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| Publications of Gleb Finkelstein :chronological combined listing:
%% Papers Published
@article{fds207762,
Author = {Henok T. Mebrahtu and Ivan V. Borzenets and Dong E. Liu and Huaixiu
Zheng, Yuriy V. Bomze and Alex I. Smirnov and Harold U. Baranger and Gleb Finkelstein},
Title = {Quantum phase transition in a resonant level coupled to
interacting leads},
Journal = {Nature},
Volume = {488},
Pages = {61},
Year = {2012},
Month = {August},
url = {http://www.nature.com/nature/journal/v488/n7409/full/nature11265.html},
Abstract = {An interacting one-dimensional electron system, the
Luttinger liquid, is distinct from the ``conventional''
Fermi liquids formed by interacting electrons in two and
three dimensions. Some of its most spectacular properties
are revealed in the process of electron tunneling: as a
function of the applied bias or temperature the tunneling
current demonstrates a non-trivial power-law suppression.
Here, we create a system which emulates tunneling in a
Luttinger liquid, by controlling the interaction of the
tunneling electron with its environment. We further replace
a single tunneling barrier with a double-barrier resonant
level structure and investigate resonant tunneling between
Luttinger liquids. For the first time, we observe perfect
transparency of the resonant level embedded in the
interacting environment, while the width of the resonance
tends to zero. We argue that this unique behavior results
from many-body physics of interacting electrons and signals
the presence of a quantum phase transition (QPT). In our
samples many parameters, including the interaction strength,
can be precisely controlled; thus, we have created an
attractive model system for studying quantum critical
phenomena in general. Our work therefore has broadly
reaching implications for understanding QPTs in more complex
systems, such as cold atoms and strongly correlated bulk
materials.},
Doi = {doi:10.1038/nature11265},
Key = {fds207762}
}
@article{fds212272,
Author = {I.V. Borzenets and I. Yoon and M.W. Prior and B.R. Donald and R.D.
Mooney and G. Finkelstein},
Title = {Ultra-sharp metal and nanotube-based probes for applications
in scanning microscopy and neural recording,},
Journal = {Journal of Applied Physics},
Volume = {111},
Number = {074703},
Pages = {074703},
Year = {2012},
ISSN = {0021-8979},
Abstract = {This paper discusses several methods for manufacturing
ultra-sharp probes, with applications geared toward, but not
limited to, scanning microscopy (STM, AFM) and
intra-cellular recordings of neural signals. We present
recipes for making tungsten, platinum/iridium alloy, and
nanotube fibril tips. Electrical isolation methods using
Parylene-C or PMMA are described.},
Key = {fds212272}
}
@article{fds207767,
Author = {I. Borzenets and U.C. Coskun and H. Mebrahtu and G.
Finkelstein},
Title = {Pb-graphene-Pb Josephson junctions: characterization in
magnetic field},
Journal = {IEEE transactions on Applied Superconductivity},
Volume = {22},
Pages = {1800104},
Year = {2012},
ISSN = {1051-8223},
Abstract = {We fabricate superconductor-graphene-superconductor
Josephson junctions with superconducting regions made of
lead (Pb). The critical current through grapehene may be
modulated by external magnetic field; the resulting
Fraunhofer interference pattern shows several periods of
oscillations, indicating that the junction is uniform.
Deviations from the perfect Fraunhofer pattern are observed,
and their cause is explained by a simulation that mimics the
sample design.},
Key = {fds207767}
}
@article{fds199753,
Author = {P. Li and P.M. Wu and Y. Bomze and I.V. Borzenets and G. Finkelstein and A.M. Chang},
Title = {Retrapping current, self-heating, and hysteretic
current-voltage characteristics in ultranarrow
superconducting aluminum nanowires},
Journal = {Physical Review B},
Volume = {84},
Pages = {184508},
Year = {2011},
url = {http://prb.aps.org/abstract/PRB/v84/i18/e184508},
Doi = {10.1103/PhysRevB.84.184508},
Key = {fds199753}
}
@article{fds199679,
Author = {I.V. Borzenets and U.C. Coskun and S.J. Jones and G.
Finkelstein},
Title = {Phase Diffusion in Graphene-Based Josephson
Junctions},
Journal = {Physical Review Letters},
Volume = {107},
Pages = {137005},
Year = {2011},
url = {http://prl.aps.org/abstract/PRL/v107/i13/e137005},
Abstract = {We report on graphene-based Josephson junctions with
contacts made from lead. The high transition temperature of
this superconductor allows us to observe the supercurrent
branch at temperatures up to ~2 K, at which point we can
detect a small, but nonzero, resistance. We attribute this
resistance to the phase diffusion mechanism, which has not
been yet identified in graphene. By measuring the resistance
as a function of temperature and gate voltage, we can
further characterize the nature of the electromagnetic
environment and dissipation in our samples.},
Doi = {10.1103/PhysRevLett.107.137005},
Key = {fds199679}
}
@article{fds199676,
Author = {Mauricio Pilo-Pais and Sarah Goldberg and Enrique C. Samano and Thomas H. LaBean and Gleb Finkelstein},
Title = {Connecting the Nanodots: Programmable Nanofabrication of
Fused Metal Shapes on DNA Templates},
Journal = {Nano Letters},
Volume = {11},
Pages = {3489-3492},
Year = {2011},
url = {http://pubs.acs.org/doi/abs/10.1021/nl202066c},
Abstract = {We present a novel method for producing complex metallic
nanostructures of programmable design. DNA origami
templates, modified to have DNA binding sites with a
uniquely coded sequence, were adsorbed onto silicon dioxide
substrates. Gold nanoparticles functionalized with the cDNA
sequence were then attached. These seed nanoparticles were
later enlarged, and even fused, by electroless deposition of
silver. Using this method, we constructed a variety of
metallic structures, including rings, pairs of bars, and H
shapes.},
Doi = {10.1021/nl202066c},
Key = {fds199676}
}
@article{fds199677,
Author = {Enrique C. Samano and Mauricio Pilo-Pais and Sarah Goldberg and Briana N. Vogen and Gleb Finkelstein and Thomas H.
LaBean},
Title = {Self-assembling DNA templates for programmed artificial
biomineralization},
Journal = {Soft Matter / Highlights},
Volume = {7},
Pages = {3240},
Year = {2011},
url = {http://pubs.rsc.org/en/Content/ArticleLanding/2011/SM/c0sm01318h},
Abstract = {Complex materials with micron-scale dimensions and
nanometre-scale feature resolution created via engineered
DNA self-assembly represent an important new class of soft
matter. These assemblies are increasingly being exploited as
templates for the programmed assembly of functional
inorganic materials that have not conventionally lent
themselves to organization by molecular recognition
processes. The current challenge is to apply these
bioinspired DNA templates toward the fabrication of
composite materials for use in electronics, photonics, and
other fields of technology. This highlight focuses on
methods we consider most useful for integration of DNA
templated structures into functional composite
nanomaterials, particularly, organization of preformed
nanoparticles and metallization procedures.},
Doi = {10.1039/C0SM01318H},
Key = {fds199677}
}
@article{fds199678,
Author = {Peng Li and Phillip M. Wu and Yuriy Bomze and Ivan V. Borzenets and Gleb
Finkelstein and A. M. Chang},
Title = {Single Phase Slip Limited Switching Current in 1-Dimensional
Superconducting Al Nanowires},
Journal = {Physical Review Letters},
Volume = {107},
Pages = {137004},
Year = {2011},
url = {http://prl.aps.org/abstract/PRL/v107/i13/e137004},
Abstract = {An aluminum nanowire switches from superconducting to normal
as the current is increased in an upsweep. The switching
current (Is) averaged over upsweeps approximately follows
the depairing critical current (Ic) but falls below it.
Fluctuations in Is exhibit three distinct regions of
behaviors and are nonmonotonic in temperature: saturation
well below the critical temperature Tc, an increase as
T^{2/3} at intermediate temperatures, and a rapid decrease
close to Tc. Heat dissipation analysis indicates that a
single phase slip is able to trigger switching at low and
intermediate temperatures, whereby the T^{2/3} dependence
arises from the thermal activation of a phase slip, while
saturation at low temperatures provides striking evidence
that the phase slips by macroscopic quantum
tunneling.},
Doi = {10.1103/PhysRevLett.107.137004},
Key = {fds199678}
}
@article{fds183614,
Author = {Yu. Bomze and I. Borzenets and H. Mebrahtu and A. Makarovski and G.
Finkelstein},
Title = {Two-stage Kondo effect and Kondo-box level spectroscopy in a
carbon nanotube},
Journal = {Physical Review B},
Volume = {82},
Pages = {161411R},
Year = {2010},
Abstract = {The concept of the “Kondo box” describes a single spin,
antiferromagnetically coupled to a quantum dot with a finite
level spacing. Here, a Kondo box is formed in a carbon
nanotube interacting with a localized electron. We
investigate the spins of its first few eigenstates and
compare them to a recent theory. In an “open” Kondo-box,
strongly coupled to the leads, we observe a nonmonotonic
temperature dependence of the nanotube conductance, which
results from a competition between the Kondo-box singlet and
the “conventional” Kondo state that couples the nanotube
to the leads.},
Key = {fds183614}
}
@article{fds166297,
Author = {Yu. Bomze and H. Mebrahtu and I. Borzenets and A. Makarovski and G.
Finkelstein},
Title = {Resonant tunneling in a dissipative environment},
Journal = {Physical Review B},
Volume = {79},
Pages = {241402R},
Year = {2009},
url = {http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=PRBMDO000079000024241402000001&idtype=cvips&gifs=yes},
Abstract = {We measure tunneling through a single quantum level in a
carbon nanotube quantum dot connected to resistive metal
leads. For the electrons tunneling to/from the nanotube, the
leads serve as a dissipative environment, which suppresses
the tunneling rate. In the regime of sequential tunneling,
the height of the singleelectron conductance peaks increases
as the temperature is lowered, although it scales more
weakly than the conventional 1/T. In the resonant tunneling
regime (temperature smaller than the level width), the peak
width approaches saturation, while the peak height starts to
decrease. Overall, the peak height shows a nonmonotonic
temperature dependence. We associate this unusual behavior
with the transition from the sequential to the resonant
tunneling through a single quantum level in a dissipative
environment.},
Key = {fds166297}
}
@article{fds152703,
Author = {S.H. Park and G. Finkelstein and T.H. Labean},
Title = {Stepwise Self-Assembly of DNA Tile Lattices Using dsDNA
Bridges},
Journal = {Journal of the American Chemical Society},
Volume = {130},
Number = {40-41},
Year = {2008},
Key = {fds152703}
}
@article{fds152704,
Author = {U.C. Coskun and H. Mebrahtu and P. Huang and J. Huang and A. Biasco and A.
Makarovski, A. Lazarides and T. LaBean and G.
Finkelstein},
Title = {Chemical patterning of silicon dioxide substrates for
selective deposition of gold nanoparticles and fabrication
of single-electron transistors},
Journal = {Applied Physics Letters},
Volume = {93},
Pages = {123101},
Year = {2008},
Key = {fds152704}
}
@article{fds152705,
Author = {F.B. Anders and D.E. Logan and M.R. Galpin and G.
Finkelstein},
Title = {Zero-Bias Conductance in Carbon Nanotube Quantum
Dots},
Journal = {Physical Review Letters},
Volume = {100},
Pages = {086809},
Year = {2008},
Key = {fds152705}
}
@article{fds140192,
Author = {A. Makarovski and G. Finkelstein},
Title = {Su(4) mixed valence regime in carbon nanotube quantum
dots},
Journal = {Physica B},
Volume = {403},
Pages = {1555},
Year = {2008},
Key = {fds140192}
}
@article{fds140189,
Author = {A. Makarovski and A. Zhukov and J. Liu and G.
Finkelstein},
Title = {SU(4) and SU(2) Kondo Effects in Carbon Nanotube Quantum
Dots},
Journal = {Physical Review B},
Volume = {75},
Pages = {R241407},
Year = {2007},
Key = {fds140189}
}
@article{fds140190,
Author = {A. Makarovski and J. Liu and G. Finkelstein},
Title = {Evolution of Transport Regimes in Carbon Nanotube Quantum
Dots},
Journal = {Physical Review Letters},
Volume = {99},
Pages = {066801},
Year = {2007},
Key = {fds140190}
}
@article{fds140191,
Author = {A. Makarovski and A. Zhukov and J. Liu and G.
Finkelstein},
Title = {Four-Probe Measurements of Carbon Nanotubes with Narrow
Metal Contacts},
Journal = {Physical Review B},
Volume = {76},
Pages = {R161405},
Year = {2007},
Key = {fds140191}
}
@article{fds139642,
Author = {M. Prior and A. Makarovski and G. Finkelstein},
Title = {Low-temperature conductive tip atomic force microscope for
carbon nanotube probing and manipulation},
Journal = {Applied Physics Letters},
Volume = {91},
Pages = {053112},
Year = {2007},
Key = {fds139642}
}
@article{fds43821,
Author = {A. Makarovski and L. An and J. Liu and G. Finkelstein},
Title = {Persistent Orbitals Degeneracy in Carbon
Nanotubes},
Journal = {Physical Review B},
Volume = {74},
Pages = {155431},
Year = {2006},
Abstract = {In the Coulomb blockade regime, we find the
quantum-mechanical orbitals in carbon nanotubes to be doubly
degenerate over a large number of states. The experimental
observation of the orbital degeneracy indicates adiabatic
reflection at the nanotube-metal contacts and high quality
of the nanotube material. A pair of electrons occupying the
degenerate orbitals is found to form a triplet state even at
zero magnetic field. Finally, we observe unexpected
low-energy excitations at complete filling of a
four-electron shell.},
Key = {fds43821}
}
@article{fds43823,
Author = {S.H. Park and M.W. Prior and T.H. LaBean and G.
Finkelstein},
Title = {Silver nanowires templated on DNA molecules},
Journal = {Applied Physics Letters},
Volume = {89},
Pages = {033901},
Year = {2006},
Abstract = {We report on the electrical conductivity measurement of
silver nanowires templated on native λ-bacteriophage
and synthetic double- stranded DNA molecules. After an
electroless chemical deposition, the metallized DNA wires
have a diameter down to 15 nm, which are among the thinnest
metallic nanowires available to date. Two-terminal I-V
measurements demonstrating various conduction behaviors are
presented. DNA-templated functionalized nanowires represent
a potential breakthrough in the self-assembly of
nanometer-scale structures for electronics-layout because
they can be targeted to connect at specific locations on
larger-scale circuits.},
Key = {fds43823}
}
@article{fds43820,
Author = {S.H. Park and R. Barish and H. Li and J.H. Reif and G. Finkelstein and H.
Yan and T.H. LaBean},
Title = {Three-Helix Bundle DNA Tiles Self-Assemble into 2D Lattice
or 1D Templates for Silver Nanowires.},
Journal = {Nano Letters},
Volume = {5},
Pages = {693},
Year = {2005},
Month = {March},
Abstract = {We present a DNA nanostructure, the three- helix bundle
(3HB), which consists of three double helical DNA domains
connected by six immobile crossover junctions such that the
helix axes are not coplanar. The 3HB motif presents a
triangular cross-section with one helix lying in the groove
formed by the other two. By differential programming of
sticky- ends, 3HB tiles can be arrayed in two distinct
lattice conformations: one-dimensional filaments and
two-dimensional lattices. Filaments and lattices have been
visualized by high-resolution, tapping mode atomic force
microscopy (AFM) under buffer. Their dimensions are shown to
be in excellent agreement with designed structures. We also
demonstrate an electroless chemical deposition for
fabricating metallic nanowires templated on self-assembled
filaments. The metallized nanowires have diameters down to
20 nm and display Ohmic current-voltage characteristic.},
Key = {fds43820}
}
@article{fds30137,
Author = {S.H. Park and H. Yan and J.H. Reif and T.H. LaBean and G.
Finkelstein},
Title = {Electronic nanostructures templated on self-assembled DNA
scaffolds},
Journal = {Nanotechnology},
Volume = {15},
Pages = {S525-S527},
Year = {2004},
Month = {July},
url = {http://www.phy.duke.edu/~gleb/Pdf_FILES/nanotech.pdf},
Abstract = {We report on the self-assembly of one- and two-dimensional
DNA scaffolds, which serve as templates for the targeted
deposition of ordered nanoparticles and molecular arrays.
TheDNAnanostructures are easy to reprogram, and we
demonstrate two distinct conformations: sheets and tubes.
The DNA tubes and individual DNA molecules are metallized in
solution to produce ultra-thin metal wires.},
Key = {fds30137}
}
@article{fds17223,
Author = {Hao Yan and Sung Ha Park and Gleb Finkelstein and John H. Reif and Thomas H. LaBean},
Title = {DNA-Templated Self-Assembly of Protein Arrays and Highly
Conductive Nanowires},
Journal = {Science},
Volume = {301},
Pages = {1882},
Year = {2003},
Month = {September},
Key = {fds17223}
}
@article{fds3772,
Author = {B. Zheng and C. Lu and A. Makarovski and G. Finkelstein and J.
Liu},
Title = {Efficient CVD Growth of Single-Walled Carbon Nanotubes on
Surface Using Carbon Monoxide Precursor},
Journal = {Nano Letters},
Volume = {2},
Number = {8},
Pages = {895},
Year = {2002},
Month = {August},
Key = {fds3772}
}
@article{fds3774,
Author = {S.H. Tessmer and G. Finkelstein and P.I. Glicofridis and R.C.
Ashoori},
Title = {Modeling Subsurface Charge Accumulation Images of a Quantum
Hall Liquid},
Journal = {Phys. Rev. B},
Volume = {66},
Pages = {125308},
Year = {2002},
Month = {August},
Key = {fds3774}
}
@article{fds3773,
Author = {P.I. Glicofridis and G. Finkelstein and R.C. Ashoori and M.
Shayegan},
Title = {Determination of the Resistance across Incompressible Strips
through Imaging of Charge Motion},
Journal = {Phys. Rev. B},
Volume = {65},
Pages = {121312},
Year = {2002},
Month = {March},
Key = {fds3773}
}
@article{fds4085,
Author = {G. Finkelstein and P.I. Glicofridis and R.C. Ashoori and M.
Shayegan},
Title = {Topographic Mapping of the Quantum Hall Liquid Using a Few
Electron Bubble},
Journal = {Science},
Volume = {289},
Pages = {90},
Year = {2000},
Month = {December},
Key = {fds4085}
}
@article{fds4086,
Author = {G. Finkelstein and P.I. Glicofridis and S.H. Tessmer and R.C. Ashoori and M. R. Melloch},
Title = {Imaging of Low Compressibility Strips in the Quantum Hall
Liquid},
Journal = {Phys. Rev. B},
Volume = {61},
Pages = {R16 323},
Year = {2000},
Month = {December},
Key = {fds4086}
}
@article{fds4084,
Author = {G. Finkelstein and P.I. Glicofridis and S.H. Tessmer and R.C. Ashoori and M.R. Melloch},
Title = {Imaging the Low Compressibility Strips Formed by the Quantum
Hall Liquid in a Smooth Potential Gradient},
Journal = {Physica E},
Volume = {6},
Pages = {251},
Year = {2000},
Month = {November},
Key = {fds4084}
}
@article{fds4087,
Author = {S. Glasberg and G. Finkelstein and H. Shtrikman and I.
Bar-Joseph},
Title = {Comparative Study of the Negatively and Positively Charged
Excitons in GaAs Quantum Wells},
Journal = {Phys. Rev. B},
Volume = {59},
Pages = {R10425},
Year = {1999},
Month = {December},
Key = {fds4087}
}
@booklet{Finkelstein98,
Author = {G. Finkelstein and V. Umansky and I. Bar-joseph and V. Ciulin and S.
Haacke, J.D. Ganiere and B. Deveaud},
Title = {Charged exciton dynamics in GaAs quantum
wells},
Journal = {Phys. Rev. B},
Volume = {58},
Number = {19},
Pages = {12637 -- 12640},
Year = {1998},
Month = {November},
Key = {Finkelstein98}
}
@booklet{Finkelstein98a,
Author = {G. Finkelstein},
Title = {Gustav Magnus and his house: Commissioned by the Deutsche
Physikalische Gesellschaft},
Journal = {Technology And Culture},
Volume = {39},
Number = {3},
Pages = {568 -- 569},
Year = {1998},
Month = {July},
Key = {Finkelstein98a}
}
@booklet{Finkelstein98b,
Author = {G. Finkelstein and H. Shtrikman and I. Bar-joseph},
Title = {Shake-up processes of a two-dimensional electron gas in
GaAs/AlGaAs quantum wells at high magnetic
fields},
Journal = {Physica B},
Volume = {251},
Pages = {575 -- 579},
Year = {1998},
Month = {June},
Key = {Finkelstein98b}
}
@booklet{Finkelstein98c,
Author = {G. Finkelstein and H. Shtrikman and I. Bar-joseph},
Title = {Shakeup processes in a two-dimensional electron gas in
GaAs/AlGaAs quantum wells at high magnetic
fields},
Journal = {Uspekhi Fizicheskikh Nauk},
Volume = {168},
Number = {2},
Pages = {121 -- 123},
Year = {1998},
Month = {February},
Key = {Finkelstein98c}
}
@booklet{Finkelstein97,
Author = {G. Finkelstein and H. Shtrikman and I. Barjoseph},
Title = {Mechanism of shakeup processes in the photoluminescence of a
two-dimensional electron gas at high magnetic
fields},
Journal = {Phys. Rev. B},
Volume = {56},
Number = {16},
Pages = {10326 -- 10331},
Year = {1997},
Month = {October},
Key = {Finkelstein97}
}
@booklet{Barjoseph97,
Author = {I. Barjoseph and G. Finkelstein},
Title = {Trions in GaAs quantum wells},
Journal = {Compound Semiconductors 1996},
Series = {INSTITUTE OF PHYSICS CONFERENCE SERIES},
Number = {155},
Pages = {711 -- 716},
Year = {1997},
Key = {Barjoseph97}
}
@booklet{Finkelstein96a,
Author = {G. Finkelstein and H. Shtrikman and I. Barjoseph},
Title = {Shakeup processes in the recombination spectra of negatively
charged excitons},
Journal = {Phys. Rev. B},
Volume = {53},
Number = {19},
Pages = {12593 -- 12596},
Year = {1996},
Month = {May},
Key = {Finkelstein96a}
}
@booklet{Finkelstein96b,
Author = {G. Finkelstein and H. Shtrikman and I. Barjoseph},
Title = {Negatively and positively charged excitons in
GaAs/AlxGa1-xAs quantum wells},
Journal = {Phys. Rev. B},
Volume = {53},
Number = {4},
Pages = {R1709 -- R1712},
Year = {1996},
Month = {January},
Key = {Finkelstein96b}
}
@booklet{Finkelstein96,
Author = {G. Finkelstein and H. Shtrikman and I. Barjoseph},
Title = {Optical spectroscopy of neutral and charged excitons in
GaAs/AlGaAs quantum wells in high magnetic
fields},
Journal = {Surface Science},
Volume = {362},
Number = {1-3},
Pages = {357 -- 362},
Year = {1996},
Key = {Finkelstein96}
}
@booklet{Barjoseph95,
Author = {I. Barjoseph and G. Finkelstein and S. Barad and H. Shtrikman and Y.
Levinson},
Title = {4-wave-mixing in modulation-doped gaas quantum-wells under
strong magnetic-fields},
Journal = {Physica Status Solidi B-basic Research},
Volume = {188},
Number = {1},
Pages = {457 -- 463},
Year = {1995},
Month = {March},
Key = {Barjoseph95}
}
@booklet{Finkelstein95a,
Author = {G. Finkelstein and H. Shtrikman and I. Barjoseph},
Title = {Optical spectroscopy of a 2-dimensional electron-gas near
the metal-insulator-transition},
Journal = {Phys. Rev. Lett.},
Volume = {74},
Number = {6},
Pages = {976 -- 979},
Year = {1995},
Month = {February},
Key = {Finkelstein95a}
}
@booklet{Finkelstein95,
Author = {G. Finkelstein and I. Barjoseph},
Title = {Charged excitons in GaAs quantum wells.},
Journal = {Nuovo Cimento Della Societa Italiana Di Fisica D-condensed
Matter Atomic Molecular And Chemical Physics Fluids Plasmas
Biophysics},
Volume = {17},
Number = {11-12},
Pages = {1239 -- 1245},
Year = {1995},
Key = {Finkelstein95}
}
@booklet{Barad94,
Author = {S. Barad and I. Barjoseph and G. Finkelstein and Y.
Levinson},
Title = {Biexcitons in short-pulse optical experiments in strong
magnetic-fields in gaas quantum-wells},
Journal = {Phys. Rev. B},
Volume = {50},
Number = {24},
Pages = {18375 -- 18381},
Year = {1994},
Month = {December},
Key = {Barad94}
}
@booklet{Finkelstein93,
Author = {G. Finkelstein and S. Barad and O. Carmel and I. Barjoseph and Y.
Levinson},
Title = {Biexcitonic effects in transient nonlinear-optical
experiments in quantum-wells},
Journal = {Phys. Rev. B},
Volume = {47},
Number = {19},
Pages = {12964 -- 12967},
Year = {1993},
Month = {May},
Key = {Finkelstein93}
}
@booklet{Pieprzyk88,
Author = {J. Pieprzyk and G. Finkelstein},
Title = {Towards effective nonlinear cryptosystem
design},
Journal = {Iee Proceedings-e Computers And Digital Techniques},
Volume = {135},
Number = {6},
Pages = {325 -- 335},
Year = {1988},
Month = {November},
Key = {Pieprzyk88}
}
%% Papers Submitted
@article{fds212274,
Author = {Inho Yoon and Kosuke Hamaguchi and Ivan V. Borzenets and Gleb
Finkelstein, Richard Mooney and Bruce R.
Donald},
Title = {Intracellular neural recording with pure carbon nanotube
probes},
Journal = {Nature Nanotechnology},
Year = {2012},
Abstract = {The computational complexity of the brain depends in part on
a neuron’s capacity to integrate electrochemical
information from vast numbers of synaptic inputs. The
measurements of synaptic activity that are crucial for
mechanistic understanding of brain function are also
challenging because they require intracellular recording
methods to detect and resolve millivolt scale synaptic
potentials. Although glass electrodes are widely used for
intracellular recordings, novel electrodes with superior
mechanical and electrical properties are desirable because
they could extend intracellular recording methods to
challenging environments, including long term recordings in
freely behaving animals. Carbon nanotubes (CNTs) can
theoretically deliver this advance, but previous attempts
have been limited to surface coating over a flat substrate
or wires1,2, limiting their application to monolayer
neuronal cultures. Here we show that a novel yet remarkably
simple millimeter long electrode with a sub-micron tip,
fabricated from self-entangled pure CNT can be used to
obtain intracellular and extracellular recordings from
vertebrate neurons in vitro and in vivo. This fabrication
technology provides a new method for assembling
intracellular electrodes from CNTs, affording a promising
opportunity to harness nanotechnology for neuroscience
applications.},
Key = {fds212274}
}
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