Aaron Ostrander

TL;DR: This work develops a finite difference algorithm for the Poisson equation and a spectral algorithm for more general second-order elliptic equations, based on adaptive-order finite difference methods and spectral methods.

TL;DR: In this article, the authors present the first experimental results for parallel 2-qubit entangling gates in an array of fully-connected trapped ion qubits, and demonstrate an application of this capability by performing a 1-bit full addition operation on a quantum computer using a depth-4 quantum circuit.

TL;DR: In this paper, a quantum algorithm for simulating the wave equation under Dirichlet and Neumann boundary conditions is presented, which uses Hamiltonian simulation and quantum linear system algorithms as subroutines.

TL;DR: In this paper, a parallel two-qubit entangling operation on a quantum computer using a depth-four quantum circuit is presented. But the implementation of parallel entangling quantum gates is complicated by potential crosstalk, especially between qubits that are fully connected by a commonmode bus, such as in Coulomb-coupled trapped atomic ions.