Dr Raghavendra Srinivas

Robust quantum memory in a trapped-ion quantum network node

(2022)

Authors:

Peter Drmota, D Main, David P Nadlinger, Bethan C Nichol, MA Weber, Ellis M Ainley, Ayush Agrawal, Raghavendra Srinivas, Gabriel Araneda Machuca, Christopher J Ballance, David M Lucas

Universal hybrid quantum computing in trapped ions

Physical Review A American Physical Society 104:3 (2021) 32609

Authors:

Rt Sutherland, R Srinivas

Abstract:

Using discrete and continuous variable subsystems, hybrid approaches to quantum information could enable more quantum computational power for the same physical resources. Here, we propose a hybrid scheme that can be used to generate the necessary Gaussian and non-Gaussian operations for universal continuous variable quantum computing in trapped ions. This scheme utilizes two linear spin-motion interactions to generate a broad set of nonlinear effective spin-motion interactions including one- and two-mode squeezing, beam splitter, and trisqueezing operations in trapped ion systems. We discuss possible experimental implementations using laser-based and laser-free approaches.

Quantum amplification of boson-mediated interactions

Nature Physics Springer Nature 17:8 (2021) 898-902

Authors:

SC Burd, R Srinivas, HM Knaack, W Ge, AC Wilson, DJ Wineland, D Leibfried, JJ Bollinger, DTC Allcock, DH Slichter

Laser-free trapped-ion entangling gates with simultaneous insensitivity to qubit and motional decoherence

Physical Review A American Physical Society (APS) 101:4 (2020) 042334

Authors:

RT Sutherland, R Srinivas, SC Burd, HM Knaack, AC Wilson, DJ Wineland, D Leibfried, DTC Allcock, DH Slichter, SB Libby

Trapped-Ion Spin-Motion Coupling with Microwaves and a Near-Motional Oscillating Magnetic Field Gradient.

Physical review letters 122:16 (2019) 163201

Authors:

R Srinivas, SC Burd, RT Sutherland, AC Wilson, DJ Wineland, D Leibfried, DTC Allcock, DH Slichter

Abstract:

We present a new method of spin-motion coupling for trapped ions using microwaves and a magnetic field gradient oscillating close to the ions' motional frequency. We demonstrate and characterize this coupling experimentally using a single ion in a surface-electrode trap that incorporates current-carrying electrodes to generate the microwave field and the oscillating magnetic field gradient. Using this method, we perform resolved-sideband cooling of a single motional mode to its ground state.