PUBLICATIONS and PREPRINTS

33. Kasper, V., Zache, T.V., Jendrzejewksi, F. Lewenstein, M., and Zohar, E.,

Non-Abelian gauge invariance from dynamical decoupling,

arXiv:2012.08620 [quant-th] (2020)

32. Bender, J., and Zohar, E.,

A gauge redundancy-free formulation of compact QED with dynamical matter for quantum and classical computations,

Phys. Rev. D 102, 114517 (2020)

31. Bender, J., Emonts, P., Zohar, E. and Cirac, J.I.,

Real-time dynamics in 2+1d compact QED using complex periodic Gaussian states,

Phys. Rev. Research 2, 043145 (2020)

30. Emonts, P., Banuls, M.C., Cirac, J.I. and Zohar, E.,

Variational Monte Carlo simulation with tensor networks of a pure Z3 gauge theory in (2+1)d,

Phys. Rev. D 102, 074501 (2020)

29. Kasper, V., Juzeliunas, G., Lewenstein, M., Jendrzejewski, F. and Zohar, E.,

From the Jaynes-Cummings model to non-Abelian gauge theories: a guided tour for the quantum engineer,

New J. Phys. 22 103027 (2020)

28. Zohar, E.,

Local Manipulation and Measurement of Nonlocal Many-Body Operators in Lattice Gauge Theory Quantum Simulators,

Phys. Rev. D. 101, 034518 (2020)

27. Emonts, P. and Zohar, E.,

Gauss law, Minimal Coupling and Fermionic PEPS for Lattice Gauge Theories,

SciPost Phys. Lect. Notes 12 (2020)

​​26. Zohar, E. and Cirac, J.I..,

Removing Staggered Fermionic Matter in U(N) and SU(N) Lattice Gauge Theories,

Phys. Rev. D 99, 114511 (2019)

25. Cloët, I.C., Dietrich, M.R., Arrington, J., Bazavov, A., Bishof, M., Freese, A., Gorshkov, A.V., Grassellino, A., Hafidi, K., Jacob, Z., McGuigan, M., Meurice, Y., Meziani, Z., Mueller, P., Muschik, C., Osborn, J., Otten, M., Petreczky, P., Polakovic, T., Poon, A., Pooser, R., Roggero, A., Saffman, M., VanDevender, B., Zhang, J., and Zohar, E.,

Opportunities for Nuclear Physics & Quantum Information Science,

a white paper prepared from the results of a Fermilab workshop for the US department of Energy  FERMILAB-CONF-19-098-TD, arXiv:1903.05453 (2019)

24. Bender, J., Zohar, E., Farace, A., and Cirac, J.I.,

Digital Quantum Simulation of Lattice Gauge Theories in Three Spatial Dimensions,

New J. Phys. 20, 093001 (2018)

23. Zohar, E. and Cirac, J.I.,

Eliminating fermionic matter fields in lattice gauge theories,

Phys. Rev. B 98, 075119 (2018)

22. Zohar, E. and Cirac, J.I.,

Combining tensor networks with Monte Carlo methods for lattice gauge theories,

Phys Rev. D., 97 034510 (2018)

21. Kull, I., Molnar, A., Zohar, E. and Cirac, J.I.,

Classification of Matrix Product States with a Local (Gauge) Symmetry,

Ann. Phys. 386, 199 (2017)

20. González-Cuadra, D., Zohar, E. and Cirac, J.I.,

Quantum Simulation of the Abelian-Higgs Lattice Gauge Theory with Ultracold Atoms,

New J. Phys. 19, 063038 (2017)

19. Zohar, E.,

Half a State, Half an Operator: a General Formulation of Stators,

J. Phys. A: Math. Theor. 50, 085301 (2017)

18. Zohar, E., Farace, A., Reznik, B. and Cirac, J.I.,

Digital Lattice Gauge Theories,

Phys. Rev. A. 95, 023604 (2017)

17. Zohar, E., Farace, A., Reznik, B. and Cirac, J.I.,

Digital Quantum Simulation of Z2 Lattice Gauge Theories with Dynamical Fermionic Matter,

Phys. Rev. Lett. 118, 070501 (2017)

16. Zohar, E., Wahl, T.B., Burrello, M. and Cirac, J.I.,

Projected Entangled Pair States with Non-Abelian Gauge Symmetries: an SU(2) Study,

Ann. Phys. 374, 84 (2016)

15. Zohar, E. and Burrello, M.,

Building Projected Entangled Pair States with a Local Gauge Symmetry,

New J. Phys. 18, 043008 (2016)

14. Zohar, E.,

Quantum Simulation of Fundamental Physics,

Nature (News and Views) 534, 480 (2016)

13. Ber, R. and Zohar, E.,

Remote State Preparation for Quantum Fields,

Found. Phys. 46, 804 (2016)

12. Zohar, E., Cirac, J.I. and Reznik, B.,

Quantum Simulations of Lattice Gauge Theories using Ultracold Atoms in Optical Lattices,

Rep. Prog. Phys. 79, 014401 (2016)

11. Zohar, E., Burrello, M., Wahl, T.B. and Cirac, J.I.,

Fermionic Projected Entangled Pair States and Local U(1) Gauge Theories,

Ann. Phys. 363, 385 (2015)

10. Kühn, S., Zohar, E., Cirac, J.I. and Bañuls, M.C.,

Non-Abelian String Breaking Phenomena with Matrix Product States ,

JHEP 07, 130 (2015) 

9. Zohar, E. and Burrello, M.,

Formulation of Lattice Gauge Theories for Quantum Simulations,

Phys. Rev. D 91, 054506 (2015)

8. Zohar, E., Cirac, J.I. and Reznik, B.,

Quantum Simulations of Gauge Theories with Ultracold Atoms: Local Gauge Invariance from Angular Momentum Conservation,

Phys. Rev. A 88, 023617 (2013)

7. Zohar, E., and Reznik, B.,

Topological Wilson-Loop Area Law Manifested using a Superposition of Loops,

New J. Phys. 15, 043041 (2013)

6. Zohar, E., Cirac, J.I. and Reznik, B.,

Cold-Atom Quantum Simulator for SU(2) Yang-Mills Lattice Gauge Theory,

Phys. Rev. Lett. 110, 125304 (2013)

5. Zohar, E., Cirac, J.I. and Reznik, B.,

Simulating 2+1d Lattice QED with Dynamical Matter using Ultracold Atoms,

Phys. Rev. Lett. 110, 055302 (2013)

4. Zohar, E., Cirac, J.I. and Reznik, B.,

Simulating Compact Quantum Electrodynamics with Ultracold Atoms: Probing Confinement and Nonperturbative Effects,

Phys. Rev. Lett. 109, 125302 (2012)

3. Zohar, E., and Reznik, B.,

Confinement and QED Electric Flux-Tubes Simulated with Ultracold Atoms,

Phys. Rev. Lett. 107, 275301 (2011)

2. Zohar, E., and Reznik, B.,

The Fermi Problem in Discrete Systems,

New J. Phys. 13, 075016 (2011)

1. Jin, K., Bach, P., Zhang, X. H., Grupel, U., Zohar, E., Diamant, I., Dagan, Y., Smadici, S., Abbamonte, P. and Greene, R. L.,

Anomalous Enhancement of the Superconducting Transition Temperature of Electron-Doped La2-xCexCuO4 and Pr2-xCexCuO4 Cuprate Heterostructures,

Phys. Rev. B 83, 060511 (2011)

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