Related papers: Mapping the positions of Two-Level-Systems on the surface of a superconducting transmon qubit

Mapping the positions of Two-Level-Systems on the surface of a superconducting transmon qubit

URL: http://arxiv.org/abs/2511.05365v1
Date: Fri, 07 Nov 2025 15:52:53 GMT
Title: Mapping the positions of Two-Level-Systems on the surface of a superconducting transmon qubit
Authors: Jürgen Lisenfeld, Alexander K. Händel, Etienne Daum, Benedikt Berlitz, Alexander Bilmes, Alexey V. Ustinov,
Abstract summary: Coherence of superconducting quantum computers is severely limited by material defects that create parasitic two-level-systems (TLS)<n>Here, we present a method to determine the individual positions of TLS at the surface of a transmon qubit.<n>Our method is useful to identify critical circuit regions where TLS contribute most to decoherence, and can guide improvements in qubit design and fabrication methods.
Score: 67.53400883122266
License: http://creativecommons.org/licenses/by/4.0/
Abstract: The coherence of superconducting quantum computers is severely limited by material defects that create parasitic two-level-systems (TLS). Progress is complicated by lacking understanding how TLS are created and in which parts of a qubit circuit they are most detrimental. Here, we present a method to determine the individual positions of TLS at the surface of a transmon qubit. We employ a set of on-chip gate electrodes near the qubit to generate local DC electric fields that are used to tune the TLS' resonance frequencies. The TLS position is inferred from the strengths at which TLS couple to different electrodes and comparing them to electric field simulations. We found that the majority of detectable surface-TLS was residing on the leads of the qubit's Josephson junction, despite the dominant contribution of its coplanar capacitor to electric field energy and surface area. This indicates that the TLS density is significantly enhanced near shadow-evaporated electrodes fabricated by lift-off techniques. Our method is useful to identify critical circuit regions where TLS contribute most to decoherence, and can guide improvements in qubit design and fabrication methods.

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