# Eigenstate control of plasmon wavepackets with electron-channel blockade

**Authors:** Shintaro Takada, Giorgos Georgiou, Junliang Wang, Yuma Okazaki, Shuji Nakamura, David Pomaranski, Arne Ludwig, Andreas D. Wieck, Michihisa Yamamoto, Christopher Bäuerle, Nobu-Hisa Kaneko

PMC · DOI: 10.1038/s41467-025-64876-z · Nature Communications · 2025-11-12

## TL;DR

Researchers developed a method to control plasmon wavepackets using a cavity to isolate electron channels, improving quantum information processing.

## Contribution

A cavity-based technique enables precise control of plasmon eigenstates by suppressing charge fractionalisation in electron channels.

## Key findings

- A cavity isolates electron conduction channels to control plasmon eigenstates.
- The electron-channel blockade effect suppresses charge fractionalisation into cavity-confined channels.
- This method allows tailored plasmon speed and minimizes unwanted excitation in adjacent circuits.

## Abstract

Coherent manipulation of plasmon wavepackets in solid-state systems is crucial for advancing nanoscale electronic devices, offering a unique platform for quantum information processing based on propagating quantum bits. Controlling the eigenstate of plasmon wavepackets is essential, as it determines their propagation speed and hence the number of quantum operations that can be performed during their flight time through a quantum system. When plasmon wavepackets are generated by short voltage pulses and transmitted through nanoscale devices, they distribute among multiple electron conduction channels via Coulomb interactions, a phenomenon known as charge fractionalisation. This spreading complicates plasmon manipulation in quantum circuits and makes precise control of the eigenstates of plasmon wavepackets challenging. Using a cavity, we demonstrate the ability to isolate and select electron conduction channels contributing to plasmon excitation, thus enabling precise control of plasmon eigenstates. Specifically, we observe an electron-channel blockade effect, where charge fractionalisation into cavity-confined channels is suppressed due to the plasmon’s narrow energy distribution, enabling more stable and predictable plasmonic circuits. This technique provides a versatile tool for designing plasmonic circuits, offering the ability to tailor plasmon speed through local parameters, minimise unwanted plasmon excitation in adjacent circuits, and enable the precise selection of electron-channel plasmon eigenstates in quantum interferometers.

Coherent control of plasmon wavepackets is essential for quantum information processing using flying electron qubits. Here, the authors demonstrate a method to isolate and select electron channels contributing to a plasmon using a cavity formed by local constrictions, enabling precise control of plasmon eigenstates.

## Full-text entities

- **Diseases:** electron (MESH:D028361)
- **Chemicals:** GaAs (MESH:C043055), Ti (MESH:D014025), Ge (MESH:D005857), Lp (MESH:D008070), Au (MESH:D006046), Ni (MESH:D009532), 2LFP (-)
- **Cell lines:** VQPC1 — Mus musculus (Mouse), Hybridoma (CVCL_C7RB)

## Full text

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## Figures

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## References

1 references — full list in the complete paper: https://tomesphere.com/paper/PMC12612246/full.md

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Source: https://tomesphere.com/paper/PMC12612246