3,077 research outputs found
Quantum Multicriticality near the Dirac-Semimetal to Band-Insulator Critical Point in Two Dimensions: A Controlled Ascent from One Dimension
We compute the effects of generic short-range interactions on gapless
electrons residing at the quantum critical point separating a two-dimensional
Dirac semimetal (DSM) and a symmetry-preserving band insulator (BI). The
electronic dispersion at this critical point is anisotropic ( with ), which results in unconventional
scaling of physical observables. Due to the vanishing density of states
(), this anisotropic semimetal (ASM) is stable
against weak short-range interactions. However, for stronger interactions the
direct DSM-BI transition can either become a first-order transition, or
get avoided by an intervening broken-symmetry phase (BSP). We perform a
renormalization group analysis by perturbing away from the one-dimensional
limit with the small parameter , augmented with a
expansion (parametrically suppressing quantum fluctuations in higher
dimension). We identify charge density wave (CDW), antiferromagnet (AFM) and
singlet s-wave superconductor as the three dominant candidates for the BSP. The
onset of any such order at strong coupling takes place
through a continuous quantum phase transition across multicritical point. We
also present the phase diagram of an extended Hubbard model for the ASM,
obtained via the controlled deformation of its counterpart in one dimension.
The latter displays spin-charge separation and instabilities to CDW, spin
density wave, and Luther-Emery liquid phases at arbitrarily weak coupling. The
spin density wave and Luther-Emery liquid phases deform into pseudospin
SU(2)-symmetric quantum critical points separating the ASM from the AFM and
superconducting orders, respectively. Our results can be germane for a
uniaxially strained honeycomb lattice or organic compound
-(BEDT-TTF).Comment: Published version: 33 Pages, 13 Figures, 7 Tables (Shortened abstract
due to character limit for arXiv submission; see main text
Hubert Butler Essay Prize: what happened to Europe without frontiers?
The great Irish essayist Hubert Butler was a cosmopolitan, his sensibility being both Irish and passionately European. He situated Ireland squarely in the main current of European history, whereas England occupied a kind of eccentric tributary, or even backwater, of its own making. Thus, the vote for Brexit would not have surprised him, writes Roy Foster who judged the inaugural Hubert Butler Essay Prize this year
Alien Registration- Foster, Roy E. (Lewiston, Androscoggin County)
https://digitalmaine.com/alien_docs/29744/thumbnail.jp
Topological superconductivity of spin-3/2 carriers in a three-dimensional doped Luttinger semimetal
We investigate topological Cooper pairing, including gapless Weyl and fully
gapped class DIII superconductivity, in a three-dimensional doped Luttinger
semimetal. The latter describes effective spin-3/2 carriers near a quadratic
band touching and captures the normal-state properties of the 227 pyrochlore
iridates and half-Heusler alloys. Electron-electron interactions may favor
non--wave pairing in such systems, including even-parity -wave pairing.
We argue that the lowest energy -wave pairings are always of complex (e.g.,
) type, with nodal Weyl quasiparticles. This implies scaling of the density of states (DoS) at low energies in the clean
limit, or over a wide critical region in the presence of
disorder. The latter is consistent with the -dependence of the penetration
depth in the half-Heusler compound YPtBi. We enumerate routes for experimental
verification, including specific heat, thermal conductivity, NMR relaxation
time, and topological Fermi arcs. Nucleation of any -wave pairing also
causes a small lattice distortion and induces an -wave component; this gives
a route to strain-engineer exotic pairings. We also consider odd-parity,
fully gapped -wave superconductivity. For hole doping, a gapless Majorana
fluid with cubic dispersion appears at the surface. We invent a generalized
surface model with -fold dispersion to simulate a bulk with winding number
. Using exact diagonalization, we show that disorder drives the surface
into a critically delocalized phase, with universal DoS and multifractal
scaling consistent with the conformal field theory (CFT) SO(), where
counts replicas. This is contrary to the naive expectation of
a surface thermal metal, and implies that the topology tunes the surface
renormalization group to the CFT in the presence of disorder.Comment: Published Version in PRB (Editors' Suggestion): 49 Pages, 17 Figures,
3 Table
ASTM patio, carport and awning standard
Issued as Monthly progress letter no. 1-2, and Letter report, Project no. A-181
The Homeostasis Protocol: Avoiding Transaction Coordination Through Program Analysis
Datastores today rely on distribution and replication to achieve improved
performance and fault-tolerance. But correctness of many applications depends
on strong consistency properties - something that can impose substantial
overheads, since it requires coordinating the behavior of multiple nodes. This
paper describes a new approach to achieving strong consistency in distributed
systems while minimizing communication between nodes. The key insight is to
allow the state of the system to be inconsistent during execution, as long as
this inconsistency is bounded and does not affect transaction correctness. In
contrast to previous work, our approach uses program analysis to extract
semantic information about permissible levels of inconsistency and is fully
automated. We then employ a novel homeostasis protocol to allow sites to
operate independently, without communicating, as long as any inconsistency is
governed by appropriate treaties between the nodes. We discuss mechanisms for
optimizing treaties based on workload characteristics to minimize
communication, as well as a prototype implementation and experiments that
demonstrate the benefits of our approach on common transactional benchmarks
The Ursinus Weekly, December 12, 1949
Women select four to appear on ballot for May sovereign • Twelve receive Who\u27s who honors • Students anticipate traditional roster of yuletide events • Men\u27s council clarifies stand on frosh customs • Music group plans January 5 concert • Yuletide setting pervades starlight ball • Messiah ensemble wins new acclaim • Ruby sells greeting cards, plans welcome-back dance • Bear quintet loses 73-54 to strong Moravian five • Cubs score victory in greyhound game with 44-36 margin • Court coeds report for daily practice; experience lacking • Jayvees win third; down Lehigh 48-46 in thrilling battle • Ursinus rallies too late; Engineers triumph 49-42 • Players to receive fall sport awardshttps://digitalcommons.ursinus.edu/weekly/1580/thumbnail.jp
Supramolecular structure in the membrane of Staphylococcus aureus
The fundamental processes of life are organized and based on common basic principles. Molecular organizers, often interacting with the membrane, capitalize on cellular polarity to precisely orientate essential processes. The study of organisms lacking apparent polarity or known cellular organizers (e.g., the bacterium Staphylococcus aureus) may enable the elucidation of the primal organizational drive in biology. How does a cell choose from infinite locations in its membrane? We have discovered a structure in the S. aureus membrane that organizes processes indispensable for life and can arise spontaneously from the geometric constraints of protein complexes on membranes. Building on this finding, the most basic cellular positioning system to optimize biological processes, known molecular coordinators could introduce further levels of complexity.
All life demands the temporal and spatial control of essential biological functions. In bacteria, the recent discovery of coordinating elements provides a framework to begin to explain cell growth and division. Here we present the discovery of a supramolecular structure in the membrane of the coccal bacterium Staphylococcus aureus, which leads to the formation of a large-scale pattern across the entire cell body; this has been unveiled by studying the distribution of essential proteins involved in lipid metabolism (PlsY and CdsA). The organization is found to require MreD, which determines morphology in rod-shaped cells. The distribution of protein complexes can be explained as a spontaneous pattern formation arising from the competition between the energy cost of bending that they impose on the membrane, their entropy of mixing, and the geometric constraints in the system. Our results provide evidence for the existence of a self-organized and nonpercolating molecular scaffold involving MreD as an organizer for optimal cell function and growth based on the intrinsic self-assembling properties of biological molecules
The Application Of Impact Dampers To Continuous Systems
A study has been made of the application of impact dampers to two types of continuous systems, a simply supported and a clamped beam. Experimental models were tested in the laboratory and computer programs were developed to calculate response by two separate approaches. Results from calculations agreed favorably with experimental tests. Curves presented show the response to be expected for values of significant system parameters and enable the user to apply impact dampers to these types of continuous systems. © 1975 by ASME
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