent the pulse parameters as a vectorp, which is op- timized with the Nelder-Mead method [53]. In order t...

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1D simulations To obtainσ∆ for a given heterostructure according to Eq. (7), we need to compute the envelope functionψenv. To do so, a 1D effective mass model suffices. We solve the 1D effective mass Hamiltonian H1D EM =T 1D +Uϕ+U qw,(E1) whereT 1D is a discretized 1D kinetic energy operator, Uϕ=eE zzis the potential due to a vertical electric field Ez, a...

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The work was performed using the compute re- sources and assistance of the UW-Madison Center For High Throughput Computing (CHTC) in the Depart- ment of Computer Sciences [51]. The CHTC is sup- ported by UW-Madison, the Advanced Computing Ini- tiative, the Wisconsin Alumni Research Foundation, the 15 Wisconsin Institutes for Discovery, and the National Sc...

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III in the main text, to develop high-fidelity pulses, we want to estimate the pulse sensi- tivity to charge noise

ComputingL charge As described in Sec. III in the main text, to develop high-fidelity pulses, we want to estimate the pulse sensi- tivity to charge noise. To do so, we utilize a formalism based on a general 2-level Hamiltonian [44, 52] H=H c +δH,(B1) whereH c is the desired (time-dependent) control Hamil- tonian, and the leakage term δH=χx(t)σx +χz(t)σz,(...

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ComputingL leak While we restrict ourselves to the 2-level spin subspace to approximate the gate sensitivity to charge noise, we need to consider leakage out of this subspace while per- forming gate operations. To do so, at each step, we simu- late the evolution of the full 8-level system fromt= 0to t=T :=nT res under the Schrodinger equation, including a...

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11, we plot the components of the total cost Cin Eq

Comparison of cost components In Fig. 11, we plot the components of the total cost Cin Eq. (13) for a variety of valley configurations. Here, we show results for the cosine pulse family, as- suming an optimisticσε= 1µeV. In Fig. 11(a), we assumeE vL =E vR = 100µeV, and in (b) we assume EvL =E vR = 20µeV. Each column represents a dif- ferent valley phase d...

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We represent the pulse parameters as a vectorp, which is op- timized with the Nelder-Mead method [53]

Randomization and re-optimization As described in the main text, in the second stage of our optimization procedure, we fine-tune the pulse parameters for each of the five best-performing pulse lengths through randomization and re-optimization. We represent the pulse parameters as a vectorp, which is op- timized with the Nelder-Mead method [53]. In order t...

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We select ini- tial conditions such that the optimized pulse performs a single rotation fromθ= 0toπ, and not multiple rota- tions

Additional details To perform our pulse optimization and simulation, we use the Julia programming language [54]. We select ini- tial conditions such that the optimized pulse performs a single rotation fromθ= 0toπ, and not multiple rota- tions. Data analysis, plotting, and other computations are performed in the Python programming language, in- cluding the...

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(7), we need to compute the envelope functionψenv

1D simulations To obtainσ∆ for a given heterostructure according to Eq. (7), we need to compute the envelope functionψenv. To do so, a 1D effective mass model suffices. We solve the 1D effective mass Hamiltonian H1D EM =T 1D +Uϕ+U qw,(E1) whereT 1D is a discretized 1D kinetic energy operator, Uϕ=eE zzis the potential due to a vertical electric field Ez, a...

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We note that these simulations contain no valley physics, since their pur- pose is only to describe the orbital energies of the sys- tem

3D simulations We also employ 3D effective mass simulations to de- scribe the local chemical potential and tunnel coupling fluctuations due to alloy disorder. We note that these simulations contain no valley physics, since their pur- pose is only to describe the orbital energies of the sys- tem. Following the methods of Ref. [38], we use a coarse- grained...

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Alloy disorder As described above, alloy disorder can induce small shifts in the ground-state energy in the presence of fluc- tuating lateral electric fields. From effective mass theory, the first-order correction to the ground-state energy due to alloy disorder is given by Edis gs = ∫ dr|ψ0(r)|2Udis qw (r),(F1) whereψ0 is the zeroth order envelope functi...

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22 First, we determine the effects of an interface step on the ground-state energy of a single quantum dot

Interface steps Now, we consider the effect of an interface step on the effective detuning fluctuations in a flopping mode qubit. 22 First, we determine the effects of an interface step on the ground-state energy of a single quantum dot. We obtain the ground state energyEgs by diagonalizing the effective mass Hamiltonian Eq. (E5), varying the dot centerx0...

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To do so, we consider two models of the lateral confinement potential: biquadratic and quartic, following Ref

Alloy disorder First, we evaluate the role of alloy disorder on the tun- nel coupling in a double dot. To do so, we consider two models of the lateral confinement potential: biquadratic and quartic, following Ref. [59], given by the following Ubi = 1 2mtω2 { Min [( x−x0−d 2 )2 , ( x−x0 + d 2 )2] + (y−y0)2 } Uqu = 1 2mtω2 [ 1 d2 ( (x−x0)2−d2 4 )2 + (y−y0)2...

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As above, we use 3D effective mass simulations to determinetc for different step configura- tions

Interface steps Next, weinvestigatetheroleofinterfacestepsintunnel coupling fluctuations. As above, we use 3D effective mass simulations to determinetc for different step configura- tions. In this case, we exclude alloy disorder by using the virtual crytal approximation. Again, we use the quartic potential model and an inter-dot separationd= 60 nm in Eq. ...

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direct” modulation oftc, as opposed to the disorder- induced “indirect

Fluctuations in the inter-dot distance Lastly, we investigate the role of fluctuations in the inter-dot distance due to charge noise. In the case where charge defects live near the qubit, each dot could experience electric field fluctuations in opposite direc- tions. These could have the effect of moving the two dots slightly closer or slightly farther ap...

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We expect the effects of charge noise to be more apparent for large noise amplitudes

Impact ofδtc on gate fidelity To estimate the expected infidelity due to tunnel cou- pling fluctuations, we examine the cosine pulse family, in the pessimisticσε= 15µeVcharge noise regime. We expect the effects of charge noise to be more apparent for large noise amplitudes. Starting with a pulse optimized foreitherE vL =E vR = 20µeVorE vL =E vR = 100µeV, ...

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to generate these landscapes, assuming the real and imaginary components of∆are uncorrelated, and the spatial covariance of∆is given by Eq. (19). Appendix I: Linear quantum dot array In Section VII of the main text, we considered sparse grids of quantum dots, showing that they enable a much higher probability of finding a high-fidelity qubit. Here, weperf...

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