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Autori principali: Chung, Daun, Choi, Kwangyeul, Lee, Woojun, Kim, Chiyoon, Shon, Hosung, Park, Jeonghyun, Cho, Beomgeun, Lee, Kyungmin, Kim, Suhan, Yoo, Seungwoo, Jung, Eui Hwan, Jung, Changhyun, Kang, Jiyong, Kim, Kyunghye, Berkis, Roberts, Northup, Tracy, Cho, Dong-Il "Dan'', Kim, Taehyun
Natura: Preprint
Pubblicazione: 2024
Soggetti:
Accesso online:https://arxiv.org/abs/2411.13955
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author Chung, Daun
Choi, Kwangyeul
Lee, Woojun
Kim, Chiyoon
Shon, Hosung
Park, Jeonghyun
Cho, Beomgeun
Lee, Kyungmin
Kim, Suhan
Yoo, Seungwoo
Jung, Eui Hwan
Jung, Changhyun
Kang, Jiyong
Kim, Kyunghye
Berkis, Roberts
Northup, Tracy
Cho, Dong-Il "Dan''
Kim, Taehyun
author_facet Chung, Daun
Choi, Kwangyeul
Lee, Woojun
Kim, Chiyoon
Shon, Hosung
Park, Jeonghyun
Cho, Beomgeun
Lee, Kyungmin
Kim, Suhan
Yoo, Seungwoo
Jung, Eui Hwan
Jung, Changhyun
Kang, Jiyong
Kim, Kyunghye
Berkis, Roberts
Northup, Tracy
Cho, Dong-Il "Dan''
Kim, Taehyun
contents Silicon-based ion trap chips can benefit from existing advanced fabrication technologies, such as multi-metal layer techniques for two-dimensional architectures and silicon photonics for the integration of on-chip optical components. However, the scalability of these technologies may be compromised by semiconductor charging, where photogenerated charge carriers produce electric potentials that disrupt ion motion. Inspired by recent studies on charge distribution mechanisms in semiconductors, we developed a silicon-based chip with gold coated on all exposed silicon surfaces. This modification significantly stabilized ion motion compared to a chip without such metallic shielding, a result that underscores the detrimental effects of exposed silicon. With the mitigation of background silicon-induced fields to negligible levels, quantum operations such as sideband cooling and two-ion entangling gates, which were previously infeasible with the unshielded chip, can now be implemented.
format Preprint
id arxiv_https___arxiv_org_abs_2411_13955
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A silicon-based ion trap chip protected from semiconductor charging
Chung, Daun
Choi, Kwangyeul
Lee, Woojun
Kim, Chiyoon
Shon, Hosung
Park, Jeonghyun
Cho, Beomgeun
Lee, Kyungmin
Kim, Suhan
Yoo, Seungwoo
Jung, Eui Hwan
Jung, Changhyun
Kang, Jiyong
Kim, Kyunghye
Berkis, Roberts
Northup, Tracy
Cho, Dong-Il "Dan''
Kim, Taehyun
Quantum Physics
Silicon-based ion trap chips can benefit from existing advanced fabrication technologies, such as multi-metal layer techniques for two-dimensional architectures and silicon photonics for the integration of on-chip optical components. However, the scalability of these technologies may be compromised by semiconductor charging, where photogenerated charge carriers produce electric potentials that disrupt ion motion. Inspired by recent studies on charge distribution mechanisms in semiconductors, we developed a silicon-based chip with gold coated on all exposed silicon surfaces. This modification significantly stabilized ion motion compared to a chip without such metallic shielding, a result that underscores the detrimental effects of exposed silicon. With the mitigation of background silicon-induced fields to negligible levels, quantum operations such as sideband cooling and two-ion entangling gates, which were previously infeasible with the unshielded chip, can now be implemented.
title A silicon-based ion trap chip protected from semiconductor charging
topic Quantum Physics
url https://arxiv.org/abs/2411.13955