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Citations on Google Scholar

  1. S. Kim*, J.F. Mendez-Valderrama*, X. Wang* and Debanjan Chowdhury, Theory of Correlated Insulator(s) and Superconductor at  ν=1 in Twisted WSe2, arXiv:2406.03525. [arXiv]

  2. R. Mukherjee*, H. Guo*, K. Lewellen and Debanjan ChowdhuryArresting Quantum Chaos Dynamically in Transmon Arrays, arXiv:2405.14935. [arXiv]

  3. H. Guo, R. Mukherjee and Debanjan ChowdhuryDynamical Freezing in Exactly Solvable Models of Driven Chaotic Quantum Dots, arXiv:2405.01627. [arXiv] 

  4. X. Wang, J.F. Mendez-Valderrama, J.S. Hofmann and Debanjan Chowdhury, Intertwined magnetism and superconductivity in isolated correlated flat bands, Phys. Rev. B 110, L041105 (2024). [arXiv] (Letter (Editors' suggestion)

  5. S. Kim, M. Saad, D. Mao, A. Agarwala and Debanjan Chowdhury, Quasicrystalline spin liquids, arXiv:2402.07971. [arXiv]

  6. J.F. Mendez-Valderrama, D. Mao and Debanjan Chowdhury, A theory for the low-energy optical sum-rule in moiré graphene, arXiv:2312.03819. [arXiv]

  7. W. Zhao*, B. Shen*, Z. Tao*, S. Kim, P. Knüppel, Z. Han, Y. Zhang, K. Watanabe, T. Taniguchi, Debanjan Chowdhury, J. Shan, K.F. Mak, Emergence of ferromagnetism at the onset of moiré Kondo breakdown, arXiv:2310.06044 (2023). [arXiv]

  8. X. Wang, R. Moessner and Debanjan Chowdhury, Interaction-mitigated Landau damping, Phys. Rev. B 109, L121102 (2024). [arXiv] (Letter)

  9. T.G. Kiely and Debanjan Chowdhury, Continuous Wigner-Mott Transition at nu=1/5, arXiv:2305.13355. [arXiv]

  10. D. Mao and Debanjan Chowdhury, Upper bounds on superconducting and excitonic phase-stiffness for interacting isolated narrow bands, Phys. Rev. B 109, 024507 (2024). [arXiv] (Editors' suggestion)

  11. Z. Yang, B. Fauque, T. Nomura, T. Shitaokoshi, S. Kim, Debanjan Chowdhury, Z. Pribulova, J. Kacmarcik, A. Pourret, G. Knebel, D. Aoki, T. Klein, D. K. Maude, C. Marcenat, Y. Kohama, Unveiling the double-peak structure of quantum oscillations in the specific heat, Nature Communications 14, 7006 (2023). [arXiv]

  12. J.F. Mendez-Valderrama*, E. Tulipman*, E. Zhakina, A.P. Mackenzie, E. Berg and Debanjan ChowdhuryT-linear resistivity from magneto-elastic scattering: application to PdCrO2, Proceedings of the National Academy of Sciences 120 (36), e2305609120 (2023). [arXiv]

  13. E. Zhakina, R. Daou, A. Maignan, P.H. McGuinness, M. König, H. Rosner, S. Kim, S. Khim, R. Grasset, M. Konczykowski, E. Tulipman, J.F. Mendez-Valderrama, Debanjan Chowdhury, E. Berg, and A.P. Mackenzie,  Investigation of Planckian behavior in a high-conductivity oxide: PdCrO2, Proceedings of the National Academy of Sciences 120 (36), e2307334120 (2023). [arXiv]

  14. S.J. Thornton, D. Liarte, P. Abbamonte, J.P. Sethna and Debanjan Chowdhury, Jamming and unusual charge density fluctuations of strange metals, Nature Communications 14, 3919 (2023). [arXiv]

  15. D. Mao and Debanjan Chowdhury, Diamagnetic response and phase stiffness for interacting isolated narrow bands, Proceedings of the National Academy of Sciences 120 (11), e2217816120 (2023). [arXiv]

  16. X. Wang and Debanjan Chowdhury, Collective density fluctuations of strange metals with critical Fermi surfaces, Phys. Rev. B 107, 125157 (2023). [arXiv(Editors' suggestion) 

  17. A.J. McRoberts*, J.F. Mendez-Valderrama*, R. Moessner and Debanjan Chowdhury, Intermediate-scale theory for electrons coupled to frustrated local-moments, Phys. Rev. B 107, L020402 (2023). [arXiv] (Letter)

  18. S. Kim, A. Agarwala and Debanjan Chowdhury, Fractionalization and topology in amorphous electronic solids, Phys. Rev. Lett. 130, 026202 (2023). [arXiv]

  19. S. Kim, T. Senthil and Debanjan Chowdhury, Continuous Mott transition in moiré semiconductors: role of long-wavelength inhomogeneities, Phys. Rev. Lett. 130, 066301 (2023). [arXiv]

  20. J.S. Hofmann, E. Berg and Debanjan ChowdhurySuperconductivity, charge density wave and supersolidity in flat bands with tunable quantum metric, Phys. Rev. Lett. 130, 226001 (2023). [arXiv]

  21. S. Xie, B.D. Faeth, Y. Tang, L. Li, E. Gerber, C.T. Parzyck, Debanjan Chowdhury, Y.H. Zhang, C. Jozwiak, A. Bostwick, E. Rotenberg, E-A. Kim, J. Shan, K.F. Mak, K.M. Shen, Strong interlayer interactions in bilayer and trilayer moiré superlatticesScience Advances 8, eabk1911 (2022).

  22. D. Liarte, S.J. Thornton, E. Schwen, I. Cohen, Debanjan Chowdhury, J.P. Sethna, Universal scaling for disordered viscoelastic matter II: Collapses, global behavior and spatio-temporal properties, arXiv:2202.13933. [arXiv]

  23. D. Liarte, S.J. Thornton, E. Schwen, I. Cohen, Debanjan Chowdhury, J.P. Sethna, Universal scaling for disordered viscoelastic matter near the onset of rigidity, Phys. Rev. E 106, L052601 (2022). [arXiv(Letter)

  24. S. Musser, T. Senthil and Debanjan Chowdhury, Theory of a continuous bandwidth-tuned Wigner-Mott transition, Phys. Rev. B 106, 155145 (2022). [arXiv]

  25. S. Musser, Debanjan Chowdhury, P.A. Lee and T. Senthil, Interpreting angle dependent magnetoresistance in layered materials: application to cuprates, Phys. Rev. B 105, 125105 (2022). [arXiv]

  26. Debanjan Chowdhury, A. Georges, O. Parcollet and S. Sachdev, Sachdev-Ye-Kitaev Models and Beyond: A Window into Non-Fermi Liquids, Rev. Mod. Phys. 94, 035004 (2022). [arXiv]

  27. J.S. Hofmann, Debanjan Chowdhury, S.A. Kivelson and E. Berg, Heuristic bounds on superconductivity and how to exceed them, npj Quantum Materials 7, 83 (2022). [arXiv]

  28. T. Li, S. Jiang, L. Li, Y. Zhang, K. Kang, J. Zhu, K. Watanabe, T. Taniguchi, Debanjan Chowdhury, L. Fu, J. Shan, K.F. Mak, Continuous Mott transition in semiconductor moiré superlattices, Nature 597, 350 (2021). [arXiv]

  29. C. Lewandowski, S. Nadj-Perge and Debanjan Chowdhury, Does filling-dependent band renormalization aid pairing in twisted bilayer graphene?, npj Quantum Materials 6, 82 (2021). [arXiv]

  30. J.F. Mendez-Valderrama and Debanjan Chowdhury, Bad metallic transport in geometrically frustrated models, Phys. Rev. B 103, 195111 (2021). [arXiv]

  31. C. Lewandowski, Debanjan Chowdhury and J. Ruhman, Pairing in magic-angle twisted bilayer graphene: role of phonon and plasmon umklapp, Phys. Rev. B 103, 235401 (2021). [arXiv] (Editors' suggestion)

  32. L. Zou and Debanjan Chowdhury, Deconfined metal-insulator transitions in quantum Hall bilayers, Phys. Rev. Research 2, 032071(R) (2020). [arXiv] (Rapid Communication)

  33. L. Zou and Debanjan Chowdhury, Deconfined metallic quantum criticality: a U(2) gauge theoretic approach, Phys. Rev. Research 2, 023344 (2020). [arXiv]

  34. J.S. Hofmann, E. Berg and Debanjan Chowdhury, Superconductivity, pseudogap and phase separation in topological flat bands, Phys. Rev. B 102, 201112(R) (2020). [arXiv] (Rapid Communication) (Editors' suggestion)

  35. Debanjan Chowdhury and E. Berg, The unreasonable effectiveness of Eliashberg theory for pairing of non-Fermi liquids, Annals of Physics 417, 168125 (2020). (Special issue dedicated to Gerasim Eliashberg.) [arXiv]

  36. Debanjan Chowdhury and E. Berg, Intrinsic superconducting instabilities of a solvable model for an incoherent metal, Phys. Rev. Research 2, 013301 (2020). [arXiv]

  37. D. Mao, Debanjan Chowdhury, T. Senthil, Slow scrambling and hidden integrability in a random rotor model, Phys. Rev. B 102, 094306 (2020). [arXiv]

  38. Y. Cao*, Debanjan Chowdhury*, D. Rodan-Legrain, O. Rubies-Bigorda, K. Watanabe, T. Taniguchi, T. Senthil and P. Jarillo-Herrero, Strange metal in magic-angle graphene with near Planckian dissipation, Phys. Rev. Lett. 124, 076801 (2020). [arXiv] (Editors' suggestion)
    [Featured in a Physics viewpoint article,
    Graphene reveals its strange side, by Subir Sachdev.]

  39. T.A. Webb, M.C. Boyer, Y. Yin, Debanjan Chowdhury, Y. He, T. Kondo, T. Takeuchi, H. Ikuta, E.W. Hudson, J.E. Hoffman and M.H. Hamidian, Density wave probes cuprate quantum phase transition, Phys. Rev. X 9, 021021 (2019). [arXiv

  40. A. Zhong, X. Shen, A. Kogar, L. Ye, C. Marks, Debanjan Chowdhury, T. Rohwer, B. Freelon, S. Weathersby, R. Li, J. Yang, J. Checkelsky, X. Wang and N. Gedik, Ultrafast manipulation of mirror domain walls in a charge density waveScience Advances 4, eaau5501 (2018). [arXiv]

  41. Debanjan Chowdhury, Y. Werman, E. Berg and T. Senthil, Translationally invariant non-Fermi liquids with critical Fermi-surfaces: Solvable models, Phys. Rev. X 8, 031024 (2018). [arXiv]

  42. Debanjan Chowdhury*, B. Skinner* and P.A. Lee, Semiclassical theory of the tunneling anomaly in partially spin-polarized compressible quantum Hall states, Phys. Rev. B 97, 195114 (2018). [arXiv]

  43. A. Klein, S. Lederer, Debanjan Chowdhury, E. Berg and A.V. Chubukov, Dynamical susceptibility of a near-critical non-conserved order parameter and B2g Raman response in Fe-based superconductors, Phys. Rev. B 98, 041101(R) (2018). [arXiv] (Rapid Communication

  44. Debanjan Chowdhury*, B. Skinner* and P.A. Lee, Effect of magnetization on the tunneling anomaly in compressible quantum Hall states, Phys. Rev. Lett. 120, 266601 (2018). [arXiv]

  45. I. Sodemann, Debanjan Chowdhury and T. Senthil, Quantum oscillations in insulators with neutral Fermi-surfaces, Phys. Rev. B 97, 045152 (2018). [arXiv]

  46. A. Klein, S. Lederer, Debanjan Chowdhury, E. Berg and A.V. Chubukov, Dynamical susceptibility near a long-wavelength critical point with a non-conserved order parameter, Phys. Rev. B 97, 155115 (2018). [arXiv]

  47. Debanjan Chowdhury, I. Sodemann and T. Senthil, Mixed-valence insulators with neutral Fermi-surfacesNature Communications 9, 1766 (2018). [arXiv

  48. A.A. Patel, Debanjan Chowdhury, S. Sachdev and B. Swingle, Quantum butterfly effect in weakly interacting diffusive metals, Phys. Rev. X 7, 031047 (2017). [arXiv]

  49. Debanjan Chowdhury and B. Swingle, Onset of many-body chaos in the O(N) model, Phys. Rev. D 96, 065005 (2017). [arXiv]

  50. B. Swingle and Debanjan Chowdhury, Slow scrambling in disordered quantum systems, Phys. Rev. B 95, 060201(R) (2017). [arXiv] (Rapid Communication) (Editors' suggestion)

  51. A.A. Patel and Debanjan Chowdhury, Two dimensional spin liquids with Z2 topological order in an array of quantum wires, Phys. Rev. B 94, 195130 (2016). [arXiv]

  52. S. Sachdev and Debanjan ChowdhuryThe novel metallic states of the cuprates: topological Fermi liquids and strange metals, Progress of Theoretical and Experimental Physics 12C102 (2016). (Special issue: "Nambu, A foreteller of Modern Physics III"). [arXiv]

  53. A.A. Patel, Debanjan Chowdhury, A. Allais and S. Sachdev, Confinement transition to density wave order in metallic doped spin liquidsPhys. Rev. B 93, 165139 (2016). [arXiv

  54. Y. Wang, Debanjan Chowdhury, and A.V. Chubukov, Fluctuating charge order in the cuprates: spatial anisotropy and feedback from superconductivity,  Phys. Rev. B 92, 161103(R) (2015). [arXiv] (Rapid Communication)

  55. Debanjan Chowdhury, J. Orenstein, S. Sachdev and T. Senthil, Phase transition beneath the superconducting dome in BaFe2(As1-xPx)2Phys. Rev. B 92, 081113(R) (2015). [arXiv] (Rapid Communication)

  56. Debanjan Chowdhury and S. Sachdev, The enigma of the pseudogap phase of the cuprate superconductors, Invited chapter in the book "Quantum criticality in condensed matter" (World Scientific, ISBN: 978-981-4704-08-3). [arXiv] [Publisher]

  57. Debanjan Chowdhury and S. Sachdev, Higgs criticality in a two-dimensional metal, Phys. Rev. B 91, 115123 (2015)[arXiv]

  58. Debanjan Chowdhury and S. Sachdev, Density wave instabilities of fractionalized Fermi liquidsPhys. Rev. B 90, 245136 (2014). [arXiv]

  59. A. Allais, Debanjan Chowdhury and S. Sachdev, Connecting high-field quantum oscillations to zero-field electron spectral functions in the underdoped cuprates, Nature Communications 5, 5771 (2014). [arXiv]

  60. Debanjan Chowdhury and S. Sachdev, Feedback of superconducting fluctuations on charge order in the underdoped cupratesPhys. Rev. B 90, 134516 (2014). [arXiv]

  61. M. Punk, Debanjan Chowdhury and S. Sachdev, Topological excitations and the dynamic structure factor of spin liquids on the kagome lattice, Nature Physics 10, 289-293 (2014). [arXiv]

  62. Debanjan Chowdhury, B. Swingle, E. Berg and S. Sachdev, Singularity of the London penetration depth at quantum critical points in superconductors, Phys. Rev. Lett. 111, 157004 (2013). [arXiv]

  63. Debanjan Chowdhury, S. Raju, S. Sachdev, A. Singh and P. Strack, Multipoint correlators of conformal field theories: implications for quantum critical transport, Phys. Rev. B 87, 085138 (2013). [arXiv]

  64. P. Mandal, Debanjan Chowdhury, S.S. Banerjee and T. Tamegai, High sensitivity differential Magneto-Optical imaging with a compact Faraday-modulator, Review of Scientific Instruments 83, 123906 (2012). [arXiv]

  65. D. Bergeron, Debanjan Chowdhury, M. Punk, S. Sachdev and A.-M.S. Tremblay, Breakdown of Fermi liquid behavior at the (π,π)=2kF spin-density wave quantum critical point: the case of electron-doped cuprates, Phys. Rev. B 86, 155123 (2012). [arXiv] (Editors' suggestion)   

  66. N. W. Goehring, P. K. Trong, J. S. Bois, Debanjan Chowdhury, E. M. Nicola, A. A. Hyman and S. W. Grill, Polarization of PAR Proteins by Advective Triggering of a Pattern-Forming system, Science 334, 6059, 1137-1141 (2011). (Editors' choice
    [Highlighted in: Current Biology 22, 2, R58-R61 (2012), and, Developmental Cell 21, 6, 981-982 (2011).]

  67. Debanjan Chowdhury, E. Berg and S. Sachdev, Nematic order in the vicinity of a vortex in superconducting FeSe, Phys. Rev. B 84, 205113 (2011). [arXiv

  68. N. W. Goehring, Debanjan Chowdhury, A. A. Hyman and S. W. Grill, FRAP Analysis of Membrane-Associated Proteins: Lateral Diffusion and Membrane-Cytoplasmic Exchange, Biophysical Journal 99, 8, 2443-2452 (2010)

  69. Debanjan Chowdhury and M.C. Cross, Synchronization of oscillators with long range power law interactions, Phys. Rev. E 82, 016205 (2010). [arXiv]

  70. Debanjan Chowdhury, U. Divakaran and A. Dutta, Adiabatic dynamics in passage across quantum critical lines and gapless phases, Phys. Rev. E 81, 012101 (2010). [arXiv]

  71. A. Garai, Debanjan Chowdhury, D. Chowdhury and T.V. Ramakrishnan, Stochastic kinetics of ribosomes: Single motor properties and collective behavior, Phys. Rev. E 80, 011908 (2009). [arXiv]

  72. Debanjan ChowdhurySearching for targets on a model DNA: Effects of inter-segment hopping, detachment and re-attachmentInt. J Mod. Phys. C 20, 6, 817-830 (2009). [arXiv]

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