Collective dynamics in Rydberg arrays

In recent years, neutral atoms in tweezer arrays have gained prominence as scalable platforms for a variety of quantum technology applications, primarily due to the powerful collective dynamics offered by the Rydberg blockade mechanism.

As the platform’s size continues to grow, there is an increasing theoretical emphasis on devising protocols that predominantly utilize global atom driving, given the persistent challenges associated with individual atom addressing.

In this research proposal, the Applicant will deepen the understanding of the complex collective dynamics inherent to Rydberg arrays, with the objective of formulating innovative, scalable protocols that minimize the reliance on local controls.

He will investigate a brand new set of dynamics, made accessible via the strategic inclusion of proper arrangement of atoms – superatoms and Rydberg gadgets – for quantum computation and optimization purposes, leveraging the Host’s deep expertise in the field.