All my arXiv preprints can be found at http://arxiv.org/a/campbell_e_2
Some of my older paper are listed below, though I have stopped maintaining this list.
Quantifying quantum speedups: improved classical simulation from tighter magic monotones
James R. Seddon, Bartosz Regula, Hakop Pashayan, Yingkai Ouyang, Earl T. Campbell
arXiv2002.06181
Tight bounds on the simultaneous estimation of incompatible parameters
Jasminder S. Sidhu, Yingkai Ouyang, Earl T. Campbell, Pieter Kok
arXiv1:912.09218 (2019)
Compilation by stochastic Hamiltonian sparsification
Yingkai Ouyang, David R. White, Earl Campbell
Quantum 4 235 (2020)
arXiv:1910.06255 (2019)
Reviewed in a perspective article by Leonardo Novo
Efficient quantum measurement of Pauli operators
Ophelia Crawford, Barnaby van Straaten, Daochen Wang,
Thomas Parks, Earl Campbell and Stephen Brierley
arxiv:1908.06942 (2019)
The Role of Multiplicative Complexity in Compiling Low T-count Oracle Circuits
G Meuli, M Soeken, E Campbell, M Roetteler, G De Micheli
Proc. Int’l Conf. on Computer-Aided Design (ICCAD 2019)
arXiv:1908.01609
Optimising Trotter-Suzuki Decompositions for Quantum Simulation Using Evolutionary Strategies
Benjamin Jones, George O’Brien, David White, Earl Campbell, John Clark
GECCO ’19 Proceedings of the Genetic and Evolutionary Computation Conference 1223
arxiv:1904.01336 (2019)
Lower bounds on the non-Clifford resources for quantum computations
M Beverland, E Campbell, M Howard, V Kliuchnikov
arXiv:1904.01124 (2019)
Accepted to Quantum Science and Technology
A quantum compiler for qudits of prime dimension greater than 3
Luke E. Heyfron, Earl Campbell
arxiv:1902.05634 (2019)
Quantifying magic for multi-qubit operations
James R. Seddon, Earl Campbell
Proc. R. Soc. A 475 20190251 (2019)
arxiv:1901.03322
A random compiler for fast Hamiltonian simulation
Earl Campbell
Phys. Rev. Lett. 123 070503 (2019)
Selected as an editor’s suggestion and commented on in a Physics Viewpoint.
arXiv:1811.08017 (2018)
Applying quantum algorithms to constraint satisfaction problems
Earl Campbell, Ankur Khurana, Ashley Montanaro
Quantum 3, 167 (2019)
arXiv:1810.05582
Simulation of quantum circuits by low-rank stabilizer decompositions
Sergey Bravyi, Dan Browne, Padraic Calpin, Earl Campbell, David Gosset, Mark Howard
Quantum 3, 181 (2019)
arXiv:1808.00128
This work was presented by David Gosset at QIP 2019.
A theory of single-shot error correction for adversarial noise
Earl T. Campbell
Quantum Science and Technology 4, 025006 (2019)
arXiv:1805.09271
This work was presented by me at QIP 2019
An Efficient Quantum Compiler that reduces T count
Luke Heyfron, Earl T. Campbell
Quantum Science and Technology 4, 015004 (2018)
arXiv:1712.01557
Magic state parity-checker with pre-distilled components
Earl T. Campbell, Mark Howard
Quantum 2, 56 (2018).
arXiv:1709.02214 (2017)
This work was presented in the 2nd half of my talk QEC 2017 and the video is available here.
Hyperbolic and Semi-Hyperbolic Surface Codes for Quantum Storage
Nikolas P. Breuckmann, Christophe Vuillot, Earl Campbell, Anirudh Krishna, Barbara M. Terhal
Quantum Sci. Technol. 2 035007 (2017)
arXiv:1703.00590
The Steep Road Towards Robust and Universal Quantum Computation
Earl T. Campbell, Barbara M. Terhal, Christophe Vuillot
Nature 549 172 (2017)
arXiv:1612.07330
Optimal Quantum Metrology of Distant Black Bodies
Mark E. Pearce, Earl T. Campbell, Pieter Kok
Quantum, 1 21 (2017)
arXiv:1612.04828
Shorter gate sequences for quantum computing by mixing unitaries
Earl T. Campbell
Phys. Rev. A. 95 042306 (2017)
arXiv:1612.02689
This work was presented by me at QIP 2018 and a video is available here
Application of a resource theory for magic states to fault-tolerant quantum computing
Mark Howard, Earl T. Campbell
Phys. Rev. Lett. 118 090501 (2017)
arXiv:1609.07488
This work was presented by Mark Howard at QIP 2017 and a video is available here
This work formed part of a survery talk by Earl Campbell at the ThinkQ workshop (video here).
Unifying gate-synthesis and magic state distillation
Earl T. Campbell, Mark Howard
Phys. Rev. Lett. 118 060501 (2017)
arXiv:1606.01906
This work was presented by me at QIP 2017 and a video is available here
A unified framework for magic state distillation and multi-qubit gate-synthesis with reduced resource cost
Earl T. Campbell, Mark Howard
Phys. Rev. A 95 022316 (2017)
arXiv:1606.01904
Quantum computation with realistic magic state factories
Joe O’Gorman, Earl T. Campbell
Phys. Rev. A. 95 032338 (2017)
arXiv:1605.07197
An efficient magic state approach to small angle rotations
Earl T. Campbell, Joe O’Gorman
Quantum Science and Technology 1, 015007 (2016)
arXiv:1603.04230 (2016)
This work was presented in the 1st half of my talk QEC 2017 and the video is available here.
Cellular automaton decoders of topological quantum memories in the fault tolerant setting
M. Herold, M. J. Kastoryano, Earl. T. Campbell, J. Eisert
New Journal of Physics 19 063012 (2017)
arXiv:1511.0557
Qudit Colour Codes and Gauge Colour Codes in All Spatial Dimensions
Fern H.E. Watson, Earl T. Campbell, Hussain Anwar, Dan E. Browne
Phys. Rev. A 92, 022312 (2015)
arXiv:1503.08800
Renormalising entanglement distillation
Stephan Waeldchen, Janina Gertis, Earl T. Campbell, Jens Eisert
Phys. Rev. Lett 116 020502 (2016)
arXiv:1503.04822
Decoherence in open Majorana systems
Earl T. Campbell
LIPIcs conference proceeding for TQC2015 44 111 (2015)
arxiv:1502.05626
Cellular-automaton decoders for topological quantum memories
M. Herold, Earl T. Campbell, J. Eisert, M. J. Kastoryano
nature partner journal: Quantum Information. 1 15010 (2015)
arXiv:1406.2338 (2014)
Order 3 Symmetry in the Clifford Hierarchy
Ingemar Bengtsson, Kate Blanchfield, Earl Campbell, Mark Howard
J. Phys. A: Math. Theor. 47 455302 (2014)
selected by journal as a highlight of 2014
arXiv:1407.2713
Enhanced fault-tolerant quantum computing in d-level systems
Earl T. Campbell
Phys. Rev. Lett. 113 230501 (2014)
arXiv:1406.3055
Efficient Decoders for Qudit Topological Codes
Hussain Anwar, Benjamin J. Brown, Earl T. Campbell, Dan E. Browne
New J. Phys. 16 063038 (2014)
arXiv:1311.4895
Majorana fermions and non-locality
Earl T. Campbell, Matty Hoban, and Jens Eisert
Quant. Info. Comm. 14 0981 (2014)
arXiv:1305.1953
Continuous-variable entanglement distillation and non-commutative central limit theorems
Earl T. Campbell, Marco G. Genoni, and Jens Eisert
Phys. Rev. A 87 042330 (2013)
arXiv:1211.5483
Magic state distillation in all prime dimensions using quantum Reed-Muller codes
Earl T. Campbell, Hussain Anwar, and Dan E. Browne
Phys. Rev. X 2 041021 (2012)
arXiv:1205.3104
Qutrit Magic State Distillation
Hussain Anwar, Earl T. Campbell, and Dan E. Browne
New J. Phys. 14 063006 (2012)
arXiv:1202.2326
Gaussification and entanglement distillation of continuous variable systems: a unifying picture.
Earl T. Campbell and Jens Eisert.
Phys. Rev. Lett. 108 020501(2012)
arxiv:1107.1406 (2011)
Non-adaptive Measurement-based Quantum Computation and Multi-party Bell Inequalities.
Matty J. Hoban, Earl T. Campbell, Klearchos Loukopoulos, and Dan E. Browne.
New Journal of Physics 13 023014 (2011)
arXiv:1009.5213 (2010)
Catalysis and activation of magic states in fault tolerant architectures.
Earl T. Campbell.
Physical Review A 83 032317 (2011)
arXiv:1010.0104
This work was presented as a featured talk at QIP 2011,
and a video recording is available here.
Optimal entangling capacity of dynamical processes.
Earl T. Campbell.
Physical Review A 82 042314 (2010)
arXiv:1007.1445
Bound states for magic state distillation in fault-tolerant quantum computation.
Earl T. Campbell, and Dan E. Browne.
Physical Review Letters 104 030503 (2010)
arXiv:0908.0836
On the structure of protocols for magic state distillation.
Earl T. Campbell, and Dan E. Browne.
Lecture Notes in Computer Science: Theory of Quantum Computation, Communication and Cryptography 4th Workshop, TQC 5906 Page 20 (2009)
arXiv:0908.0838
An introduction to one-way quantum computing in distributed architectures.
Earl Campbell, and Joseph Fitzsimons.
International Journal of Quantum Information special issue on Distributed Quantum Computing. Volume 8, Number 1-2,219-258 (2010)
arXiv:0906.2725
How to exploit local information when distilling entanglement.
Earl T. Campbell.
International Journal of Quantum Information special issue on Distributed Quantum Computing. Volume 8, Number 1-2, 161-180 (2010)
arXiv:0906.1527
Measurement based entanglement under conditions of extreme photon loss.
Earl T. Campbell, and Simon C. Benjamin.
Physical Review Letters 101 130502 (2008)
arXiv:0710.4352
Distributed quantum-information processing with minimal local resources.
Earl T. Campbell.
Physical Review A Rapid Communication 76 040302(R) (2007).
arXiv:0704.1464
Efficient growth of complex graph states via imperfect path erasure.
Earl T. Campbell, Joseph Fitzsimons, Simon C. Benjamin, and Pieter Kok.
New Journal of Physics 9, 196 (2007)
quant-ph/0702209
Adaptive strategies for graph state growth in the presence of monitored errors.
Earl T. Campbell, Joseph Fitzsimons, Simon C. Benjamin, and Pieter Kok.
Physical Review A 75, 042303 (2007)
quant-ph/0606199