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1. Strongly coupled edge states in a graphene quantum Hall interferometer.

Author

Werkmeister, Thomas, Ehrets, James R., Ronen, Yuval, Wesson, Marie E., Najafabadi, Danial, Wei, Zezhu, Watanabe, Kenji, Taniguchi, Takashi, Feldman, D. E., Halperin, Bertrand I., Yacoby, Amir, and Kim, Philip

Subjects
QUANTUM Hall effect, SECOND harmonic generation, ELECTRON density, ELECTRON pairs, INTERFEROMETERS, MICHELSON interferometer
Abstract

Electronic interferometers using the chiral, one-dimensional (1D) edge channels of the quantum Hall effect (QHE) can demonstrate a wealth of fundamental phenomena. The recent observation of phase jumps in a Fabry-Pérot (FP) interferometer revealed anyonic quasiparticle exchange statistics in the fractional QHE. When multiple integer edge channels are involved, FP interferometers have exhibited anomalous Aharonov-Bohm (AB) interference frequency doubling, suggesting putative pairing of electrons into 2 e quasiparticles. Here, we use a highly tunable graphene-based QHE FP interferometer to observe the connection between interference phase jumps and AB frequency doubling, unveiling how strong repulsive interaction between edge channels leads to the apparent pairing phenomena. By tuning electron density in-situ from filling factor ν < 2 to ν > 7 , we tune the interaction strength and observe periodic interference phase jumps leading to AB frequency doubling. Our observations demonstrate that the combination of repulsive interaction between the spin-split ν = 2 edge channels and charge quantization is sufficient to explain the frequency doubling, through a near-perfect charge screening between the localized and extended edge channels. Our results show that interferometers are sensitive probes of microscopic interactions and enable future experiments studying correlated electrons in 1D channels using density-tunable graphene. Previous measurements of interferometers based on quantum Hall (QH) edge channels have suggested potential electron pairing effects. Here, the authors investigate the coupling between QH edge channels in graphene Aharonov-Bohm (AB) interferometers, proposing a possible single-particle explanation for the apparent interference phase jumps and AB frequency doubling. [ABSTRACT FROM AUTHOR]

Published
2024
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3. A two-site Kitaev chain in a two-dimensional electron gas.

Author

ten Haaf, Sebastiaan L. D., Wang, Qingzhen, Bozkurt, A. Mert, Liu, Chun-Xiao, Kulesh, Ivan, Kim, Philip, Xiao, Di, Thomas, Candice, Manfra, Michael J., Dvir, Tom, Wimmer, Michael, and Goswami, Srijit

Abstract

Artificial Kitaev chains can be used to engineer Majorana bound states (MBSs) in superconductor–semiconductor hybrids1–4. In this work, we realize a two-site Kitaev chain in a two-dimensional electron gas by coupling two quantum dots through a region proximitized by a superconductor. We demonstrate systematic control over inter-dot couplings through in-plane rotations of the magnetic field and via electrostatic gating of the proximitized region. This allows us to tune the system to sweet spots in parameter space, where robust correlated zero-bias conductance peaks are observed in tunnelling spectroscopy. To study the extent of hybridization between localized MBSs, we probe the evolution of the energy spectrum with magnetic field and estimate the Majorana polarization, an important metric for Majorana-based qubits5,6. The implementation of a Kitaev chain on a scalable and flexible two-dimensional platform provides a realistic path towards more advanced experiments that require manipulation and readout of multiple MBSs.We have implemented a two-site Kitaev chain in a two-dimensional electron gas by coupling quantum dots through Andreev bound states in a superconductor–semiconductor hybrid region. [ABSTRACT FROM AUTHOR]

Published
2024
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4. Advance Care Planning (ACP) als Element eines klinisch-ethischen Unterstützungsangebotes – Darstellung und Evaluation.

Author

Nowak, Andre, Linoh, Kim Philip, Flöther, Lilit, Schildmann, Jan, and Nadolny, Stephan

Abstract

Copyright of Ethik in der Medizin is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2023
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5. Relaxation and Domain Wall Structure of Bilayer Moiré Systems.

Author

Cazeaux, Paul, Clark, Drake, Engelke, Rebecca, Kim, Philip, and Luskin, Mitchell

Subjects
UNIT cell, HETEROSTRUCTURES
Abstract

Moiré patterns result from setting a 2D material such as graphene on another 2D material with a small twist angle or from the lattice mismatch of 2D heterostructures. We present a continuum model for the elastic energy of these bilayer moiré structures that includes an intralayer elastic energy and an interlayer misfit energy that is minimized at two stackings (disregistries). We show by theory and computation that the displacement field that minimizes the global elastic energy subject to a global boundary constraint gives large alternating regions of one of the two energy-minimizing stackings separated by domain walls. We derive a model for the domain wall structure from the continuum bilayer energy and give a rigorous asymptotic estimate for the structure. We also give an improved estimate for the L 2 -norm of the gradient on the moiré unit cell for twisted bilayers that scales at most inversely linearly with the twist angle, a result which is consistent with the formation of one-dimensional domain walls with a fixed width around triangular domains at very small twist angles. [ABSTRACT FROM AUTHOR]

Published
2023
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6. A universal deep-learning model for zinc finger design enables transcription factor reprogramming.

Author

Ichikawa, David M., Abdin, Osama, Alerasool, Nader, Kogenaru, Manjunatha, Mueller, April L., Wen, Han, Giganti, David O., Goldberg, Gregory W., Adams, Samantha, Spencer, Jeffrey M., Razavi, Rozita, Nim, Satra, Zheng, Hong, Gionco, Courtney, Clark, Finnegan T., Strokach, Alexey, Hughes, Timothy R., Lionnet, Timothee, Taipale, Mikko, and Kim, Philip M.

Abstract

Cys2His2 zinc finger (ZF) domains engineered to bind specific target sequences in the genome provide an effective strategy for programmable regulation of gene expression, with many potential therapeutic applications. However, the structurally intricate engagement of ZF domains with DNA has made their design challenging. Here we describe the screening of 49 billion protein–DNA interactions and the development of a deep-learning model, ZFDesign, that solves ZF design for any genomic target. ZFDesign is a modern machine learning method that models global and target-specific differences induced by a range of library environments and specifically takes into account compatibility of neighboring fingers using a novel hierarchical transformer architecture. We demonstrate the versatility of designed ZFs as nucleases as well as activators and repressors by seamless reprogramming of human transcription factors. These factors could be used to upregulate an allele of haploinsufficiency, downregulate a gain-of-function mutation or test the consequence of regulation of a single gene as opposed to the many genes that a transcription factor would normally influence. Zinc finger design is facilitated with a deep-learning model. [ABSTRACT FROM AUTHOR]

Published
2023
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8. Disrupting the α-synuclein-ESCRT interaction with a peptide inhibitor mitigates neurodegeneration in preclinical models of Parkinson's disease.

Author

Nim, Satra, O'Hara, Darren M., Corbi-Verge, Carles, Perez-Riba, Albert, Fujisawa, Kazuko, Kapadia, Minesh, Chau, Hien, Albanese, Federica, Pawar, Grishma, De Snoo, Mitchell L., Ngana, Sophie G., Kim, Jisun, El-Agnaf, Omar M. A., Rennella, Enrico, Kay, Lewis E., Kalia, Suneil K., Kalia, Lorraine V., and Kim, Philip M.

Subjects
PEPTIDES, PARKINSON'S disease, DOPAMINERGIC neurons, ANIMAL models in research, ALPHA-synuclein, PROTEIN-protein interactions, NEURODEGENERATION
Abstract

Accumulation of α-synuclein into toxic oligomers or fibrils is implicated in dopaminergic neurodegeneration in Parkinson's disease. Here we performed a high-throughput, proteome-wide peptide screen to identify protein-protein interaction inhibitors that reduce α-synuclein oligomer levels and their associated cytotoxicity. We find that the most potent peptide inhibitor disrupts the direct interaction between the C-terminal region of α-synuclein and CHarged Multivesicular body Protein 2B (CHMP2B), a component of the Endosomal Sorting Complex Required for Transport-III (ESCRT-III). We show that α-synuclein impedes endolysosomal activity via this interaction, thereby inhibiting its own degradation. Conversely, the peptide inhibitor restores endolysosomal function and thereby decreases α-synuclein levels in multiple models, including female and male human cells harboring disease-causing α-synuclein mutations. Furthermore, the peptide inhibitor protects dopaminergic neurons from α-synuclein-mediated degeneration in hermaphroditic C. elegans and preclinical Parkinson's disease models using female rats. Thus, the α-synuclein-CHMP2B interaction is a potential therapeutic target for neurodegenerative disorders. ESCRT-III is involved in the endolysosomal system and disturbed in neurodegenerative diseases. Here the authors show that disruption of an interaction between ESCRT-III member CHMP2B and α-synuclein by a peptide inhibitor mitigates neurodegeneration in Parkinson's disease models. [ABSTRACT FROM AUTHOR]

Published
2023
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9. Torsional periodic lattice distortions and diffraction of twisted 2D materials.

Author

Sung, Suk Hyun, Goh, Yin Min, Yoo, Hyobin, Engelke, Rebecca, Xie, Hongchao, Zhang, Kuan, Li, Zidong, Ye, Andrew, Deotare, Parag B., Tadmor, Ellad B., Mannix, Andrew J., Park, Jiwoong, Zhao, Liuyan, Kim, Philip, and Hovden, Robert

Subjects
ELECTRON diffraction, GRAPHENE, TORSIONAL load
Abstract

Twisted 2D materials form complex moiré structures that spontaneously reduce symmetry through picoscale deformation within a mesoscale lattice. We show twisted 2D materials contain a torsional displacement field comprised of three transverse periodic lattice distortions (PLD). The torsional PLD amplitude provides a single order parameter that concisely describes the structural complexity of twisted bilayer moirés. Moreover, the structure and amplitude of a torsional periodic lattice distortion is quantifiable using rudimentary electron diffraction methods sensitive to reciprocal space. In twisted bilayer graphene, the torsional PLD begins to form at angles below 3.89° and the amplitude reaches 8 pm around the magic angle of 1. 1°. At extremely low twist angles (e.g. below 0.25°) the amplitude increases and additional PLD harmonics arise to expand Bernal stacked domains separated by well defined solitonic boundaries. The torsional distortion field in twisted bilayer graphene is analytically described and has an upper bound of 22.6 pm. Similar torsional distortions are observed in twisted WS2, CrI3, and WSe2/MoSe2. In twisted 2D materials, spontaneous lattice reconstructions mean that twist angle alone provides an incomplete description. Here, using electron diffraction, the authors show that the displacement field in twisted bilayer graphene can be described as a superposition of three periodic lattice distortion (PLD) waves with wavevectors oriented at 120° from each other, forming a "torsional" PLD. [ABSTRACT FROM AUTHOR]

Published
2022
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10. Beam steering at the nanosecond time scale with an atomically thin reflector.

Author

Andersen, Trond I., Gelly, Ryan J., Scuri, Giovanni, Dwyer, Bo L., Wild, Dominik S., Bekenstein, Rivka, Sushko, Andrey, Sung, Jiho, Zhou, You, Zibrov, Alexander A., Liu, Xiaoling, Joe, Andrew Y., Watanabe, Kenji, Taniguchi, Takashi, Yelin, Susanne F., Kim, Philip, Park, Hongkun, and Lukin, Mikhail D.

Subjects
BEAM steering, OPTICAL devices, EXCITON theory, SEMICONDUCTORS
Abstract

Techniques to mold the flow of light on subwavelength scales enable fundamentally new optical systems and device applications. The realization of programmable, active optical systems with fast, tunable components is among the outstanding challenges in the field. Here, we experimentally demonstrate a few-pixel beam steering device based on electrostatic gate control of excitons in an atomically thin semiconductor with strong light-matter interactions. By combining the high reflectivity of a MoSe2 monolayer with a graphene split-gate geometry, we shape the wavefront phase profile to achieve continuously tunable beam deflection with a range of 10°, two-dimensional beam steering, and switching times down to 1.6 nanoseconds. Our approach opens the door for a new class of atomically thin optical systems, such as rapidly switchable beam arrays and quantum metasurfaces operating at their fundamental thickness limit. Andersen et al. have demonstrated a new type of beam steering device based on the excitonic response of an atomically thin semiconductor. Using electrostatic gates, the authors achieved tunable steering with switching times on the nanosecond scale. [ABSTRACT FROM AUTHOR]

Published
2022
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11. Evidence for 4e charge of Cooper quartets in a biased multi-terminal graphene-based Josephson junction.

Author

Huang, Ko-Fan, Ronen, Yuval, Mélin, Régis, Feinberg, Denis, Watanabe, Kenji, Taniguchi, Takashi, and Kim, Philip

Subjects
JOSEPHSON junctions, COOPER pair, DEPENDENCY (Psychology), MAGNETIC flux, SUPERCONDUCTING quantum interference devices, CRITICAL currents
Abstract

In a Josephson junction (JJ) at zero bias, Cooper pairs are transported between two superconducting contacts via the Andreev bound states (ABSs) formed in the Josephson channel. Extending JJs to multiple superconducting contacts, the ABSs in the Josephson channel can coherently hybridize Cooper pairs among different superconducting electrodes. Biasing three-terminal JJs with antisymmetric voltages, for example, results in a direct current (DC) of Cooper quartet (CQ), which involves a four-fermion entanglement. Here, we report half a flux periodicity in the interference of CQ formed in graphene based multi-terminal (MT) JJs with a magnetic flux loop. We observe that the quartet differential conductance associated with supercurrent exhibits magneto-oscillations associated with a charge of 4e, thereby presenting evidence for interference between different CQ processes. The CQ critical current shows non-monotonic bias dependent behavior, which can be modeled by transitions between Floquet-ABSs. Our experimental observation for voltage-tunable non-equilibrium CQ-ABS in flux-loop-JJs significantly extends our understanding of MT-JJs, enabling future design of topologically unique ABS spectrum. Here, the authors perform measurements of the interference effects of Cooper Quartets (CQ), observed in a multi-terminal graphene Josephson junction where two terminals are tied by a flux loop. By biasing the superconducting contacts, they identify a superconducting branch attributed to CQ currents, and present evidence for interference between different CQ processes. [ABSTRACT FROM AUTHOR]

Published
2022
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12. PepNN: a deep attention model for the identification of peptide binding sites.

Author

Abdin, Osama, Nim, Satra, Wen, Han, and Kim, Philip M.

Subjects
PEPTIDES, BINDING sites, CARRIER proteins, PROTEIN binding, DEEP learning
Abstract

Protein-peptide interactions play a fundamental role in many cellular processes, but remain underexplored experimentally and difficult to model computationally. Here, we present PepNN-Struct and PepNN-Seq, structure and sequence-based approaches for the prediction of peptide binding sites on a protein. A main difficulty for the prediction of peptide-protein interactions is the flexibility of peptides and their tendency to undergo conformational changes upon binding. Motivated by this, we developed reciprocal attention to simultaneously update the encodings of peptide and protein residues while enforcing symmetry, allowing for information flow between the two inputs. PepNN integrates this module with modern graph neural network layers and a series of transfer learning steps are used during training to compensate for the scarcity of peptide-protein complex information. We show that PepNN-Struct achieves consistently high performance across different benchmark datasets. We also show that PepNN makes reasonable peptide-agnostic predictions, allowing for the identification of novel peptide binding proteins. PepNN integrates an attention-based deep learning module with transfer learning to predict the peptide binding sites of input proteins and the binding ability of proteins lacking a known peptide ligand. [ABSTRACT FROM AUTHOR]

Published
2022
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13. Temperature-Mediated Nerve Blocks in the Treatment of Pain.

Author

Fishman, Michael A., Scherer, Ashley M., Katsarakes, Ashley M., Larson, Lexi, and Kim, Philip S.

Abstract

Purpose Of Review: Analgesic hot and cold temperatures have been used for both conservative and ablative therapies for millennia. There are well-known locoregional neurovascular changes associated with the application of heat or ice in the literature and in practice. The oscillation between heat and cold has recently been identified as a synergistic mechanism of action with early translational results in humans.Recent Findings: Recent mechanistic work in the feline model has demonstrated that a reliable, reversible nerve block can be achieved within a temperature range that is non-destructive (15-45°C). The underlying mechanism is a newly described hysteresis in the responsiveness of peripheral nerves to alternating thermal stimuli resulting in nerve blockade. Recently presented feasibility data reports positive results in subjects with occipital pain and peripheral scar pain in terms of pain and associated symptom improvement. Temperature-mediated changes in pain and sensation have been observed for hot and cold applications at a variety of temperatures. Recent insights into the synergy between preheating followed by cooling resulting in peripheral nerve fiber block has potential in a variety of conditions in which peripheral nerve etiology is noted. Recent findings in chronic headache patients report decreased pain and symptom improvement. Further studies are ongoing to understand the indications for this novel therapy. [ABSTRACT FROM AUTHOR]

Published
2021
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14. Bilayer Wigner crystals in a transition metal dichalcogenide heterostructure.

Author

Zhou, You, Sung, Jiho, Brutschea, Elise, Esterlis, Ilya, Wang, Yao, Scuri, Giovanni, Gelly, Ryan J., Heo, Hoseok, Taniguchi, Takashi, Watanabe, Kenji, Zaránd, Gergely, Lukin, Mikhail D., Kim, Philip, Demler, Eugene, and Park, Hongkun

Abstract

One of the first theoretically predicted manifestations of strong interactions in many-electron systems was the Wigner crystal1–3, in which electrons crystallize into a regular lattice. The crystal can melt via either thermal or quantum fluctuations4. Quantum melting of the Wigner crystal is predicted to produce exotic intermediate phases5,6 and quantum magnetism7,8 because of the intricate interplay of Coulomb interactions and kinetic energy. However, studying two-dimensional Wigner crystals in the quantum regime has often required a strong magnetic field9–11 or a moiré superlattice potential12–15, thus limiting access to the full phase diagram of the interacting electron liquid. Here we report the observation of bilayer Wigner crystals without magnetic fields or moiré potentials in an atomically thin transition metal dichalcogenide heterostructure, which consists of two MoSe2 monolayers separated by hexagonal boron nitride. We observe optical signatures of robust correlated insulating states at symmetric (1:1) and asymmetric (3:1, 4:1 and 7:1) electron doping of the two MoSe2 layers at cryogenic temperatures. We attribute these features to bilayer Wigner crystals composed of two interlocked commensurate triangular electron lattices, stabilized by inter-layer interaction16. The Wigner crystal phases are remarkably stable, and undergo quantum and thermal melting transitions at electron densities of up to 6 × 1012 per square centimetre and at temperatures of up to about 40 kelvin. Our results demonstrate that an atomically thin heterostructure is a highly tunable platform for realizing many-body electronic states and probing their liquid–solid and magnetic quantum phase transitions4–8,17.Optical signatures reveal correlated insulating Wigner crystals—electron solids—in a bilayer of a two-dimensional transition metal dichalcogenide, MoSe2, with hexagonal boron nitride between the layers. [ABSTRACT FROM AUTHOR]

Published
2021
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15. Alternative Zuliefersysteme im Brauereisektor – Regionalmodelle des Braugerstenbezugs in Bayern.

Author

Maier, Philipp, Klein, Oliver, and Schumacher, Kim Philip

Abstract

Copyright of Standort: Zeitschrift für Angewandte Geographie is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2021
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16. Graphene-based Josephson junction microwave bolometer.

Author

Lee, Gil-Ho, Efetov, Dmitri K., Jung, Woochan, Ranzani, Leonardo, Walsh, Evan D., Ohki, Thomas A., Taniguchi, Takashi, Watanabe, Kenji, Kim, Philip, Englund, Dirk, and Fong, Kin Chung

Abstract

Sensitive microwave detectors are essential in radioastronomy1, dark-matter axion searches2 and superconducting quantum information science3,4. The conventional strategy to obtain higher-sensitivity bolometry is the nanofabrication of ever smaller devices to augment the thermal response5–7. However, it is difficult to obtain efficient photon coupling and to maintain the material properties in a device with a large surface-to-volume ratio owing to surface contamination. Here we present an ultimately thin bolometric sensor based on monolayer graphene. To utilize the minute electronic specific heat and thermal conductivity of graphene, we develop a superconductor–graphene–superconductor Josephson junction8–13 bolometer embedded in a microwave resonator with a resonance frequency of 7.9 gigahertz and over 99 per cent coupling efficiency. The dependence of the Josephson switching current on the operating temperature, charge density, input power and frequency shows a noise-equivalent power of 7 × 10−19 watts per square-root hertz, which corresponds to an energy resolution of a single 32-gigahertz photon14, reaching the fundamental limit imposed by intrinsic thermal fluctuations at 0.19 kelvin. Our results establish that two-dimensional materials could enable the development of bolometers with the highest sensitivity allowed by the laws of thermodynamics.An ultimately thin microwave bolometric sensor based on a superconductor–graphene–superconductor Josephson junction with monolayer graphene has a sensitivity approaching the fundamental limit imposed by intrinsic thermal fluctuations. [ABSTRACT FROM AUTHOR]

Published
2020
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17. Imaging viscous flow of the Dirac fluid in graphene.

Author

Ku, Mark J. H., Zhou, Tony X., Li, Qing, Shin, Young J., Shi, Jing K., Burch, Claire, Anderson, Laurel E., Pierce, Andrew T., Xie, Yonglong, Hamo, Assaf, Vool, Uri, Zhang, Huiliang, Casola, Francesco, Taniguchi, Takashi, Watanabe, Kenji, Fogler, Michael M., Kim, Philip, Yacoby, Amir, and Walsworth, Ronald L.

Abstract

The electron–hole plasma in charge-neutral graphene is predicted to realize a quantum critical system in which electrical transport features a universal hydrodynamic description, even at room temperature1,2. This quantum critical 'Dirac fluid' is expected to have a shear viscosity close to a minimum bound3,4, with an interparticle scattering rate saturating1 at the Planckian time, the shortest possible timescale for particles to relax. Although electrical transport measurements at finite carrier density are consistent with hydrodynamic electron flow in graphene5–8, a clear demonstration of viscous flow at the charge-neutrality point remains elusive. Here we directly image viscous Dirac fluid flow in graphene at room temperature by measuring the associated stray magnetic field. Nanoscale magnetic imaging is performed using quantum spin magnetometers realized with nitrogen vacancy centres in diamond. Scanning single-spin and wide-field magnetometry reveal a parabolic Poiseuille profile for electron flow in a high-mobility graphene channel near the charge-neutrality point, establishing the viscous transport of the Dirac fluid. This measurement is in contrast to the conventional uniform flow profile imaged in a metallic conductor and also in a low-mobility graphene channel. Via combined imaging and transport measurements, we obtain viscosity and scattering rates, and observe that these quantities are comparable to the universal values expected at quantum criticality. This finding establishes a nearly ideal electron fluid in charge-neutral, high-mobility graphene at room temperature4. Our results will enable the study of hydrodynamic transport in quantum critical fluids relevant to strongly correlated electrons in high-temperature superconductors9. This work also highlights the capability of quantum spin magnetometers to probe correlated electronic phenomena at the nanoscale. Viscous Dirac fluid flow in room-temperature graphene is imaged using quantum diamond magnetometry, revealing a parabolic Poiseuille profile for electron flow in a high-mobility graphene channel near the charge-neutrality point. [ABSTRACT FROM AUTHOR]

Published
2020
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18. Tunable spin-polarized correlated states in twisted double bilayer graphene.

Author

Liu, Xiaomeng, Hao, Zeyu, Khalaf, Eslam, Lee, Jong Yeon, Ronen, Yuval, Yoo, Hyobin, Haei Najafabadi, Danial, Watanabe, Kenji, Taniguchi, Takashi, Vishwanath, Ashvin, and Kim, Philip

Abstract

Reducing the energy bandwidth of electrons in a lattice below the long-range Coulomb interaction energy promotes correlation effects. Moiré superlattices—which are created by stacking van der Waals heterostructures with a controlled twist angle1–3—enable the engineering of electron band structure. Exotic quantum phases can emerge in an engineered moiré flat band. The recent discovery of correlated insulator states, superconductivity and the quantum anomalous Hall effect in the flat band of magic-angle twisted bilayer graphene4–8 has sparked the exploration of correlated electron states in other moiré systems9–11. The electronic properties of van der Waals moiré superlattices can further be tuned by adjusting the interlayer coupling6 or the band structure of constituent layers9. Here, using van der Waals heterostructures of twisted double bilayer graphene (TDBG), we demonstrate a flat electron band that is tunable by perpendicular electric fields in a range of twist angles. Similarly to magic-angle twisted bilayer graphene, TDBG shows energy gaps at the half- and quarter-filled flat bands, indicating the emergence of correlated insulator states. We find that the gaps of these insulator states increase with in-plane magnetic field, suggesting a ferromagnetic order. On doping the half-filled insulator, a sudden drop in resistivity is observed with decreasing temperature. This critical behaviour is confined to a small area in the density–electric-field plane, and is attributed to a phase transition from a normal metal to a spin-polarized correlated state. The discovery of spin-polarized correlated states in electric-field-tunable TDBG provides a new route to engineering interaction-driven quantum phases. Twisted double bilayer graphene devices show tunable spin-polarized correlated states that are sensitive to electric and magnetic fields, providing further insights into correlated states in two-dimensional moiré materials. [ABSTRACT FROM AUTHOR]

Published
2020
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20. Cannabis for Pain and Headaches: Primer.

Author

Kim, Philip, Fishman, Michael, Kim, Philip S, and Fishman, Michael A

Abstract

Purpose Of Review: Marijuana has been used both medicinally and recreationally since ancient times and interest in its compounds for pain relief has increased in recent years. The identification of our own intrinsic, endocannabinoid system has laid the foundation for further research.Recent Findings: Synthetic cannabinoids are being developed and synthesized from the marijuana plant such as dronabinol and nabilone. The US Food and Drug Administration approved the use of dronabinol and nabilone for chemotherapy-associated nausea and vomiting and HIV (Human Immunodeficiency Virus) wasting. Nabiximols is a cannabis extract that is approved for the treatment of spasticity and intractable pain in Canada and the UK. Further clinical trials are studying the effect of marijuana extracts for seizure disorders. Phytocannabinoids have been identified as key compounds involved in analgesia and anti-inflammatory effects. Other compounds found in cannabis such as flavonoids and terpenes are also being investigated as to their individual or synergistic effects. This article will review relevant literature regarding medical use of marijuana and cannabinoid pharmaceuticals with an emphasis on pain and headaches. [ABSTRACT FROM AUTHOR]

Published
2017
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23. Heterointerface effects in the electrointercalation of van der Waals heterostructures.

Author

Bediako, D. Kwabena, Rezaee, Mehdi, Yoo, Hyobin, Larson, Daniel T., Zhao, S. Y. Frank, Taniguchi, Takashi, Watanabe, Kenji, Brower-Thomas, Tina L., Kaxiras, Efthimios, and Kim, Philip

Abstract

Molecular-scale manipulation of electronic and ionic charge accumulation in materials is the backbone of electrochemical energy storage [1]- [4]. Layered van der Waals (vdW) crystals are a diverse family of materials into which mobile ions can electrochemically intercalate into the interlamellar gaps of the host atomic lattice [5], [6]. The structural diversity of such materials enables the interfacial properties of composites to be optimized to improve ion intercalation for energy storage and electronic devices [7]- [12]. However, the ability of heterolayers to modify intercalation reactions, and their role at the atomic level, are yet to be elucidated. Here we demonstrate the electrointercalation of lithium at the level of individual atomic interfaces of dissimilar vdW layers. Electrochemical devices based on vdW heterostructures [13] of stacked hexagonal boron nitride, graphene and molybdenum dichalcogenide (MoX2; X = S, Se) layers are constructed. We use transmission electron microscopy, in situ magnetoresistance and optical spectroscopy techniques, as well as low-temperature quantum magneto-oscillation measurements and ab initio calculations, to resolve the intermediate stages of lithium intercalation at heterointerfaces. The formation of vdW heterointerfaces between graphene and MoX2 results in a more than tenfold greater accumulation of charge in MoX2 when compared to MoX2/MoX2 homointerfaces, while enforcing a more negative intercalation potential than that of bulk MoX2 by at least 0.5 V. Beyond energy storage, our combined experimental and computational methodology for manipulating and characterizing the electrochemical behaviour of layered systems opens new pathways to control the charge density in two-dimensional electronic and optoelectronic devices. The electrointercalation of lithium into van der Waals heterostructures of graphene, hexagonal boron nitride and molybdenum dichalcogenides is studied at the level of individual atomic interfaces. [ABSTRACT FROM AUTHOR]

Published
2018
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25. Analysis of Scanned Probe Images for Magnetic Focusing in Graphene.

Author

Bhandari, Sagar, Lee, Gil-Ho, Kim, Philip, and Westervelt, Robert

Subjects
SCANNING probe microscopy, NANOELECTROMECHANICAL systems, ELECTRIC admittance, SCATTERING (Physics), ELECTRONS
Abstract

We have used cooled scanning probe microscopy (SPM) to study electron motion in nanoscale devices. The charged tip of the microscope was raster-scanned at constant height above the surface as the conductance of the device was measured. The image charge scatters electrons away, changing the path of electrons through the sample. Using this technique, we imaged cyclotron orbits that flow between two narrow contacts in the magnetic focusing regime for ballistic hBN-graphene-hBN devices. We present herein an analysis of our magnetic focusing imaging results based on the effects of the tip-created charge density dip on the motion of ballistic electrons. The density dip locally reduces the Fermi energy, creating a force that pushes electrons away from the tip. When the tip is above the cyclotron orbit, electrons are deflected away from the receiving contact, creating an image by reducing the transmission between contacts. The data and our analysis suggest that the graphene edge is rather rough, and electrons scattering off the edge bounce in random directions. However, when the tip is close to the edge, it can enhance transmission by bouncing electrons away from the edge, toward the receiving contact. Our results demonstrate that cooled SPM is a promising tool to investigate the motion of electrons in ballistic graphene devices. [ABSTRACT FROM AUTHOR]

Published
2017
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31. Multicenter evaluation of the role of UroVysion FISH assay in surveillance of patients with bladder cancer: does FISH positivity anticipate recurrence?

Author

Seideman, Casey, Canter, Daniel, Kim, Philip, Cordon, Billy, Weizer, Alon, Oliva, Irma, Rao, Jianyu, Inman, Brant, Posch, Michael, Herr, Harry, and Lotan, Yair

Subjects
BIOLOGICAL assay, BLADDER cancer treatment, CANCER relapse, CYSTOSCOPY, RETROSPECTIVE studies, CYTOLOGY
Abstract

Background: The significance of a positive UroVysion FISH assay is uncertain in patients with normal cystoscopy. This multicenter study evaluates the clinical significance of a positive FISH assay in patients with no visible tumor and excluding those with a positive cytology. Methods: A multi-institutional, retrospective study of patients with a history of urothelial carcinoma of the bladder identified 664 patients with a FISH assay after excluding those with cystoscopic evidence of a tumor and/or positive cytology. Our primary end point was cancer recurrence, defined by biopsy. Progression was defined as recurrence with a tumor stage ≥T2. Statistical analyses were performed using Fisher's exact test as a one-tailed test and Chi-square test with significance at 0.05, using SPSS version 19.0 (SPSS Inc., Chicago, IL, USA). Results: Of the 664 patients in this study, tumor stage was Ta (363, 55 %), T1 (183, 28 %), and CIS (109, 16 %) and most were high grade (440 pts, 66 %). The median follow-up was 26 months (3-104 months), and 277 (41.7 %) patients were recurred. In patients who were FISH positive, mean time to recurrence was 12.6 months, compared to 17.9 months if FISH negative ( p = 0.03). In univariate analysis, atypical cytology, positive FISH, cystoscopic findings (atypical vs. normal), and previous intravesical therapy were associated with recurrence ( p < 0.05). On multivariate analysis, pathologic stage, cystoscopic findings, and cytology were independently associated with recurrence ( p < 0.05). Progression to ≥T2 disease occurred in 34 (5.1 %) patients in this cohort. On multivariate analysis, only initial T stage and FISH result were found to be independent predictors of progression ( p < 0.05). Conclusions: Patients with a positive FISH and atypical cytology are more likely to recur even in the absence of visible tumor. FISH positivity may portend a higher risk for progression. These findings require prospective validation. [ABSTRACT FROM AUTHOR]

Published
2015
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32. Multi-terminal transport measurements of MoS2 using a van der Waals heterostructure device platform.

Author

Cui, Xu, Lee, Gwan-Hyoung, Kim, Young Duck, Arefe, Ghidewon, Huang, Pinshane Y., Lee, Chul-Ho, Chenet, Daniel A., Zhang, Xian, Wang, Lei, Ye, Fan, Pizzocchero, Filippo, Jessen, Bjarke S., Watanabe, Kenji, Taniguchi, Takashi, Muller, David A., Low, Tony, Kim, Philip, and Hone, James

Subjects
MOLYBDENUM disulfide, VAN der Waals forces, HETEROSTRUCTURES, SEMICONDUCTORS, ELECTRON mobility, QUANTUM mechanics
Abstract

Atomically thin two-dimensional semiconductors such as MoS2 hold great promise for electrical, optical and mechanical devices and display novel physical phenomena. However, the electron mobility of mono- and few-layer MoS2 has so far been substantially below theoretically predicted limits, which has hampered efforts to observe its intrinsic quantum transport behaviours. Potential sources of disorder and scattering include defects such as sulphur vacancies in the MoS2 itself as well as extrinsic sources such as charged impurities and remote optical phonons from oxide dielectrics. To reduce extrinsic scattering, we have developed here a van der Waals heterostructure device platform where MoS2 layers are fully encapsulated within hexagonal boron nitride and electrically contacted in a multi-terminal geometry using gate-tunable graphene electrodes. Magneto-transport measurements show dramatic improvements in performance, including a record-high Hall mobility reaching 34,000 cm2 V-1 s-1 for six-layer MoS2 at low temperature, confirming that low-temperature performance in previous studies was limited by extrinsic interfacial impurities rather than bulk defects in the MoS2. We also observed Shubnikov-de Haas oscillations in high-mobility monolayer and few-layer MoS2. Modelling of potential scattering sources and quantum lifetime analysis indicate that a combination of short-range and long-range interfacial scattering limits the low-temperature mobility of MoS2. [ABSTRACT FROM AUTHOR]

Published
2015
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33. C2H2 zinc finger proteins greatly expand the human regulatory lexicon.

Author

Najafabadi, Hamed S, Mnaimneh, Sanie, Schmitges, Frank W, Garton, Michael, Lam, Kathy N, Yang, Ally, Albu, Mihai, Weirauch, Matthew T, Radovani, Ernest, Kim, Philip M, Greenblatt, Jack, Frey, Brendan J, and Hughes, Timothy R

Subjects
ZINC-finger proteins, TRANSCRIPTION factors, GENETIC regulation, DNA-binding proteins, NUCLEOTIDE sequencing, IMMUNOPRECIPITATION
Abstract

Cys2-His2 zinc finger (C2H2-ZF) proteins represent the largest class of putative human transcription factors. However, for most C2H2-ZF proteins it is unknown whether they even bind DNA or, if they do, to which sequences. Here, by combining data from a modified bacterial one-hybrid system with protein-binding microarray and chromatin immunoprecipitation analyses, we show that natural C2H2-ZFs encoded in the human genome bind DNA both in vitro and in vivo, and we infer the DNA recognition code using DNA-binding data for thousands of natural C2H2-ZF domains. In vivo binding data are generally consistent with our recognition code and indicate that C2H2-ZF proteins recognize more motifs than all other human transcription factors combined. We provide direct evidence that most KRAB-containing C2H2-ZF proteins bind specific endogenous retroelements (EREs), ranging from currently active to ancient families. The majority of C2H2-ZF proteins, including KRAB proteins, also show widespread binding to regulatory regions, indicating that the human genome contains an extensive and largely unstudied adaptive C2H2-ZF regulatory network that targets a diverse range of genes and pathways. [ABSTRACT FROM AUTHOR]

Published
2015
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38. Inducing superconducting correlation in quantum Hall edge states

Author

Lee, Gil-Ho, Huang, Katie, Efetov, Dmitri K., Wei, Di Sonia, Hart, Sean, Taniguchi, Takashi, Watanabe, Kenji, Yacoby, Amir, and Kim, Philip

Abstract

The quantum Hall (QH) effect supports a set of chiral edge states at the boundary of a two-dimensional system. A superconductor (SC) contacting these states can provide correlations of the quasiparticles in the dissipationless edge states. Here we fabricated highly transparent and nanometre-scale SC junctions to graphene. We demonstrate that the QH edge states can couple via superconducting correlations through the SC electrode narrower than the superconducting coherence length. We observe that the chemical potential of the edge state exhibits a sign reversal across the SC electrode. This provides direct evidence of conversion of the incoming electron to the outgoing hole along the chiral edge state, termed crossed Andreev conversion (CAC). We show that CAC can successfully describe the temperature, bias and SC electrode width dependences. This hybrid SC/QH system could provide a novel route to create isolated non-Abelian anyonic zero modes, in resonance with the chiral edge states., Physics

Published
2017
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40. Atomically thin p-n junctions with van der Waals heterointerfaces.

Author

Lee, Chul-Ho, Lee, Gwan-Hyoung, van der Zande, Arend M., Chen, Wenchao, Li, Yilei, Han, Minyong, Cui, Xu, Arefe, Ghidewon, Nuckolls, Colin, Heinz, Tony F., Guo, Jing, Hone, James, and Kim, Philip

Subjects
P-N junctions (Semiconductors), VAN der Waals forces, OPTOELECTRONIC devices, SANDWICH construction (Materials), QUANTUM tunneling
Abstract

Semiconductor p-n junctions are essential building blocks for electronic and optoelectronic devices. In conventional p-n junctions, regions depleted of free charge carriers form on either side of the junction, generating built-in potentials associated with uncompensated dopant atoms. Carrier transport across the junction occurs by diffusion and drift processes influenced by the spatial extent of this depletion region. With the advent of atomically thin van der Waals materials and their heterostructures, it is now possible to realize a p-n junction at the ultimate thickness limit. Van der Waals junctions composed of p- and n-type semiconductors-each just one unit cell thick-are predicted to exhibit completely different charge transport characteristics than bulk heterojunctions. Here, we report the characterization of the electronic and optoelectronic properties of atomically thin p-n heterojunctions fabricated using van der Waals assembly of transition-metal dichalcogenides. We observe gate-tunable diode-like current rectification and a photovoltaic response across the p-n interface. We find that the tunnelling-assisted interlayer recombination of the majority carriers is responsible for the tunability of the electronic and optoelectronic processes. Sandwiching an atomic p-n junction between graphene layers enhances the collection of the photoexcited carriers. The atomically scaled van der Waals p-n heterostructures presented here constitute the ultimate functional unit for nanoscale electronic and optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published
2014
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41. Measurement of collective dynamical mass of Dirac fermions in graphene.

Author

Yoon, Hosang, Forsythe, Carlos, Wang, Lei, Tombros, Nikolaos, Watanabe, Kenji, Taniguchi, Takashi, Hone, James, Kim, Philip, and Ham, Donhee

Subjects
FERMIONS, GRAPHENE, QUASIPARTICLES, ELECTRONS, OPTICAL frequency conversion
Abstract

Individual electrons in graphene behave as massless quasiparticles. Unexpectedly, it is inferred from plasmonic investigations that electrons in graphene must exhibit a non-zero mass when collectively excited. The inertial acceleration of the electron collective mass is essential to explain the behaviour of plasmons in this material, and may be directly measured by accelerating it with a time-varying voltage and quantifying the phase delay of the resulting current. This voltage-current phase relation would manifest as a kinetic inductance, representing the reluctance of the collective mass to accelerate. However, at optical (infrared) frequencies, phase measurements of current are generally difficult, and, at microwave frequencies, the inertial phase delay has been buried under electron scattering. Therefore, to date, the collective mass in graphene has defied unequivocal measurement. Here, we directly and precisely measure the kinetic inductance, and therefore the collective mass, by combining device engineering that reduces electron scattering and sensitive microwave phase measurements. Specifically, the encapsulation of graphene between hexagonal boron nitride layers, one-dimensional edge contacts and a proximate top gate configured as microwave ground together enable the inertial phase delay to be resolved from the electron scattering. Beside its fundamental importance, the kinetic inductance is found to be orders of magnitude larger than the magnetic inductance, which may be utilized to miniaturize radiofrequency integrated circuits. Moreover, its bias dependency heralds a solid-state voltage-controlled inductor to complement the prevalent voltage-controlled capacitor. [ABSTRACT FROM AUTHOR]

Published
2014
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42. The impact of smoking on pathologic response to neoadjuvant cisplatin-based chemotherapy in patients with muscle-invasive bladder cancer.

Author

Kim, Philip, Kent, Matthew, Zhao, Philip, Sfakianos, John, Bajorin, Dean, Bochner, Bernard, and Dalbagni, Guido

Subjects
*SMOKING, *IMMUNOLOGICAL adjuvants, *CISPLATIN, *CANCER chemotherapy, *BLADDER cancer patients, *ETIOLOGY of diseases, *PATHOLOGY
Abstract

Purpose: Smoking is the primary etiologic risk factor for bladder cancer and has been implicated in mechanisms of chemoresistance. We investigated smoking as a potential predictor for pathologic outcomes after neoadjuvant chemotherapy (NC) and radical cystectomy (RC) for muscle-invasive bladder cancer. Methods: We identified 139 patients treated with neoadjuvant cisplatin-based chemotherapy followed by RC for T2-4aN0M0 bladder cancer. Logistic regression was used to evaluate associations between smoking characteristics and pathologic outcomes (pT0, complete response; pT0/pTis/pT1, any response). In a secondary analysis, multivariate Cox regression was used to assess associations between smoking and recurrence-free and cancer-specific survival. Results: Our cohort consisted of 99 (71 %) males, with a median age of 65 (interquartile range 56, 71). Prevalence of never, former, and current smokers was 25, 45, and 29 %, respectively. In total, 63 patients experienced disease recurrence, 39 died of disease, and 11 died of other causes. There were no statistically significant associations between smoking characteristics and complete ( p = 0.5) or any ( p = 0.2) pathologic response to NC. Similarly, we did not find any association between smoking characteristics and recurrence ( p = 0.6) or cancer-specific survival ( p = 0.9). Conclusions: In this series, smoking characteristics were not found to be predictive of pathologic response after NC and RC, although this analysis was limited by the small study sample size. However, the harmful effects of smoking warrants continued emphasis on smoking cessation counseling in bladder cancer patients. [ABSTRACT FROM AUTHOR]

Published
2014
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44. Label-free single-molecule detection of DNA-hybridization kinetics with a carbon nanotube field-effect transistor.

Author

Sorgenfrei, Sebastian, Gonzalez Jr., Ruben L., Kim, Philip, Nuckolls, Colin, Shepard, Kenneth L., Chien-yang Chiu, and Young-Jun Yu

Subjects
BIOMOLECULES, DNA, NUCLEIC acid hybridization, FLUORESCENCE spectroscopy, CARBON nanotubes, FIELD-effect transistors
Abstract

Single-molecule measurements of biomolecules can provide information about the molecular interactions and kinetics that are hidden in ensemble measurements. However, there is a requirement for techniques with improved sensitivity and time resolution for use in exploring biomolecular systems with fast dynamics. Here, we report the detection of DNA hybridization at the single-molecule level using a carbon nanotube field-effect transistor. By covalently attaching a single-stranded probe DNA sequence to a point defect in a carbon nanotube, we are able to measure two-level fluctuations in the conductance of the nanotube in the presence of a complementary DNA target. The kinetics of the system are studied as a function of temperature, allowing the measurement of rate constants, melting curves and activation energies for different sequences and target concentrations. The kinetics demonstrate non-Arrhenius behaviour, in agreement with DNA hybridization experiments using fluorescence correlation spectroscopy. This technique is label-free and could be used to probe single-molecule dynamics at microsecond timescales. [ABSTRACT FROM AUTHOR]

Published
2011
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45. Nucleotide-resolution analysis of structural variants using BreakSeq and a breakpoint library.

Author

Lam, Hugo Y. K., Mu, Xinmeng Jasmine, Stütz, Adrian M., Tanzer, Andrea, Cayting, Philip D., Snyder, Michael, Kim, Philip M., Korbel, Jan O., and Gerstein, Mark B.

Subjects
GENOMICS, MOLECULAR genetics, NUCLEOTIDES, NUCLEIC acids, OLIGONUCLEOTIDES, GENOMES
Abstract

Structural variants (SVs) are a major source of human genomic variation; however, characterizing them at nucleotide resolution remains challenging. Here we assemble a library of breakpoints at nucleotide resolution from collating and standardizing ~2,000 published SVs. For each breakpoint, we infer its ancestral state (through comparison to primate genomes) and its mechanism of formation (e.g., nonallelic homologous recombination, NAHR). We characterize breakpoint sequences with respect to genomic landmarks, chromosomal location, sequence motifs and physical properties, finding that the occurrence of insertions and deletions is more balanced than previously reported and that NAHR-formed breakpoints are associated with relatively rigid, stable DNA helices. Finally, we demonstrate an approach, BreakSeq, for scanning the reads from short-read sequenced genomes against our breakpoint library to accurately identify previously overlooked SVs, which we then validate by PCR. As new data become available, we expect our BreakSeq approach will become more sensitive and facilitate rapid SV genotyping of personal genomes. [ABSTRACT FROM AUTHOR]

Published
2010
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46. Performance of monolayer graphene nanomechanical resonators with electrical readout.

Author

Changyao Chen, Rosenblatt, Sami, Bolotin, Kirill I., Kalb, William, Kim, Philip, Kymissis, Ioannis, Stormer, Horst L., Heinz, Tony F., and Hone, James

Subjects
GRAPHENE, NANOELECTROMECHANICAL systems, ELECTRIC resonators, STIFFNESS (Mechanics), RESONANT ultrasound spectroscopy
Abstract

The enormous stiffness and low density of graphene make it an ideal material for nanoelectromechanical applications. Here, we demonstrate the fabrication and electrical readout of monolayer graphene resonators, and test their response to changes in mass and temperature. The devices show resonances in the megahertz range, and the strong dependence of resonant frequency on applied gate voltage can be fitted to a membrane model to yield the mass density and built-in strain of the graphene. Following the removal and addition of mass, changes in both density and strain are observed, indicating that adsorbates impart tension to the graphene. On cooling, the frequency increases, and the shift rate can be used to measure the unusual negative thermal expansion coefficient of graphene. The quality factor increases with decreasing temperature, reaching ∼1 × 104 at 5 K. By establishing many of the basic attributes of monolayer graphene resonators, the groundwork for applications of these devices, including high-sensitivity mass detectors, is put in place. [ABSTRACT FROM AUTHOR]

Published
2009
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47. Observation of the fractional quantum Hall effect in graphene.

Author

Bolotin, Kirill I., Ghahari, Fereshte, Shulman, Michael D., Stormer, Horst L., and Kim, Philip

Subjects
QUANTUM Hall effect, GRAPHENE, ELECTRON-electron interactions, MAGNETIC fields, COULOMB functions, QUANTUM theory, MAGNETIC flux, CHIRALITY of nuclear particles, PARTICLES (Nuclear physics)
Abstract

When electrons are confined in two dimensions and subject to strong magnetic fields, the Coulomb interactions between them can become very strong, leading to the formation of correlated states of matter, such as the fractional quantum Hall liquid. In this strong quantum regime, electrons and magnetic flux quanta bind to form complex composite quasiparticles with fractional electronic charge; these are manifest in transport measurements of the Hall conductivity as rational fractions of the elementary conductance quantum. The experimental discovery of an anomalous integer quantum Hall effect in graphene has enabled the study of a correlated two-dimensional electronic system, in which the interacting electrons behave like massless chiral fermions. However, owing to the prevailing disorder, graphene has so far exhibited only weak signatures of correlated electron phenomena, despite intense experimental and theoretical efforts. Here we report the observation of the fractional quantum Hall effect in ultraclean, suspended graphene. In addition, we show that at low carrier density graphene becomes an insulator with a magnetic-field-tunable energy gap. These newly discovered quantum states offer the opportunity to study correlated Dirac fermions in graphene in the presence of large magnetic fields. [ABSTRACT FROM AUTHOR]

Published
2009
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48. Near-field focusing and magnification through self-assembled nanoscale spherical lenses.

Author

Ju Young Lee, Byung Hee Hong, Woo Youn Kim, Seung Kyu Min, Yukyung Kim, Jouravlev, Mikhail V., Bose, Ranojoy, Keun Soo Kim, In-Chul Hwang, Kaufman, Laura J., Chee Wei Wong, Kim, Philip, and Kim, Kwang S.

Subjects
MICROSCOPES, PLASMONS (Physics), OPTICS, OPTICAL diffraction, MOLECULES, FLUORESCENCE microscopy
Abstract

It is well known that a lens-based far-field optical microscope cannot resolve two objects beyond Abbe’s diffraction limit. Recently, it has been demonstrated that this limit can be overcome by lensing effects driven by surface-plasmon excitation, and by fluorescence microscopy driven by molecular excitation. However, the resolution obtained using geometrical lens-based optics without such excitation schemes remains limited by Abbe’s law even when using the immersion technique, which enhances the resolution by increasing the refractive indices of immersion liquids. As for submicrometre-scale or nanoscale objects, standard geometrical optics fails for visible light because the interactions of such objects with light waves are described inevitably by near-field optics. Here we report near-field high resolution by nanoscale spherical lenses that are self-assembled by bottom-up integration of organic molecules. These nanolenses, in contrast to geometrical optics lenses, exhibit curvilinear trajectories of light, resulting in remarkably short near-field focal lengths. This in turn results in near-field magnification that is able to resolve features beyond the diffraction limit. Such spherical nanolenses provide new pathways for lens-based near-field focusing and high-resolution optical imaging at very low intensities, which are useful for bio-imaging, near-field lithography, optical memory storage, light harvesting, spectral signal enhancing, and optical nano-sensing. [ABSTRACT FROM AUTHOR]

Published
2009
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49. Quantum interference and Klein tunnelling in graphene heterojunctions.

Author

Young, Andrea F. and Kim, Philip

Subjects
*QUANTUM interference, *QUANTUM theory, *QUANTUM tunneling, *HETEROJUNCTIONS, *SEMICONDUCTOR junctions
Abstract

The observation of quantum conductance oscillations in mesoscopic systems has traditionally required the confinement of the carriers to a phase space of reduced dimensionality. Although electron optics such as lensing and focusing have been demonstrated experimentally, building a collimated electron interferometer in two unconfined dimensions has remained a challenge owing to the difficulty of creating electrostatic barriers that are sharp on the order of the electron wavelength. Here, we report the observation of conductance oscillations in extremely narrow graphene heterostructures where a resonant cavity is formed between two electrostatically created bipolar junctions. Analysis of the oscillations confirms that p–n junctions have a collimating effect on ballistically transmitted carriers. The phase shift observed in the conductance fringes at low magnetic fields is a signature of the perfect transmission of carriers normally incident on the junctions and thus constitutes a direct experimental observation of ‘Klein tunnelling’. [ABSTRACT FROM AUTHOR]

Published
2009
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50. Outcomes of patients with clinical CIS-only disease treated with radical cystectomy.

Author

Huang, George Jiunruey, Kim, Philip H., Skinner, Donald G., and Stein, John P.

Subjects
*LYMPH node diseases, *URINARY organ diseases, *BLADDER cancer treatment, *FEMALE reproductive organ diseases, *PATIENTS, *THERAPEUTICS
Abstract

To report the long-term oncological efficacy of radical cystectomy for patients with presumed clinical CIS only disease, to characterize the likelihood of clinical understaging, and to characterize the pattern of recurrence. One thousand six hundred patients have undergone radical cystectomy and pelvic lymph node dissection with intent to cure from August 1971 to December 2005 at the University of Southern California; 27 patients from this cohort who satisfied both the inclusion and exclusion criteria were identified. Relevant clinical and pathological data at time of cystectomy and during follow-up were reported. Overall and recurrence-free survival was estimated using the Kaplan–Meier method. At time of cystectomy, 33% of patients were found to be clinically understaged. Median follow-up was 94 months. Estimated 5- and 10-year overall survival was 87 and 56%, respectively. Estimated 5- and 10-year recurrence-free survival was 100 and 83%, respectively. Excellent long-term survival outcomes can be achieved with radical cystectomy. Radical cystectomy should be strongly considered for patients who have failed prior intravesical therapy. Long-term surveillance of the retained urethra and of the upper tract is essential, as recurrence can occur years following cystectomy. Patients who recur are at high risk of dying from disease. [ABSTRACT FROM AUTHOR]

Published
2009
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