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Clifford gates
Lattice Surgery with a Twist: Simplifying Clifford Gates of Surface Codes
Arxiv:2003.09412V2 [Quant-Ph] 7 Jul 2021 Hadamard-Free Circuits Expose the Structure of the Clifford Group
Quantum Topological Error Correction Codes Are Capable of Improving the Performance of Clifford Gates
Universal Quantum Computation with Ideal Clifford Gates and Noisy Ancillas
Randomized Benchmarking of Two-Qubit Gates
Arxiv:2006.01273V1 [Quant-Ph] 1 Jun 2020 Performance of the System According to Our Bench- 5.1 Full Stack Benchmarking
Supercomputer Simulations of Transmon Quantum Computers Quantum Simulations of Transmon Supercomputer
Quantum Proofs Can Be Verified Using Only Single Qubit Measurements
Arxiv:2007.08532V2 [Quant-Ph]
A Study of the Robustness of Magic State Distillation Against Clifford Gate Faults
Superconducting Qubits: Current State of Play Arxiv:1905.13641V3
Logical Clifford Synthesis for Stabilizer Codes
Stim: a Fast Stabilizer Circuit Simulator Craig Gidney
Naik2017.Pdf
QEC07 Poster Information
Constructions for Quantum Indistinguishability Obfuscation
Benchmarking Gate Fidelities in a Si/Sige Two-Qubit Device
Quantifying the Magic Resources for Quantum Computation
Top View
Languages and Representations for Quantum Computing: Stabilizers and Tensor Networks
Quantum Error Correcting Codes and Fault-Tolerant Quantum Computation Over Nice Rings
ZERO-KNOWLEDGE PROOF SYSTEMS for QMA\Ast
Direct Randomized Benchmarking for Multi-Qubit Devices
Delegation of Quantum Computations
Quantum Topological Error Correction Codes Are Capable of Improving the Performance of Clifford Gates
Very Low Overhead Fault-Tolerant Magic State Preparation Using Redundant Ancilla Encoding and flag Qubits ✉ ✉ Christopher Chamberland 1,2 and Kyungjoo Noh 1
Magic State Distillation and Gate Compilation in Quantum Algorithms for Quantum Chemistry Arxiv:1501.01298V3 [Quant-Ph] 29
Universal Fault-Tolerant Measurement-Based Quantum Computation
Shelly Garion IBM Research - Haifa
Logical Clifford Synthesis for Stabilizer Codes
Simulation of Quantum Circuits by Low-Rank Stabilizer Decompositions
Fault-Tolerant Quantum Computing
Reducing T-Count with the ZX-Calculus
Low-Cost Quantum Circuits for Classically Intractable Instances of the Hamiltonian Dynamics Simulation Problem
Improved Classical Simulation of Quantum Circuits Dominated by Clifford Gates
Fault-Tolerant Quantum Computing in the Pauli Or Clifford Frame with Slow Error Diagnostics
Quantum Simulation Logic, Oracles, and the Quantum Advantage
Fault-Tolerant Operation of a Quantum Error-Correction Code Laird Egan1,†, Dripto M
Quantum Information Processing with Superconducting Qubits
Programme and Book of Abstracts
Learning Quantum Circuits of Some T Gates Ching-Yi Lai and Hao-Chung Cheng
Quantum Advantage of Unitary Clifford Circuits with Magic State Inputs
Arxiv:1904.06560V5 [Quant-Ph] 7 Jul 2021 2
Complexity Classification of Conjugated Clifford Circuits
GHZ Correlations Are Just a Bit Nonlocal
Gates, States, and Circuits
An Introduction to Quantum Error Correction and Fault-Tolerant Quantum Computation
Quantum Error Correction During 50 Gates
Un-Weyl-Ing the Clifford Hierarchy
Complexity Classification of Conjugated Clifford Circuits CCC’S@CCC’18
Semiclassical Formulation of the Gottesman-Knill Theorem and Universal Quantum Computation
Complexity Classification of Conjugated Clifford Circuits
Algorithms for the Optimization of Quantum Circuits
Efficient Quantum Gate Teleportation in Higher Dimensions
Sara Zafar Jafarzadeh
Disjointness of Stabilizer Codes and Limitations on Fault-Tolerant Logical Gates
Basics of Quantum Computing and Some Recent Results Tomoyuki Morimae (YITP Kyoto University) 50+10 Min
Clifford Gates in the Holant Framework
Quantum Information Theory in Quantum Hamiltonian Complexity
Leakage Reduction in Fast Superconducting Qubit Gates Via Optimal Control ✉ M
Experimental Implementation of Non-Clifford Interleaved Randomized Benchmarking with a Controlled-$S$ Gate
Universal Fault-Tolerant Gates on Concatenated Stabilizer Codes
Encoding One Logical Qubit Into Six Physical Qubits