Supersensitive rotation sensor from superintegrability
Leandro Hayato Ymai, Karin Wittmann Wilsmann, Joel Bacellar Neves, Arlei Prestes Tonel, Jon Links, Angela Foerster
TL;DR
This paper proposes a quantum rotation sensor using ultra-cold dipolar atoms in a four-well setup, leveraging superintegrability to surpass the Heisenberg limit in sensitivity.
Contribution
It introduces a novel quantum sensing method based on superintegrability, achieving ultra-sensitive rotation detection beyond traditional quantum limits.
Findings
Achieves rotation sensitivity beyond the Heisenberg limit.
Utilizes superintegrability for enhanced quantum sensing.
Proposes a simple population imbalance measurement protocol.
Abstract
Detection based on quantum principles such as entanglement has the capacity to achieve finessed levels of sensitivity, bringing transformative impacts to applications. In this study, we propose a rotation sensor using ultra-cold dipolar atoms trapped in a four-well configuration. The design, based on a simple population imbalance measurement to quantify rotation, profits from the property of superintegrability. The implementation of the measurement protocol achieves rotation-detection sensitivity beyond the Heisenberg limit. Our results spotlight superintegrability opportunities for advancing the field of quantum sensing.
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