Scaling up a sign-ordered Kitaev chain without magnetic flux control

C. Liu; Sebastian Miles; Alberto Bordin; Sebastiaan L.D. Ten Haaf; Grzegorz P. Mazur; A. Mert Bozkurt; Michael Wimmer

doi:10.1103/PhysRevResearch.7.L012045

Scaling up a sign-ordered Kitaev chain without magnetic flux control

C. Liu^*, Sebastian Miles, Alberto Bordin, Sebastiaan L.D. Ten Haaf, Grzegorz P. Mazur, A. Mert Bozkurt, Michael Wimmer

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

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Abstract

Quantum-dot-superconductor arrays have emerged as a new and promising material platform for realizing topological Kitaev chains. So far, experiments have implemented a two-site chain with limited protection. Here, we propose an experimentally feasible protocol for scaling up the chain in order to enhance the protection of the Majorana zero modes. To this end, we make use of the fact that the relative sign of normal and superconducting hoppings mediated by an Andreev bound state can be changed by electrostatic gates. In this way, our method only relies on the use of individual electrostatic gates on hybrid regions, quantum dots, and tunnel barriers, respectively, without the need for individual magnetic flux control, greatly simplifying the device design. Our work provides guidance for realizing a topologically protected Kitaev chain, which is the building block of error-resilient topological quantum computation.

Original language	English
Article number	L012045
Number of pages	6
Journal	Physical Review Research
Volume	7
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevResearch.7.L012045
Publication status	Published - 2025

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PhysRevResearch.7.L012045Final published version, 470 KBLicence: CC BY

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title = "Scaling up a sign-ordered Kitaev chain without magnetic flux control",

abstract = "Quantum-dot-superconductor arrays have emerged as a new and promising material platform for realizing topological Kitaev chains. So far, experiments have implemented a two-site chain with limited protection. Here, we propose an experimentally feasible protocol for scaling up the chain in order to enhance the protection of the Majorana zero modes. To this end, we make use of the fact that the relative sign of normal and superconducting hoppings mediated by an Andreev bound state can be changed by electrostatic gates. In this way, our method only relies on the use of individual electrostatic gates on hybrid regions, quantum dots, and tunnel barriers, respectively, without the need for individual magnetic flux control, greatly simplifying the device design. Our work provides guidance for realizing a topologically protected Kitaev chain, which is the building block of error-resilient topological quantum computation.",

author = "C. Liu and Sebastian Miles and Alberto Bordin and {Ten Haaf}, {Sebastiaan L.D.} and Mazur, {Grzegorz P.} and Bozkurt, {A. Mert} and Michael Wimmer",

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AU - Liu, C.

AU - Miles, Sebastian

AU - Bordin, Alberto

AU - Ten Haaf, Sebastiaan L.D.

AU - Mazur, Grzegorz P.

AU - Bozkurt, A. Mert

AU - Wimmer, Michael

PY - 2025

Y1 - 2025

N2 - Quantum-dot-superconductor arrays have emerged as a new and promising material platform for realizing topological Kitaev chains. So far, experiments have implemented a two-site chain with limited protection. Here, we propose an experimentally feasible protocol for scaling up the chain in order to enhance the protection of the Majorana zero modes. To this end, we make use of the fact that the relative sign of normal and superconducting hoppings mediated by an Andreev bound state can be changed by electrostatic gates. In this way, our method only relies on the use of individual electrostatic gates on hybrid regions, quantum dots, and tunnel barriers, respectively, without the need for individual magnetic flux control, greatly simplifying the device design. Our work provides guidance for realizing a topologically protected Kitaev chain, which is the building block of error-resilient topological quantum computation.

AB - Quantum-dot-superconductor arrays have emerged as a new and promising material platform for realizing topological Kitaev chains. So far, experiments have implemented a two-site chain with limited protection. Here, we propose an experimentally feasible protocol for scaling up the chain in order to enhance the protection of the Majorana zero modes. To this end, we make use of the fact that the relative sign of normal and superconducting hoppings mediated by an Andreev bound state can be changed by electrostatic gates. In this way, our method only relies on the use of individual electrostatic gates on hybrid regions, quantum dots, and tunnel barriers, respectively, without the need for individual magnetic flux control, greatly simplifying the device design. Our work provides guidance for realizing a topologically protected Kitaev chain, which is the building block of error-resilient topological quantum computation.

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Scaling up a sign-ordered Kitaev chain without magnetic flux control

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