Quantized current steps due to the ac coherent quantum phase-slip effect

  • Josephson, BD Possible new effects in superconductive tunneling. Phys. Lett. 1251-253 (1962).

    ADS Article Google Scholar

  • Shapiro, S. Josephson currents in superconducting tunneling: the effect of microwaves and other observations. Phys. Rev. Lett. 1180–82 (1963).

    ADS CAS Article Google Scholar

  • Averin, DV & Likharev, KK in Mesoscopic Phenomena in Solids (eds Altshuler, BL et al.) Ch. 6 (North Holland, 1991).

  • Mooij, JE & Nazarov, YV Superconducting nanowires as quantum phase-slip junctions. nat. Phys. two169–172 (2006).

    CAS Article Google Scholar

  • Averin, DV, Zorin, AB & Likharev, KK Bloch oscillations in small Josephson junctions. Sov. Phys. JETP 61407-413 (1985).

    Google Scholar ADS

  • Pekola, JP et al. Single-electron current sources: toward a refined definition of the ampere. Rev. Mod. Phys. 851421–1472 (2013).

    ADS Article Google Scholar

  • Astafiev, OV et al. Coherent quantum phase slip. nature 484355–358 (2012).

    ADS CAS Article Google Scholar

  • Zener, CM Non-adiabatic crossing of energy levelsproc. process R. Soc. London THE https://doi.org/10.1098/rspa.1932.0165 (1932).

  • Golubev, DS & Zaikin, AD Quantum tunneling of the order parameter in superconducting nanowires. Phys. Rev. B 64014504 (2001).

    ADS Article Google Scholar

  • Schön, G. & Zaikin, AD Quantum coherent effects, phase transitions, and the dissipative dynamics of ultra small tunnel junctions. Phys. Rep. 198237-412 (1990).

    ADS Article Google Scholar

  • Tinkham, M. Introduction to Superconductivity 2nd edn (McGraw Hill, 1996).

  • Kuzmin, LS & Haviland, DB Observation of the Bloch oscillations in an ultrasmall Josephson junction. Phys. Rev. Lett. 672890-2893 (1991).

    ADS CAS Article Google Scholar

  • Kuzmin, L., Pashkin, Y., Zorin, A. & Claeson, T. Linewidth of Bloch oscillations in small Josephson junctions. Physics B 203376-380 (1994).

    ADS CAS Article Google Scholar

  • Landau, LD On the theory of energy transmission in collisions. I. Phys. Zs. sowjet 188 (1932).

    CAS Google Scholar

  • Zaikin, AD, Golubev, DS, van Otterlo, A. & Zimanyi, T. Quantum phase slips and transport in ultrathin superconducting wires. Phys. Rev. Lett. 781552 (1997).

    ADS CAS Article Google Scholar

  • Peltonen, JT et al. Coherent flux tunneling through NbN nanowires. Phys. Rev. B 88220506 (2013).

    ADS Article Google Scholar

  • Peltonen, JT et al. Coherent dynamics and decoherence in a superconducting weak link. Phys. Rev. B 94180508 (2016).

    ADS Article Google Scholar

  • de Graaf, SE et al. Charge quantum interference device. nat. Phys. 14590–594 (2018).

    Article Google Scholar

  • Linzen, S. et al. Structural and electrical properties of ultrathin niobium nitride films grown by atomic layer deposition. Supercond. Sci. Technol. 30035010 (2017).

    ADS Article Google Scholar

  • Sacépé, B., Feigel’man, M. & Klapwijk, TM Quantum breakdown of superconductivity in low-dimensional materials. nat. Phys. 16734–746 (2020).

    Article Google Scholar

  • Zaitsev, AV Quasiclassical equations of the theory of superconductivity for contiguous metals and the properties of constricted microcontacts. Sov. Phys. JETP 591015–1024 (1984).

    Google Scholar ADS

  • Abay, S. et al. Charge transport in InAs nanowire Josephson junctions. Phys. Rev. B 89214508 (2014).

    ADS Article Google Scholar

  • de Graaf, SE, Shaikhaidarov, R., Lindström, T., Tzalenchuk, AY & Astafiev, OV Charge control of blockade of Cooper pair tunneling in highly disordered tin nanowires in an inductive environment. Phys. Rev. B 99205115 (2019).

    ADS Article Google Scholar

  • Glück, M., Kolovsky, AR & Korsch, HJ Wannier–Stark resonances in optical and semiconductor superlattices. Phys. Rep. 366103–182 (2002).

    ADS MathSciNet Article Google Scholar

  • Barone, A. & Paterno, G. Physics and Applications of the Josephson Effect vol. 1 (John Wiley & Sons, 1982).

  • Averin, DV, Nazarov, YV & Odintsov, AA Incoherent tunneling of the Cooper pairs and magnetic flux quanta in ultrasmall Josephson junctions. Physics B 165945-946 (1990).

    ADS Article Google Scholar

  • Tien, PK & Gordon, JP Multiphoton process observed in the interaction of microwave fields with the tunneling between superconductor films. Phys. Rev. 129647-651 (1963).

    ADS Article Google Scholar

  • Roychowdhury, A., Dreyer, M., Anderson, JR, Lobb, CJ & Wellstood, FC Microwave photon-assisted incoherent Cooper-pair tunneling in a Josephson STM. Phys. Rev. App. 4034011 (2015).

    ADS Article Google Scholar

  • Kot, P. et al. Microwave-assisted tunneling and interference effects in superconducting junctions under fast driving signals. Phys. Rev. B 101134507 (2020).

    ADS CAS Article Google Scholar

  • Giazotto, F., Heikkilä, TT, Luukanen, A., Savin, AM & Pekola, JP Opportunities for mesoscopics in thermometry and refrigeration: physics and applications. Rev. Mod. Phys. 78217 (2006).

    ADS CAS Article Google Scholar

  • Giblin, SP et al. Realization of a quantum current standard at liquid helium temperature with sub-ppm reproducibility. Metrology. 57025013 (2020).

    ADS CAS Article Google Scholar

  • Yamahata, G., Giblin, SP, Kataoka, M., Karasawa, T. & Fujiwara, A. High-accuracy current generation in the nanoampere regime from a silicon single-trap electron pump. Sci. Rep. 745137 (2017).

    ADS CAS Article Google Scholar

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