Snir Gazit

Snir Gazit

Associate Professor
The Racah Institute of Physics
The Hebrew university of Jerusalem

List of publications

[1] E.Y. Cohen, F.F. Assaad, and S. Gazit. “Antiferromagnetism and Stripe Channel Order in the SU(N)-Symmetric Two-Channel Kondo Lattice Model.” arXiv e-prints, pp. arXiv:2509.12311 (2025).

[2] P.P. Belgaonkar, M. Zimmerman, S. Gazit, and D. Orgad. “Trimer superfluidity of antiparallel dipolar excitons in a bilayer heterostructure.” arXiv e-prints, pp. arXiv:2507.15938 (2025).

[3] U. Borla, A. De, and S. Gazit. “‘Odd’ Toric Code in a tilted field: Higgs-confinement multicriticality, spontaneous self-duality symmetry breaking, and valence bond solids.” arXiv e-prints, pp. arXiv:2507.16523 (2025).

[4] A. De, L. Radzihovsky, and S. Gazit. “Emergent Berezinskii-Kosterlitz-Thouless deconfinement in super-Coulombic plasmas.” arXiv e-prints, pp. arXiv:2506.05461 (2025).

[5] G. Segall, S. Gazit, and D. Podolsky. “Improved actions using the renormalization group.” Physical Review B, vol. 111, no. 18, pp. 184413 (2025).

[6] A. Noah, N. Fridman, Y. Zur, M. Markman, Y.K. King, M. Klang, R. Rama-Eiroa, H. Solanki, M.L.R. Ashby, T. Levin, and et al. “Field‑Induced Antiferromagnetic Correlations in a Nanopatterned Van der Waals Ferromagnet: A Potential Artificial Spin Ice.” Advanced Science, vol. 12, no. 5, pp. 2409240 (2025).

[7] L. Oppenheim, M. Koch-Janusz, S. Gazit, and Z. Ringel. “Machine learning the operator content of the critical self-dual Ising-Higgs lattice gauge theory.” Physical Review Research, vol. 6, no. 4, pp. 043322 (2024).

[8] U. Borla, S. Gazit, and S. Moroz. “Deconfined quantum criticality in Ising gauge theory entangled with single-component fermions.” Physical Review B, vol. 110, no. 20, pp. L201110 (2024).

[9] G. Shkolnik, S. Gopalakrishnan, D.A. Huse, S. Gazit, and J.H. Pixley. “Infinitely fast critical dynamics: Teleportation through temporal rare regions in monitored quantum circuits.” arXiv e-prints, pp. arXiv:2411.03442 (2024).

[10] A. De, U. Borla, X. Cao, and S. Gazit. “Stochastic sampling of operator growth dynamics.” Physical Review B, vol. 110, no. 15, pp. 155135 (2024).

[11] A. Noah, N. Fridman, Y. Zur, M. Markman, Y. Katz King, M. Klang, R. Rama-Eiroa, H. Solanki, M.L. Reichenberg Ashby, T. Levin, and et al. “Field-induced antiferromagnetic correlations in a nanopatterned van der Waals ferromagnet: a potential artificial spin ice.” arXiv e-prints, pp. arXiv:2410.07310 (2024).

[12] E.Y. Cohen, A. Alexandru, and S. Gazit. “Complex path simulations of geometrically frustrated ladders.” Physical Review B, vol. 109, no. 11, pp. 115122 (2024).

[13] S. Bhattacharyya, A. De, S. Gazit, and A. Auerbach. “Metallic transport of hard-core bosons.” Physical Review B, vol. 109, no. 3, pp. 035117 (2024).

[14] G. Shkolnik, A. Zabalo, R. Vasseur, D.A. Huse, J.H. Pixley, and S. Gazit. “Measurement induced criticality in quasiperiodic modulated random hybrid circuits.” Physical Review B, vol. 108, no. 18, pp. 184204 (2023).

[15] A. Zalic, T. Taniguchi, K. Watanabe, S. Gazit, and H. Steinberg. “High Magnetic Field Stability in a Planar Graphene-NbSe2 SQUID.” Nano Letters, vol. 23, no. 13, pp. 6102–6108 (2023).

[16] A. Noah, Y. Zur, N. Fridman, S. Singh, A. Gutfreund, E. Herrera, A. Vakahi, S. Remennik, M.E. Huber, S. Gazit, and et al. “Nano-Patterned Magnetic Edges in CrGeTe3 for Quasi 1-D Spintronic Devices.” ACS Applied Nano Materials, vol. 6, no. 10, pp. 8627–8634 (2023).

[17] P. Emonts, A. Kelman, U. Borla, S. Moroz, S. Gazit, and E. Zohar. “Finding the ground state of a lattice gauge theory with fermionic tensor networks: A 2 +1 D Z2 demonstration.” Physical Review D, vol. 107, no. 1, pp. 014505 (2023).

[18] M. Zimmerman, R. Rapaport, and S. Gazit. “Collective interlayer pairing and pair superfluidity in vertically stacked layers of dipolar excitons.” Proceedings of the National Academy of Science, vol. 119, no. 30, pp. e2205845119 (2022).

[19] A. Noah, F. Toric, T.D. Feld, G. Zissman, A. Gutfreund, D. Tsruya, T.R. Devidas, H. Alpern, A. Vakahi, H. Steinberg, and et al. “Tunable exchange bias in the magnetic Weyl semimetal Co3Sn2S2.” Physical Review B, vol. 105, no. 14, pp. 144423 (2022).

[20] F. Nathan, R. Ge, S. Gazit, M. Rudner, and M. Kolodrubetz. “Quasiperiodic Floquet-Thouless Energy Pump.” Physical Review Letters, vol. 127, no. 16, pp. 166804 (2021).

[21] M. Block, J. Motruk, S. Gazit, M.P. Zaletel, Z. Landau, U. Vazirani, and N.Y. Yao. “Performance of the rigorous renormalization group for first-order phase transitions and topological phases.” Physical Review B, vol. 103, no. 19, pp. 195122 (2021).

[22] M. Dupont, S. Gazit, and T. Scaffidi. “Evidence for deconfined U (1 ) gauge theory at the transition between toric code and double semion.” Physical Review B, vol. 103, no. 14, pp. L140412 (2021).

[23] M. Dupont, S. Gazit, and T. Scaffidi. “From trivial to topological paramagnets: The case of Z2 and Z23 symmetries in two dimensions.” Physical Review B, vol. 103, no. 14, pp. 144437 (2021).

[24] B. Kang, S.A. Parameswaran, A.C. Potter, R. Vasseur, and S. Gazit. “Superuniversality from disorder at two-dimensional topological phase transitions.” Physical Review B, vol. 102, no. 22, pp. 224204 (2020).

[25] Y. Slobodkin, Y. Mazuz-Harpaz, S. Refaely-Abramson, S. Gazit, H. Steinberg, and R. Rapaport. “Quantum Phase Transitions of Trilayer Excitons in Atomically Thin Heterostructures.” Physical Review Letters, vol. 125, no. 25, pp. 255301 (2020).

[26] S. Gazit, F.F. Assaad, and S. Sachdev. “Fermi Surface Reconstruction without Symmetry Breaking.” Physical Review X, vol. 10, no. 4, pp. 041057 (2020).

[27] P.A. Volkov, S. Gazit, and J.H. Pixley. “Magnon Bose-Einstein condensation and superconductivity in a frustrated Kondo lattice.” Proceedings of the National Academy of Science, vol. 117, no. 34, pp. 20462–20467 (2020).

[28] C.T. Olund, M. Block, S. Gazit, J. McGreevy, and N.Y. Yao. “Adiabatic ground state preparation in an expanding lattice.” Physical Review B, vol. 101, no. 15, pp. 155152 (2020).

[29] A. Bohrdt, A. Omran, E. Demler, S. Gazit, and F. Grusdt. “Multiparticle Interactions for Ultracold Atoms in Optical Tweezers: Cyclic Ring-Exchange Terms.” Physical Review Letters, vol. 124, no. 7, pp. 073601 (2020).

[30] T. Schuster, S. Gazit, J.E. Moore, and N.Y. Yao. “Floquet Hopf Insulators.” Physical Review Letters, vol. 123, no. 26, pp. 266803 (2019).

[31] P. Sidorenko, A. Dikopoltsev, T. Zahavy, O. Lahav, S. Gazit, Y. Shechtman, A. Szameit, D.J. Tannor, Y.C. Eldar, M. Segev, and et al. “Improving techniques for diagnostics of laser pulses by compact representations.” Optics Express, vol. 27, no. 6, pp. 8920 (2019).

[32] S. Gazit, F.F. Assaad, S. Sachdev, A. Vishwanath, and C. Wang. “Confinement transition of &Z;2 gauge theories coupled to massless fermions: Emergent quantum chromodynamics and SO(5) symmetry.” Proceedings of the National Academy of Science, vol. 115, no. 30, pp. E6987–E6995 (2018).

[33] M.H. Kolodrubetz, F. Nathan, S. Gazit, T. Morimoto, and J.E. Moore. “Topological Floquet-Thouless Energy Pump.” Physical Review Letters, vol. 120, no. 15, pp. 150601 (2018).

[34] S. Gazit, M. Randeria, and A. Vishwanath. “Emergent Dirac fermions and broken symmetries in confined and deconfined phases of Z2 gauge theories.” Nature Physics, vol. 13, no. 5, pp. 484–490 (2017).

[35] A. Lucas, S. Gazit, D. Podolsky, and W. Witczak-Krempa. “Dynamical Response near Quantum Critical Points.” Physical Review Letters, vol. 118, no. 5, pp. 056601 (2017).

[36] S. Gazit, D. Podolsky, H. Nonne, A. Auerbach, and D.P. Arovas. “Collective Modes in a Quantum Solid.” Physical Review Letters, vol. 117, no. 8, pp. 085302 (2016).

[37] I. Khait, S. Gazit, N.Y. Yao, and A. Auerbach. “Spin transport of weakly disordered Heisenberg chain at infinite temperature.” Physical Review B, vol. 93, no. 22, pp. 224205 (2016).

[38] S. Gazit and A. Vishwanath. “Bosonic topological phase in a paired superfluid.” Physical Review B, vol. 93, no. 11, pp. 115146 (2016).

[39] S. Gazit. “Dynamics Near Quantum Criticality in Two Space Dimensions.” (2015).

[40] S. Gazit, D. Podolsky, and A. Auerbach. “Critical Capacitance and Charge-Vortex Duality Near the Superfluid-to-Insulator Transition.” Physical Review Letters, vol. 113, no. 24, pp. 240601 (2014).

[41] O. Ofer, L. Marcipar, V. Ravi Chandra, S. Gazit, D. Podolsky, D.P. Arovas, and A. Keren. “Dynamic spin fluctuations at T 0 in a spin-1/2 ferromagnetic kagome lattice.” Physical Review B, vol. 89, no. 20, pp. 205116 (2014).

[42] S. Gazit, D. Podolsky, A. Auerbach, and D.P. Arovas. “Dynamics and conductivity near quantum criticality.” Physical Review B, vol. 88, no. 23, pp. 235108 (2013).

[43] S. Gazit, D. Podolsky, and A. Auerbach. “Fate of the Higgs Mode Near Quantum Criticality.” Physical Review Letters, vol. 110, no. 14, pp. 140401 (2013).

[44] A. Szameit, Y. Shechtman, E. Osherovich, E. Bullkich, P. Sidorenko, H. Dana, S. Steiner, E.B. Kley, S. Gazit, T. Cohen-Hyams, and et al. “Sparsity-based single-shot subwavelength coherent diffractive imaging.” Nature Materials, vol. 11, no. 5, pp. 455–459 (2012).

[45] S. Gazit, A. Szameit, Y.C. Eldar, and M. Segev. “Super-resolution and reconstruction of sparse sub-wavelength images: erratum.” Optics Express, vol. 18, no. 25, pp. 26631 (2010).

[46] A. Szameit, Y. Shechtman, H. Dana, S. Steiner, S. Gazit, T. Cohen-Hyams, E. Bullkich, O. Cohen, Y.C. Eldar, S. Shoham, and et al. “Far-Field Microscopy of Sparse Subwavelength Objects.” arXiv e-prints, pp. arXiv:1010.0631 (2010).

[47] Y. Shechtman, S. Gazit, A. Szameit, Y.C. Eldar, and M. Segev. “Super-resolution and reconstruction of sparse images carried by incoherent light.” Optics Letters, vol. 35, no. 8, pp. 1148 (2010).

[48] S. Gazit, A. Szameit, Y.C. Eldar, and M. Segev. “Super-resolution and reconstruction of sparse sub-wavelength images.” Optics Express, vol. 17, no. 26, pp. 23920 (2009).