38 research outputs found
Spatiotemporal Mapping of Photocurrent in a Monolayer Semiconductor Using a Diamond Quantum Sensor
The detection of photocurrents is central to understanding and harnessing the
interaction of light with matter. Although widely used, transport-based
detection averages over spatial distributions and can suffer from low
photocarrier collection efficiency. Here, we introduce a contact-free method to
spatially resolve local photocurrent densities using a proximal quantum
magnetometer. We interface monolayer MoS2 with a near-surface ensemble of
nitrogen-vacancy centers in diamond and map the generated photothermal current
distribution through its magnetic field profile. By synchronizing the
photoexcitation with dynamical decoupling of the sensor spin, we extend the
sensor's quantum coherence and achieve sensitivities to alternating current
densities as small as 20 nA per micron. Our spatiotemporal measurements reveal
that the photocurrent circulates as vortices, manifesting the Nernst effect,
and rises with a timescale indicative of the system's thermal properties. Our
method establishes an unprecedented probe for optoelectronic phenomena, ideally
suited to the emerging class of two-dimensional materials, and stimulates
applications towards large-area photodetectors and stick-on sources of magnetic
fields for quantum control.Comment: 19 pages, 4 figure
Improved Coherence in Optically-Defined Niobium Trilayer Junction Qubits
Niobium offers the benefit of increased operating temperatures and
frequencies for Josephson junctions, which are the core component of
superconducting devices. However existing niobium processes are limited by more
complicated fabrication methods and higher losses than now-standard aluminum
junctions. Combining recent trilayer fabrication advancements, methods to
remove lossy dielectrics and modern superconducting qubit design, we revisit
niobium trilayer junctions and fabricate all-niobium transmons using only
optical lithography. We characterize devices in the microwave domain, measuring
coherence times up to s and an average qubit quality factor above
: much closer to state-of-the-art aluminum-junction devices. We find the
higher superconducting gap energy also results in reduced quasiparticle
sensitivity above K, where aluminum junction performance deteriorates.
Our low-loss junction process is readily applied to standard optical-based
foundry processes, opening new avenues for direct integration and scalability,
and paves the way for higher-temperature and higher-frequency quantum devices
Autonomous error correction of a single logical qubit using two transmons
Large-scale quantum computers will inevitably need quantum error correction
to protect information against decoherence. Traditional error correction
typically requires many qubits, along with high-efficiency error syndrome
measurement and real-time feedback. Autonomous quantum error correction (AQEC)
instead uses steady-state bath engineering to perform the correction in a
hardware-efficient manner. We realize an AQEC scheme, implemented with only two
transmon qubits in a 2D scalable architecture, that actively corrects
single-photon loss and passively suppresses low-frequency dephasing using six
microwave drives. Compared to uncorrected encoding, factors of 2.0, 5.1, and
1.4 improvements are experimentally witnessed for the logical zero, one, and
superposition states. Our results show the potential of implementing
hardware-efficient AQEC to enhance the reliability of a transmon-based quantum
information processor
Multidrug efflux pumps:structure, function and regulation
Infections arising from multidrug-resistant pathogenic bacteria are spreading rapidly throughout the world and threaten to become untreatable. The origins of resistance are numerous and complex, but one underlying factor is the capacity of bacteria to rapidly export drugs through the intrinsic activity of efflux pumps. In this Review, we describe recent advances that have increased our understanding of the structures and molecular mechanisms of multidrug efflux pumps in bacteria. Clinical and laboratory data indicate that efflux pumps function not only in the drug extrusion process but also in virulence and the adaptive responses that contribute to antimicrobial resistance during infection. The emerging picture of the structure, function and regulation of efflux pumps suggests opportunities for countering their activities
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Joint analysis of three genome-wide association studies of esophageal squamous cell carcinoma in Chinese populations
We conducted a joint (pooled) analysis of three genome-wide association studies (GWAS) 1-3 of esophageal squamous cell carcinoma (ESCC) in ethnic Chinese (5,337 ESCC cases and 5,787 controls) with 9,654 ESCC cases and 10,058 controls for follow-up. In a logistic regression model adjusted for age, sex, study, and two eigenvectors, two new loci achieved genome-wide significance, marked by rs7447927 at 5q31.2 (per-allele odds ratio (OR) = 0.85, 95% CI 0.82-0.88; P=7.72x10−20) and rs1642764 at 17p13.1 (per-allele OR= 0.88, 95% CI 0.85-0.91; P=3.10x10−13). rs7447927 is a synonymous single nucleotide polymorphism (SNP) in TMEM173 and rs1642764 is an intronic SNP in ATP1B2, near TP53. Furthermore, a locus in the HLA class II region at 6p21.32 (rs35597309) achieved genome-wide significance in the two populations at highest risk for ESSC (OR=1.33, 95% CI 1.22-1.46; P=1.99x10−10). Our joint analysis identified new ESCC susceptibility loci overall as well as a new locus unique to the ESCC high risk Taihang Mountain region
ASSEMBLY OF TWO-DIMENSIONAL ATOMIC LAYERS FOR QUANTUM CIRCUIT ENGINEERING
99 pagesEver since the first digital computer—built on hundreds of vacuum tubes—appeared in 1942, computers have evolved from room-sized machines to hand-held devices and transformed our daily lives. This impressive evolution in computers, the same as other modern technologies, is driven by the understanding of new physics, materials, and technologies. Undoubtedly, the next tech-revolution will depend on these likewise. The Two-dimensional material family is one of the promising candidates for future technology. These materials include diverse material species from metals, semiconductors to superconductors and so on, all with layered structures where each layer is only one to few atoms in thickness. Their structures of saturated in-plane covalent bonds result in the out-of-plane interlayer coupling via weak and directionless van der Waals force. These characteristics allow us to assemble any combination of two-dimensional materials layer-by-layer to create unprecedented heterostructures with atomic precision that can host exciting new physics. In this dissertation, I will present my and my colleague’s efforts to develop new methodologies for large-scale, layer-by-layer assembly of two-dimensional materials. These methods enable us to investigate and design the properties of the assembled films on the atomic scale. Based on our methods, we further demonstrate qubits that are built with two-dimensional materials for quantum computers for the first time. The methodologies and demonstrations here, hopefully, will help to pave the way for two-dimensional materials based technology in the future tech-revolution
Tuning Electrical Conductance of MoS2 Monolayers through Substitutional Doping
Tuning electrical conductivity of semiconducting materials through substitutional doping is crucial for fabricating functional devices. This, however, has not been fully realized in two-dimensional (2D) materials due to the difficulty of homogeneously controlling the dopant concentrations and the lack of systematic study of the net impact of substitutional dopants separate from that of the unintentional doping from the device fabrication processes. Here, we grow wafer-scale, continuous MoS2 monolayers with tunable concentrations of Nb and Re and fabricate devices using a polymer-free approach to study the direct electrical impact of substitutional dopants in MoS2 monolayers. In particular, the electrical conductivity of Nb doped MoS2 in the is absence of electrostatic gating is reproducibly tuned over 7 orders of magnitude by controlling the Nb concentration. Our study further indicates that the dopant carriers do not fully ionize in the 2D limit, unlike in their three-dimensional analogues, which is explained by weaker charge screening and impurity band conduction. Moreover, we show that the dopants are stable, which enables the doped films to be processed as independent building blocks that can be used as electrodes for functional circuitry
Correction: Liu, H.W.; et al. Enhanced Hsa-miR-181d/p-STAT3 and Hsa-miR-181d/p-STAT5A Ratios Mediate the Anticancer Effect of Garcinol in STAT3/5A-Addicted Glioblastoma. Cancers 2019, 11, 1888
The authors wish to make the following corrections to this paper [...
Wafer-scale synthesis of monolayer two-dimensional porphyrin polymers for hybrid superlattices
The large-scale synthesis of high-quality thin films with extensive tunability derived from molecular building blocks will advance the development of artificial solids with designed functionalities. We report the synthesis of two-dimensional (2D) porphyrin polymer films with wafer-scale homogeneity in the ultimate limit of monolayer thickness by growing films at a sharp pentane/water interface, which allows the fabrication of their hybrid superlattices. Laminar assembly polymerization of porphyrin monomers could form monolayers of metal-organic frameworks with Cu2+ linkers or covalent organic frameworks with terephthalaldehyde linkers. Both the lattice structures and optical properties of these 2D films were directly controlled by the molecular monomers and polymerization chemistries. The 2D polymers were used to fabricate arrays of hybrid superlattices with MoS2 that could be used in electrical capacitors