Implementation of Ising-type interaction via phase stable Raman addressing in a cryogenic trapped-ion quantum simulator

Trapped-ion quantum simulators are great platforms to explore wide-range of many-body systems. In such a simulator, we engineer tunable long-range spin-spin interaction between the qubits encoded in the hyperfine clock state of ¹⁷¹Yb⁺, using the Molmer-Sorensen (MS) entangling gate protocol [1]. An accurate simulation of many-body systems requires extensive spatial and temporal phase coherences of MS gate protocol, typically limited by the phase fluctuations due to optical path instabilities and ions' motion [2]. We demonstrate an Ising-type interaction using Raman addressing beams, which is insensitive to such phase fluctuations. We chose appropriate laser frequencies so that the momentum transfer to the ion from the red and blue sideband transition are in opposite direction, which eliminates the dependence of the qubit's phases on optical path lengths of the driving laser fields [3]. We further characterize and compare this phase-insensitive scheme with the usual phase-sensitive implementation of the Ising-type Hamiltonian and explore the benefits and limitations of both schemes.

[1] K. Kim, M.-S. Change, R. Islam, S. Korenblit, L.-M. Duan, C. Monroe, Phys. Rev. Lett. 103 (2009)

[2] P. J. Lee, K.-A. Brickman, L. Deslauriers, P. C. Haljan, L.-M. Duan, and C. Monroe, Journal of Optics B 7, S371 (2005)

[3] I. V. Inlek, G. Vittorini, D. Hucul, C. Crocker, and C. Monroe Phys. Rev. A 90, 042316 (2014)