Gleb Finkelstein
Physics
Professor of Physics
Research Interests
My main research topic is the study of the coexistence of superconductivity and the quantum Hall effect. The highlights of this work include: the first observation of a superconducting current induced in the regime of the quantum Hall effect, realization of the quantum Hall-based SQUID, and the first observation of the chiral Andreev edge states predicted 20 years ago. The unique combination of the two of the most robust quantum states – quantum Hall effect and superconductivity – is interesting in its own right; it also promises future applications in quantum information science, e.g. for creation of topologically protected states and excitations. Other research directions of our lab include: multi-terminal Josephson junctions which we developed in ballistic graphene; thermal conductivity measurements; studies of the novel two-dimensional superconductor KTaO_3.
Bio
Gleb Finkelstein is an experimentalist interested in physics of quantum nanostructures, such as Josephson junctions and quantum dots made of carbon nanotubes, graphene, and topological materials. These objects reveal a variety of interesting electronic properties that may form a basis for future quantum devices.
Education
- B.S. Moscow Institute of Physics and Technology (Russia), 1991
- Ph.D. Weizmann Institute of Science (Israel), 1998
Positions
- Professor of Physics
- Professor in the Department of Electrical and Computer Engineering
- Faculty Network Member of the Duke Institute for Brain Sciences
Awards, Honors, and Distinctions
- Fellow. American Physical Society. 2015
- Faculty Early Career Development (CAREER) Program. National Science Foundation. 2003
- Faculty Early Career Development (CAREER) Award. National Science Foundation. 2003
- Award for excellence in graduate research. Wolf Foundation. 1998
- Daniel Brener Memorial Prize for Ph.D. studies. Graduate School, Weizmann Institute of Science. 1996
- Distinction Prize for M.Sc. studies. Graduate School, Weizmann Institute of Science. 1993
Courses Taught
- PHYSICS 760: Mathematical Methods of Physics
- PHYSICS 509: Quantum Nanophysics
- PHYSICS 495: Thesis Independent Study
- PHYSICS 493: Research Independent Study
- PHYSICS 465: Quantum Mechanics II
- PHYSICS 371L: Electronics for physics measurements and instrumentation
- PHYSICS 271L: Electronics
Publications
- Arnault EG, Chiles J, Larson TFQ, Chen C-C, Zhao L, Watanabe K, et al. Multiplet Supercurrents in a Josephson Circuit. 2024.
- Zhao L, Larson TFQ, Iftikhar Z, Chiles J, Watanabe K, Taniguchi T, et al. Thermal properties of the superconductor-quantum Hall interfaces. 2024.
- Zhao L, Arnault EG, Larson TFQ, Watanabe K, Taniguchi T, Amet F, et al. Nonlocal transport measurements in hybrid quantum Hall-superconducting devices. Physical Review B. 2024 Mar 15;109(11).
- Zhao L, Arnault EG, Larson TFQ, Watanabe K, Taniguchi T, Amet F, et al. Non-local transport measurements in hybrid quantum Hall - superconducting devices. 2023.
- Zhao L, Iftikhar Z, Larson TFQ, Arnault EG, Watanabe K, Taniguchi T, et al. Loss and Decoherence at the Quantum Hall-Superconductor Interface. Physical review letters. 2023 Oct;131(17):176604.
- Chiles J, Arnault EG, Chen C-C, Larson TFQ, Zhao L, Watanabe K, et al. Nonreciprocal Supercurrents in a Field-Free Graphene Josephson Triode. Nano letters. 2023 Jun;23(11):5257–63.
- Arnault EG, Al-Tawhid AH, Salmani-Rezaie S, Muller DA, Kumah DP, Bahramy MS, et al. Anisotropic superconductivity at KTaO3(111) interfaces. Science advances. 2023 Feb;9(7):eadf1414.
- Larson TFQ, Zhao L, Arnault EG, Wei M-T, Seredinski A, Li H, et al. Noise-induced stabilization of dynamical states with broken time-reversal symmetry. 2022.
- Zhao L, Arnault EG, Larson TFQ, Iftikhar Z, Seredinski A, Fleming T, et al. Graphene-Based Quantum Hall Interferometer with Self-Aligned Side Gates. Nano letters. 2022 Dec;22(23):9645–51.
- Zhao L, Iftikhar Z, Larson TFQ, Arnault EG, Watanabe K, Taniguchi T, et al. Loss and decoherence at the quantum Hall - superconductor interface. 2022.
- Chiles J, Arnault EG, Chen C-C, Larson TFQ, Zhao L, Watanabe K, et al. Non-Reciprocal Supercurrents in a Field-Free Graphene Josephson Triode. 2022.
- Arnault EG, Idris S, McConnell A, Zhao L, Larson TFQ, Watanabe K, et al. Dynamical Stabilization of Multiplet Supercurrents in Multiterminal Josephson Junctions. Nano letters. 2022 Sep;22(17):7073–9.
- Zhao L, Arnault EG, Larson TFQ, Iftikhar Z, Seredinski A, Fleming T, et al. Graphene-based quantum Hall interferometer with self-aligned side gates. 2022.
- Arnault EG, Idris S, McConnell A, Zhao L, Larson TFQ, Watanabe K, et al. Dynamical Stabilization of Multiplet Supercurrents in Multi-terminal Josephson Junctions. 2022.
- Arnault EG, Larson TFQ, Seredinski A, Zhao L, Idris S, McConnell A, et al. Multiterminal Inverse AC Josephson Effect. Nano letters. 2021 Nov;21(22):9668–74.
- Seredinski A, Arnault EG, Costa VZ, Zhao L, Larson TFQ, Watanabe K, et al. One-dimensional edge contact to encapsulated MoS
2 with a superconductor. AIP Advances. 2021 Apr 1;11(4). - Zhang G, Chung C-H, Ke C-T, Lin C-Y, Mebrahtu H, Smirnov AI, et al. Nonequilibrium quantum critical steady state: Transport through a dissipative resonant level. Physical Review Research. 2021 Feb 11;3(1).
- Seredinski A, Arnault EG, Costa VZ, Zhao L, Larson TFQ, Watanabe K, et al. One-Dimensional Edge Contact to Encapsulated MoS2 with a Superconductor. 2021.
- Arnault EG, Larson T, Seredinski A, Zhao L, Idris S, McConnell A, et al. The Multi-terminal Inverse AC Josephson Effect. 2020.
- Larson TFQ, Zhao L, Arnault EG, Wei M-T, Seredinski A, Li H, et al. Zero Crossing Steps and Anomalous Shapiro Maps in Graphene Josephson Junctions. Nano letters. 2020 Oct;20(10):6998–7003.
- Zhao L, Arnault EG, Bondarev A, Seredinski A, Larson T, Draelos AW, et al. Interference of Chiral Andreev Edge States. Nature Physics. 2020 May 18;16:862–7.
- Larson TFQ, Zhao L, Arnault EG, Wei MT, Seredinski A, Li H, et al. Zero-bias crossings and peculiar Shapiro maps in graphene Josephson junctions. 2020.
- Ke CT, Draelos AW, Seredinski A, Wei MT, Li H, Hernandez-Rivera M, et al. Anomalous periodicity of magnetic interference patterns in encapsulated graphene Josephson junctions. Physical Review Research. 2019 Nov 7;1(3).
- Wei MT, Draelos AW, Seredinski A, Ke CT, Li H, Mehta Y, et al. Chiral quasiparticle tunneling between quantum Hall edges in proximity with a superconductor. Physical Review B. 2019 Sep 10;100(12).
- Seredinski A, Draelos AW, Arnault EG, Wei M-T, Li H, Fleming T, et al. Quantum Hall-based superconducting interference device. Science advances. 2019 Sep;5(9):eaaw8693.
- Ke CT, Draelos AW, Seredinski A, Wei MT, Li H, Hernandez-Rivera M, et al. 2$Φ_{0}$-periodic magnetic interference in ballistic graphene Josephson junctions. 2019.
- Draelos AW, Silverman A, Eniwaye B, Arnault EG, Ke CT, Wei MT, et al. Subkelvin lateral thermal transport in diffusive graphene. Physical Review B. 2019 Mar 29;99(12).
- Draelos AW, Wei M-T, Seredinski A, Li H, Mehta Y, Watanabe K, et al. Supercurrent Flow in Multiterminal Graphene Josephson Junctions. Nano letters. 2019 Feb;19(2):1039–43.
- Seredinski A, Draelos A, Wei MT, Ke CT, Fleming T, Mehta Y, et al. Supercurrent in Graphene Josephson Junctions with Narrow Trenches in the Quantum Hall Regime. MRS Advances. 2018 Jan 1;3(47–48):2855–64.
- Finkelstein G, Amet F. Superconductivity: When Andreev meets Hall. Nature Physics. 2017 Jul 1;13(7):625–6.
- Draelos A, Wei MT, Seredinski A, Ke C, Watanabe K, Taniguchi T, et al. Investigation of Supercurrent in the Quantum Hall Regime in Graphene Josephson Junctions. Submitted to the Journal of Low Temperature Physics. 2017;
- Borzenets IV, Amet F, Ke CT, Draelos AW, Wei MT, Seredinski A, et al. Ballistic Graphene Josephson Junctions from the Short to the Long Junction Regimes. Physical review letters. 2016 Dec;117(23):237002.
- Ke CT, Borzenets IV, Draelos AW, Amet F, Bomze Y, Jones G, et al. Critical Current Scaling in Long Diffusive Graphene-Based Josephson Junctions. Nano letters. 2016 Aug;16(8):4788–91.
- Amet F, Ke CT, Borzenets IV, Wang J, Watanabe K, Taniguchi T, et al. Supercurrent in the quantum Hall regime. Science (New York, NY). 2016 May;352(6288):966–9.
- Zhang X, Gutierrez Y, Li P, Barreda AI, Watson AM, Alcaraz De La Osa R, et al. Plasmonics in the UV range with Rhodium nanocubes. In: Proceedings of SPIE - The International Society for Optical Engineering. 2016.
- Amet F, Finkelstein G. Valleytronics: Could use a break. Nature Physics. 2015 Dec 1;11(12):989–90.
- Watson AM, Zhang X, Alcaraz de la Osa R, Marcos Sanz J, González F, Moreno F, et al. Rhodium nanoparticles for ultraviolet plasmonics. Nano letters. 2015 Feb;15(2):1095–100.
- Li J, Ke C-T, Liu K, Li P, Liang S, Finkelstein G, et al. Importance of diameter control on selective synthesis of semiconducting single-walled carbon nanotubes. ACS nano. 2014 Aug;8(8):8564–72.
- Liu DE, Zheng H, Finkelstein G, Baranger HU. Tunable quantum phase transitions in a resonant level coupled to two dissipative baths. Physical Review B - Condensed Matter and Materials Physics. 2014 Feb 18;89(8).
- Pilo-Pais M, Watson A, Demers S, LaBean TH, Finkelstein G. Surface-enhanced Raman scattering plasmonic enhancement using DNA origami-based complex metallic nanostructures. Nano letters. 2014 Jan;14(4):2099–104.
- Borzenets IV, Coskun UC, Mebrahtu HT, Bomze YV, Smirnov AI, Finkelstein G. Phonon bottleneck in graphene-based Josephson junctions at millikelvin temperatures. Physical review letters. 2013 Jul;111(2):027001.
- Chung CH, Le Hur K, Finkelstein G, Vojta M, Wölfle P. Nonequilibrium quantum transport through a dissipative resonant level. Physical Review B - Condensed Matter and Materials Physics. 2013 Jun 21;87(24).
- Mebrahtu HT, Borzenets IV, Zheng H, Bomze YV, Smirnov AI, Florens S, et al. Observation of Majorana quantum critical behaviour in a resonant level coupled to a dissipative environment. Nature Physics. 2013;
- Mebrahtu HT, Borzenets IV, Zheng H, Bomze YV, Smirnov AI, Florens S, et al. Observation of majorana quantum critical behaviour in a resonant level coupled to a dissipative environment. Nature Physics. 2013 Jan 1;9(11):732–7.
- Yoon I, Hamaguchi K, Borzenets IV, Finkelstein G, Mooney R, Donald BR. Intracellular Neural Recording with Pure Carbon Nanotube Probes. PLoS One. 2013;8(6):e65715.
- Mebrahtu HT, Borzenets IV, Liu DE, Zheng H, Bomze YV, Smirnov AI, et al. Quantum phase transition in a resonant level coupled to interacting leads. Nature. 2012 Aug;488(7409):61–4.
- Borzenets IV, Yoon I, Prior MW, Donald BR, Mooney RD, Finkelstein G. Erratum: Ultra-sharp metal and nanotube-based probes for applications in scanning microscopy and neural recording (Journal of Applied Physics (2012) 111 (074703)). Journal of Applied Physics. 2012 Jul 15;112(2).
- Borzenets IV, Coskun UC, Mebrahtu H, Finkelstein G. Pb-Graphene-Pb josephson junctions: Characterization in magnetic field. IEEE Transactions on Applied Superconductivity. 2012 Jun 14;22(5).
- Borzenets IV, Yoon I, Prior MM, Donald BR, Mooney RD, Finkelstein G. Ultra-sharp metal and nanotube-based probes for applications in scanning microscopy and neural recording. J Appl Phys. 2012 Apr 1;111(7):74703–747036.
- Mebrahtu H, Borzenets I, Bomze Y, Finkelstein G. Observation of unitary conductance for resonant tunneling with dissipation. In: Journal of Physics: Conference Series. 2012.
- Li P, Wu PM, Bomze Y, Borzenets IV, Finkelstein G, Chang AM. Retrapping current, self-heating, and hysteretic current-voltage characteristics in ultranarrow superconducting aluminum nanowires. Physical Review B - Condensed Matter and Materials Physics. 2011 Nov 8;84(18).
- Borzenets IV, Coskun UC, Jones SJ, Finkelstein G. Phase diffusion in graphene-based Josephson junctions. 2011.
- Borzenets IV, Coskun UC, Jones SJ, Finkelstein G. Phase diffusion in graphene-based Josephson junctions. Physical review letters. 2011 Sep;107(13):137005.
- Li P, Wu PM, Bomze Y, Borzenets IV, Finkelstein G, Chang AM. Switching currents limited by single phase slips in one-dimensional superconducting Al nanowires. Physical review letters. 2011 Sep;107(13):137004.
- Pilo-Pais M, Goldberg S, Samano E, Labean TH, Finkelstein G. Connecting the nanodots: programmable nanofabrication of fused metal shapes on DNA templates. Nano letters. 2011 Aug;11(8):3489–92.
- Samano EC, Pilo-Pais M, Goldberg S, Vogen BN, Finkelstein G, LaBean TH. Self-Assembling DNA Templates for Programmed Artificial Biomineralization. Soft Matter. 2011 Jan;
- Bomze Y, Borzenets I, Mebrahtu H, Makarovski A, Baranger HU, Finkelstein G. Two-stage Kondo effect and Kondo-box level spectroscopy in a carbon nanotube. Physical Review B - Condensed Matter and Materials Physics. 2010 Oct 18;82(16).
- Bomze Y, Mebrahtu H, Borzenets I, Makarovski A, Finkelstein G. Resonant Tunneling in a Dissipative Environment. 2010.
- Bomze Y, Mebrahtu H, Borzenets I, Makarovski A, Finkelstein G. Resonant tunneling in a dissipative environment. Physical Review B - Condensed Matter and Materials Physics. 2009 Jun 22;79(24).
- Zhukov AA, Finkelstein G. Dependence of transport through carbon nanotubes on local coulomb potential. JETP Letters. 2009 Apr 1;89(4):212–5.
- Coskun UC, Mebrahtu H, Huang PB, Huang J, Sebba D, Biasco A, et al. Single-electron transistors made by chemical patterning of silicon dioxide substrates and selective deposition of gold nanoparticles. Applied Physics Letters. 2008 Sep;93(12).
- Makarovski A, Finkelstein G. Su(4) mixed valence regime in carbon nanotube quantum dots. Physica B: Condensed Matter. 2008 Apr 1;403(5–9):1555–7.
- Anders FB, Logan DE, Galpin MR, Finkelstein G. Zero-bias conductance in carbon nanotube quantum dots. Physical review letters. 2008 Feb;100(8):086809.
- Park SH, Finkelstein G, Labean TH. Stepwise Self-Assembly of DNA Tile Lattices Using dsDNA Bridges. Journal of the American Chemical Society. 2008;130(40–41).
- Park SH, Finkelstein G, LaBean TH. Stepwise self-assembly of DNA tile lattices using dsDNA bridges. Journal of the American Chemical Society. 2008 Jan;130(1):40–1.
- Coskun UC, Mebrahtu H, Huang P, Huang J, Biasco A, Makarovski A, et al. Chemical patterning of silicon dioxide substrates for selective deposition of gold nanoparticles and fabrication of single-electron transistors. Applied Physics Letters. 2008;93:123101.
- Anders FB, Logan DE, Galpin MR, Finkelstein G. Zero-bias conductance in carbon nanotube quantum dots. 2007.
- Makarovski A, Zhukov A, Liu J, Finkelstein G. Four-probe measurements of carbon nanotubes with narrow metal contacts. Physical Review B - Condensed Matter and Materials Physics. 2007 Oct 25;76(16).
- Makarovski A, Zhukov A, Liu J, Finkelstein G. Four-Probe Measurements of Carbon Nanotubes with Narrow Metal Contacts. 2007.
- Makarovski A, Zhukov A, Liu J, Finkelstein G. SU(4) and SU(2) Kondo Effects in Carbon Nanotube Quantum Dots. 2007.
- Prior M, Makarovski A, Finkelstein G. Low-temperature conductive tip atomic force microscope for carbon nanotube probing and manipulation. Applied Physics Letters. 2007 Aug 10;91(5).
- Makarovski A, Liu J, Finkelstein G. Evolution of transport regimes in carbon nanotube quantum dots. Physical review letters. 2007 Aug;99(6):066801.
- Makarovski A, Zhukov A, Liu J, Finkelstein G. SU(2) and SU(4) Kondo effects in carbon nanotube quantum dots. Physical Review B - Condensed Matter and Materials Physics. 2007 Jun 25;75(24).
- Makarovski A, Zhukov A, Liu J, Finkelstein G. SU(4) and SU(2) Kondo Effects in Carbon Nanotube Quantum Dots. Physical Review B. 2007;75:R241407.
- Makarovski A, An L, Liu J, Finkelstein G. Persistent orbital degeneracy in carbon nanotubes. Physical Review B - Condensed Matter and Materials Physics. 2006 Nov 6;74(15).
- Makarovski A, Liu J, Finkelstein G. Evolution of SU(4) Transport Regimes in Carbon Nanotube Quantum Dots. 2006.
- Park SH, Prior MW, LaBean TH, Finkelstein G. Optimized fabrication and electrical analysis of silver nanowires templated on DNA molecules. Applied Physics Letters. 2006 Jul 28;89(3).
- Park SH, Prior MW, LaBean TH, Finkelstein G. Silver nanowires templated on DNA molecules. Applied Physics Letters. 2006;89:033901.
- Park SH, Li H, Yan H, Reif JH, Finkelstein G, LaBean TH. Self-assembled 1D DNA nanostructures as templates for silver nanowires. 2nd Conference on Foundations of Nanoscience: Self-Assembled Architectures and Devices, FNANO 2005. 2005 Dec 1;193–6.
- Makarovski A, An L, Liu J, Finkelstein G. Persistent Orbital Degeneracy in Carbon Nanotubes. 2005.
- Park SH, Barish R, Li H, Reif JH, Finkelstein G, Yan H, et al. Three-Helix Bundle DNA Tiles Self-Assemble into 2D Lattice or 1D Templates for Silver Nanowires. Nano Letters. 2005 Mar;5:693.
- Park SH, Yan H, Reif JH, LaBean TH, Finkelstein G. Electronic nanostructures templated on self-assembled DNA scaffolds. Nanotechnology. 2004 Jul;15:S525–7.
- Yan H, Park SH, Finkelstein G, Reif JH, LaBean TH. DNA-Templated Self-Assembly of Protein Arrays and Highly Conductive Nanowires. Science. 2003 Sep;301:1882.
- Tessmer SH, Finkelstein G, Glicofridis PI, Ashoori RC. Modeling subsurface charge accumulation images of a quantum hall liquid. Physical Review B - Condensed Matter and Materials Physics. 2002 Sep 15;66(12):1253081–6.
- Zheng B, Lu C, Gu G, Makarovski A, Finkelstein G, Liu J. Efficient CVD Growth of Single-Walled Carbon Nanotubes on Surfaces Using Carbon Monoxide Precursor. Nano Letters. 2002 Aug 1;2(8):895–8.
- Tessmer SH, Finkelstein G, Glicofridis PI, Ashoori RC. Modeling Subsurface Charge Accumulation Images of a Quantum Hall Liquid. Phys Rev B. 2002 Aug;66:125308.
- Glicofridis PI, Finkelstein G, Ashoori RC, Shayegan M. Determination of the resistance across incompressible strips through imaging of charge motion. Physical Review B - Condensed Matter and Materials Physics. 2002 Mar 15;65(12):1213121–4.
- Glicofridis PI, Finkelstein G, Ashoori RC, Shayegan M. Determination of the Resistance across Incompressible Strips through Imaging of Charge Motion. Phys Rev B. 2002 Mar;65:121312.
- Glicofridis PI, Finkelstein G, Ashoori RC, Shayegan M. Determination of the resistance across incompressible strips through imaging of charge motion. Physical Review B - Condensed Matter and Materials Physics. 2002 Jan 1;65(12):1–4.
- Glicofridis PI, Finkelstein G, Ashoori RC, Shayegan M. Direct observation of the charging of a 2D electron gas through an incompressible strip in the quantum Hall regime. 2001.
- Finkelstein G, Glicofridis PI, Tessmer SH, Ashoori RC, Melloch MR. Imaging of Low Compressibility Strips in the Quantum Hall Liquid. Phys Rev B. 2000 Dec;61:R16323.
- Finkelstein G, Glicofridis PI, Ashoori RC, Shayegan M. Topographic mapping of the quantum hall liquid using a few-electron bubble. Science. 2000 Jul 7;289(5476):90–4.
- Finkelstein G, Glicofridis PI, Tessmer SH, Ashoori RC, Melloch MR. Imaging of low-compressibility strips in the quantum Hall liquid. Physical Review B - Condensed Matter and Materials Physics. 2000;61(24):R16323–6.
- Finkelstein G, Glicofridis PI, Tessmer SH, Ashoori RC, Melloch MR. Imaging the low compressibility strips formed by the Quantum Hall liquid in a smooth potential gradient. Physica E: Low-Dimensional Systems and Nanostructures. 2000 Jan 1;6(1):251–4.
- Finkelstein G, Glicofridis PI, Tessmer SH, Ashoori RC, Melloch MR. Imaging of Low Compressibility Strips in the Quantum Hall Liquid. 1999.
- Glasberg S, Finkelstein G, Shtrikman H, Bar-Joseph I. Comparative study of the negatively and positively charged excitons in gaas quantum wells. Physical Review B - Condensed Matter and Materials Physics. 1999 Jan 1;59(16):R10425–8.
- Ciulin V, Finkelstein G, Haacke S, Ganière JD, Umansky V, Bar-Joseph I, et al. Dynamics of charged excitons in GaAs quantum wells under high magnetic field. Physica B: Condensed Matter. 1998 Dec 2;256–258:466–9.
- Finkelstein G. Gustav Magnus and his house: Commissioned by the Deutsche Physikalische Gesellschaft. Technology And Culture. 1998 Jul;39(3):568–9.
- Finkelstein G, Shtrikman H, Bar-Joseph I. Shake-up processes of a two-dimensional electron gas in GaAs/AlGaAs quantum wells at high magnetic fields. Physica B: Condensed Matter. 1998 Jun 17;249–251:575–9.
- Finkelstein G, Shtrikman H, Bar-Joseph I. Shakeup processes in a two-dimensional electron gas in GaAs/AlGaAs quantum wells at high magnetic fields. Uspekhi Fizicheskikh Nauk. 1998 Jan 1;168(2):121–3.
- Finkelstein G, Umansky V, Bar-Joseph I, Ciulin V, Haacke S, Ganière J, et al. Charged exciton dynamics in GaAs quantum wells. Physical Review B - Condensed Matter and Materials Physics. 1998 Jan 1;58(19):12637–40.
- Finkelstein G, Shtrikman H, Bar-Joseph I. Mechanism of shakeup processes in the photoluminescence of a two-dimensional electron gas at high magnetic fields. Physical Review B - Condensed Matter and Materials Physics. 1997 Jan 1;56(16):10326–31.
- Finkelstein G, Shtrikman H, Bar-Joseph I. Optical spectroscopy of neutral and charged excitons in GaAs/AlGaAs quantum wells in high magnetic fields. Surface Science. 1996 Jul 20;361–362:357–62.
- Finkelstein G, Shtrikman H, Bar-Joseph I. Shakeup processes in the recombination spectra of negatively charged excitons. Physical Review B - Condensed Matter and Materials Physics. 1996 Jan 1;53(19):12593–6.
- Finkelstein G, Shtrikman H, Bar-Joseph I. Negatively and positively charged excitons in quantum wells. Physical Review B - Condensed Matter and Materials Physics. 1996 Jan 1;53(4):R1709–12.
- Finkelstein G, Bar-Joseph I. Charged excitons in GaAs quantum wells. Il Nuovo Cimento D. 1995 Nov 1;17(11–12):1239–45.
- Barjoseph I, Finkelstein G, Barad S, Shtrikman H, Levinson Y. 4-wave-mixing in modulation-doped gaas quantum-wells under strong magnetic-fields. Physica Status Solidi B-basic Research. 1995 Mar;188(1):457–63.
- Bar‐Joseph I, Finkelstein G, Bar‐Ad S, Shtrikman H, Levinson Y. Four‐wave mixing in modulation‐doped GaAs quantum wells under strong magnetic fields. physica status solidi (b). 1995 Jan 1;188(1):457–63.
- Finkelstein G, Shtrikman H, Bar-Joseph I. Optical spectroscopy of a two-dimensional electron gas near the metal-insulator transition. Physical Review Letters. 1995 Jan 1;74(6):976–9.
- Bar-Ad S, Bar-Joseph I, Finkelstein G, Levinson Y. Biexcitons in short-pulse optical experiments in strong magnetic fields in GaAs quantum wells. Physical Review B. 1994 Jan 1;50(24):18375–81.
- Finkelstein G, Bar-Ad S, Carmel O, Bar-Joseph I, Levinson Y. Biexcitonic effects in transient nonlinear optical experiments in quantum wells. Physical Review B. 1993 Jan 1;47(19):12964–7.
- Finkelstein G. Graphene-based Josephson Triode. In.
- Finkelstein G. Inverse AC Josephson Effect in Ballistic Multiterminal Graphene Josephson Junctions. In p. 103–4.
- Finkelstein G. Graphene-based Josephson Triode. In.