Richard Rines
University of Chicago
13 Papers
7 Citations
Richard Rines is an academic researcher from University of Chicago. The author has contributed to research in topics: Qubit & Computer science. The author has an hindex of 4, co-authored 6 publications. Previous affiliations of Richard Rines include Massachusetts Institute of Technology.
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Papers
Realization of a scalable Shor algorithm
Thomas Monz,Daniel Nigg,Esteban Martínez,Matthias F. Brandl,Philipp Schindler,Richard Rines,Shannon X. Wang,Isaac L. Chuang,Rainer Blatt,Rainer Blatt +9 more
TL;DR: The realization of a scalable Shor algorithm, as proposed by Kitaev, is presented, which has been realized scalably within an ion-trap quantum computer and returns the correct factors with a confidence level exceeding 99%.
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Systematic Crosstalk Mitigation for Superconducting Qubits via Frequency-Aware Compilation
Yongshan Ding,Pranav Gokhale,Sophia Fuhui Lin,Richard Rines,Thomas Propson,Frederic T. Chong +5 more
- 01 Oct 2020
TL;DR: This work dramatically improves the crosstalk resilience of tunable-qubit, fixed-coupler hardware, matching or surpassing other more complex architectural designs such as Tunable-Coupler systems.
Clifford-based Circuit Cutting for Quantum Simulation
Kaitlin Smith,Michael A. Perlin,Pranav Gokhale,P. Frederick,David K. Owusu-Antwi,Richard Rines,V. Omole,Frederic T. Chong +7 more
- 19 Mar 2023
TL;DR: SuperSim as mentioned in this paper is a quantum circuit simulator that uses Clifford-based simulation and circuit cutting to accelerate the simulation of quantum circuits, allowing 100s of qubits to be evaluated with modest runtimes.
Iterative Precision Measurement of Branching Ratios Applied to 5P states in 88Sr
Helena Zhang,M. S. Gutierrez,Guang Hao Low,Richard Rines,Jules Stuart,Tailin Wu,Isaac L. Chuang +6 more
TL;DR: In this paper, the branching ratio of dipole transitions of trapped atomic ions was measured by performing nested sequences of population inversions, and the results were improved to 17.175(27), 15.845(71), and 0.05609(21) for 5P3/2-4D5/2.
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Superstaq: Deep Optimization of Quantum Programs
Colin Campbell,Frederic T. Chong,Denny Dahl,P. Frederick,P. Goiporia,Pranav Gokhale,Benjamin Hall,Salahedeen Issa,Eric Jones,Stephanie Lee,Andrew Litteken,V. Omole,David K. Owusu-Antwi,Michael A. Perlin,Richard Rines,Kaitlin Smith,Noah Goss,Akel Hashim,Ravi Naik,Ed Younis,Dan Lobser,Christopher G. Yale,Benchen Huang,Ji Liu +23 more
- 10 Sep 2023
TL;DR: Superstaq is described, a quantum software platform that optimizes the execution of quantum programs by tailoring to underlying hardware primitives, and demonstrates new levels of performance and new capabilities that are enabled by deeper integration between quantum programs and the device physics of hardware.
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