Transport characterization and quantum dot coupling in commercial 22FDX
- URL: http://arxiv.org/abs/2501.10146v1
- Date: Fri, 17 Jan 2025 12:17:16 GMT
- Title: Transport characterization and quantum dot coupling in commercial 22FDX
- Authors: Giselle A. Elbaz, Pierre-Louis Julliard, Mikaël Cassé, Heimanu Niebojewski, Benoit Bertrand, Grégoire Roussely, Valentin Labracherie, Maud Vinet, Tristan Meunier, Bruna Cardoso Paz,
- Abstract summary: We study the impact of gate stack, channel type and back bias as a function of temperature.<n>This screening process selected qubit devices that allowed us to couple quantum dots along both the length and width of the Si channel.<n>We present stability diagrams with clear and regular honeycomb patterns, where spurious elements such as dopants are not observed.
- Score: 0.0
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: Different groups worldwide have been working with the GlobalFoundries 22nm platform (22FDX) with the hopes of industrializing the fabrication of Si spin qubits. To guide this effort, we have performed a systematic study of six of the foundry's processes of reference (POR). Using effective mobility as a figure of merit, we study the impact of gate stack, channel type and back bias as a function of temperature. This screening process selected qubit devices that allowed us to couple quantum dots along both the length and width of the Si channel. We present stability diagrams with clear and regular honeycomb patterns, where spurious elements such as dopants are not observed. By combining these results with room and low temperature simulations, we provide insights into potential technology optimizations and show both the utility of qubit pre-screening protocols as well as the advantages of leveraging forward body bias within an FDSOI (Fully Depleted Silicon-On-Insulator) qubit platform.
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