Your search keyword '"Symmetry breaking"' showing total 269 results

1. Magnetism in Strongly Interacting One-Dimensional Quantum Mixtures.

Author

Massignan, Pietro, Levinsen, Jesper, and Parish, Meera M.

Subjects

*QUANTUM mechanics, *GROUND state (Quantum mechanics), *HEISENBERG model, *SYMMETRY breaking, *FERROMAGNETISM, *FERMI level

Abstract

We consider two species of bosons in one dimension near the Tonks-Girardeau limit of infinite interactions. For the case of equal masses and equal intraspecies interactions, the system can be mapped to a S=1/2 XXZ Heisenberg spin chain, thus allowing one to access different magnetic phases. Using a powerful ansatz developed for the two-component Fermi system, we elucidate the evolution from few to many particles for the experimentally relevant case of an external harmonic confinement. In the few-body limit, we already find clear evidence of both ferromagnetic and antiferromagnetic spin correlations as the ratio of intraspecies and interspecies interactions is varied. Furthermore, we observe the rapid emergence of symmetry-broken magnetic ground states as the particle number is increased. We therefore demonstrate that systems containing only a few bosons are an ideal setting in which to realize the highly sought-after itinerant ferromagnetic phase. [ABSTRACT FROM AUTHOR]

Published

2015

2. Cascading Multicriticality in Nonrelativistic Spontaneous Symmetry Breaking.

Author

Griffin, Tom, Grosvenor, Kevin T., Hořava, Petr, and Ziqi Yan

Subjects

*SYMMETRY breaking, *NONRELATIVISTIC quantum mechanics, *LORENTZ invariance, *NAMBU-Goldstone bosons, *INFRARED radiation

Abstract

Without Lorentz invariance, spontaneous global symmetry breaking can lead to multicritical Nambu-Goldstone modes with a higher-order low-energy dispersion ω ∼ kn (n = 2,3,...), whose naturalness is protected by polynomial shift symmetries. Here, we investigate the role of infrared divergences and the nonrelativistic generalization of the Coleman-Hohenberg-Mermin-Wagner (CHMW) theorem. We find novel cascading phenomena with large hierarchies between the scales at which the value of n changes, leading to an evasion of the "no-go" consequences of the relativistic CHMW theorem. [ABSTRACT FROM AUTHOR]

Published

2015

3. Thermodynamic Identities and Symmetry Breaking in Short-Range Spin Glasses.

Author

Arguin, L.-P., Newman, C. M., and Stein, D. L.

Subjects

*SPIN glasses, *SYMMETRY breaking, *THERMODYNAMICS, *HAMILTONIAN systems, *SYMMETRY (Physics)

Abstract

We present a technique to generate relations connecting pure state weights, overlaps, and correlation functions in short-range spin glasses. These are obtained directly from the unperturbed Hamiltonian and hold for general coupling distributions. All are satisfied in phases with simple thermodynamic structure, such as the droplet-scaling and chaotic pairs pictures. If instead nontrivial mixed-state pictures hold, the relations suggest that replica symmetry is broken as described by a Derrida-Ruelle cascade, with pure state weights distributed as a Poisson-Dirichlet process [ABSTRACT FROM AUTHOR]

Published

2015

4. Braiding a Flock: Winding Statistics of Interacting Flying Spins.

Author

Caussin, Jean-Baptiste and Bartolo, Denis

Subjects

*ANIMAL herds, *PARTICLE tracks (Nuclear physics), *STATISTICS, *SYMMETRY breaking, *ANIMAL mechanics

Abstract

When animal groups move coherently in the form of a flock, their trajectories are not all parallel, the individuals exchange their position in the group. In this Letter, we introduce a measure of this mixing dynamics, which we quantify as the winding of the braid formed from the particle trajectories. Building on a paradigmatic flocking model we numerically and theoretically explain the winding statistics and show that it is predominantly set by the global twist of the trajectories as a consequence of a spontaneous symmetry breaking. [ABSTRACT FROM AUTHOR]

Published

2015

5. Random Flips of Electric Field in Microwave-Induced States with Spontaneously Broken Symmetry.

Author

Dorozhkin, S. I., Umansky, V., Pfeiffer, L. N., West, K. W., Baldwin, K., von Klitzing, K., and Smet, J. H.

Subjects

*ELECTRIC fields, *MICROWAVES, *SYMMETRY breaking, *ELECTRONS, *MAGNETIC fields

Abstract

In a two-dimensional electron system subject to microwaves and a magnetic field, photovoltages emerge. They can be separated into two components originating from built-in electric fields and electric field domains arising from spontaneous symmetry breaking. The latter occurs in the zero resistance regime only and manifests itself in pulsed behavior, synchronous across the sample. The pulses show sign reversal. This implies a flip of the field in each domain, consistent with the existence of two equally probable electric field domain configurations due to the spontaneous symmetry breaking. [ABSTRACT FROM AUTHOR]

Published

2015

6. Direct Observation of Magnetochiral Effects through a Single Metamolecule in Microwave Regions.

Author

Satoshi Tomita, Kei Sawada, Porokhnyuk, Andrey, and Tetsuya Ueda

Subjects

*MAGNETOOPTICS, *MICROWAVES, *CHIRALITY, *MAGNETISM, *SYMMETRY breaking, *REFRACTIVE index

Abstract

We report direct observation of magnetochiral (MCh) effects for the X-band microwaves through a single metamolecule consisting of a copper chiral structure and ferrite rod. A fictitious interaction between chirality and magnetism is realized in the metamolecule without intrinsic electronic interactions. The MCh effects are induced at the resonant optical activities by applying a weak dc magnetic field of 1 mT, and are increased with the magnetic field. The nonreciprocal differences in refractive indices are evaluated to be 10-3 at 200 mT. [ABSTRACT FROM AUTHOR]

Published

2014

7. Viable Dark Matter via Radiative Symmetry Breaking in a Scalar Singlet Higgs Portal Extension of the Standard Model.

Author

Steele, T. G., Zhi-Wei Wang, Contreras, D., and Mann, R. B.

Subjects

*DARK matter, *SYMMETRY breaking, *STANDARD model (Nuclear physics), *CONFORMAL field theory, *ELECTROWEAK interactions

Abstract

We consider the generation of dark matter mass via radiative electroweak symmetry breaking in an extension of the conformal standard model containing a singlet scalar field with a Higgs portal interaction. Generating the mass from a sequential process of radiative electroweak symmetry breaking followed by a conventional Higgs mechanism can account for less than 35% of the cosmological dark matter abundance for dark matter mass Ms > 80 GeV. However, in a dynamical approach where both Higgs and scalar singlet masses are generated via radiative electroweak symmetry breaking, we obtain much higher levels of dark matter abundance. At one-loop level we find abundances of 10%-100% with 106 GeV < Ms < 120 GeV. However, when the higher-order effects needed for consistency with a 125 GeV Higgs mass are estimated, the abundance becomes 10%-80% for 80 GeV < Ms < 96 GeV, representing a significant decrease in the dark matter mass. The dynamical approach also predicts a small scalar-singlet self-coupling, providing a natural explanation for the astrophysical observations that place upper bounds on dark matter self-interaction. The predictions in all three approaches are within the Ms > 80 GeV detection region of the next generation XENON experiment. [ABSTRACT FROM AUTHOR]

Published

2014

8. Viable Dark Matter via Radiative Symmetry Breaking in a Scalar Singlet Higgs Portal Extension of the Standard Model.

Author

Steele, T. G., Zhi-Wei Wang, Contreras, D., and Mann, R. B.

Subjects

*DARK matter, *SYMMETRY breaking, *CONFORMAL field theory, *MASS (Physics), *ELECTROWEAK interactions

Abstract

The article presents a research paper which focuses on the generation of dark matter mass through radiative electroweak symmetry breaking, by using a conformal standard model with a Higgs portal extension. It says that levels of dark matter abundance increase, when both Higgs and scalar singlet masses are generated via radiative electroweak symmetry breaking.

Published

2014

9. Superconductivity on the Brink of Spin-Charge Order in a Doped Honeycomb Bilayer.

Author

Vafek, Oskar, Murray, James M., and Cvetkovic, Vladimir

Subjects

*SUPERCONDUCTIVITY, *QUANTUM field theory, *QUANTUM liquids, *FERMI liquids, *SYMMETRY breaking

Abstract

Using a controlled weak-coupling renormalization group approach, we establish the mechanism of unconventional superconductivity in the vicinity of spin or charge ordered excitonic states for the case of electrons on the Bernal stacked bilayer honeycomb lattice. With one electron per site, this system, physically realized in bilayer graphene, is unstable towards a spontaneous symmetry breaking. Repulsive interactions favor excitonic order, such as a charge nematic and/or a layer antiferromagnet. We find that upon adding charge carriers to the system, the excitonic order is suppressed, and unconventional superconductivity appears in its place, before it is replaced by a Fermi liquid. We focus on firmly establishing this phenomenon using the renormalization group formalism within an idealized model with parabolic touching of conduction and valence bands. [ABSTRACT FROM AUTHOR]

Published

2014

10. Wetting of Elastic Solids on Narnopillars.

Author

Ignacio, M., Saito, Y., Smereka, P., and Pierre-Louis, O.

Subjects

*ELASTIC solids, *SURFACE tension, *SYMMETRY breaking, *MONTE Carlo method, *CONTINUUM mechanics, *SOLID state physics

Abstract

Solids and liquids are both known to exhibit Cassie-Baxter states, where a drop or a solid nanoparticle is maintained on top of pillars due to wetting forces. We point out that due to elastic strain, solid nanocrystals exhibit a behavior different from that of liquids. First, the equilibrium Cassie-Baxter state on a single pillar exhibits a spontaneous symmetry breaking due to elastic effects. The second consequence of elasticity is the existence of stable partially impaled states, resulting from a compromise between wetting forces which favor impalement and elastic strain which resists impalement. Based on kinetic Monte Carlo simulations which include elastic strain, we discuss these effects and we propose a global phase diagram for the stability of nanocrystals on nanopillars. [ABSTRACT FROM AUTHOR]

Published

2014

11. Effects of Rotational-Symmetry Breaking on Physisorption of Ortho- and Para-H2 on Ag(111).

Author

Sugimoto, Toshiki and Fukutani, Katsuyuki

Subjects

*PHYSISORPTION, *THERMAL desorption, *NUCLEAR spin, *SYMMETRY breaking, *NUCLEAR physics

Abstract

Quantum-state-selective thermal desorption of H2 weakly physisorbed on Ag(111) demonstrates significantly different desorption features between the nuclear-spin modifications. An energy shift due to the rotational-symmetry breaking induced by an anisotropic interaction affects not only the enthalpy but also the entropy of adsorption. The preexponential factor for desorption of the ortho-H2 is about three times as large as that of the para-H2. The entropy difference indicates a perpendicular orientation preference of anisotropic physisorption potential, which also suggests the importance of partial hybridization interaction for weak physisorption. [ABSTRACT FROM AUTHOR]

Published

2014

12. Geometric Phase Effects in Dynamics Near Conical Intersections: Symmetry Breaking and Spatial Localization.

Author

Ryabinkin, Ilya G. and Izmaylov, Artur F.

Subjects

*GEOMETRIC quantum phases, *SYMMETRY breaking, *LOCALIZATION (Mathematics), *EIGENANALYSIS, *QUANTUM theory

Abstract

We show that finite systems with conical intersections can exhibit spontaneous symmetry breaking which manifests itself in spatial localization of eigenstates. This localization has a geometric phase origin and is robust against variation of model parameters. The transition between localized and delocalized eigenstate regimes resembles a continuous phase transition. The localization slows down the low-energy quantum nuclear dynamics at low temperatures. [ABSTRACT FROM AUTHOR]

Published

2013

13. Absence of Static Loop-Current Magnetism at the Apical Oxygen Site in HgBa2CuO4+δ from NMR.

Author

Mounce, A. M., Sangwon Oh, Lee, Jeongseop A., Halperin, W. P., Reyes, A. P., Kuhns, P. L., Chan, M. K., Dorow, C., Ji, L., Xia, D., Zhao, X., and Greven, M.

Subjects

*MAGNETISM, *SYMMETRY breaking, *NUCLEAR magnetic resonance, *TRANSITION temperature, *NEUTRON scattering

Abstract

The simple structure of HgBa2CuO4+δ (Hg1201) is ideal among cuprates for study of the pseudogap phase as a broken symmetry state. We have performed 17O nuclear magnetic resonance on an underdoped Hg1201 crystal with a transition temperature of 74 K to look for circulating loop currents proposed theoretically and inferred from neutron scattering. The narrow spectra preclude static local fields in the pseudogap phase at the apical site, suggesting that the moments observed with neutrons are fluctuating. The nuclear magnetic resonance frequency shifts are consistent with a dipolar field from the Cu2+ site. [ABSTRACT FROM AUTHOR]

Published

2013

14. Singularity of the London Penetration Depth at Quantum Critical Points in Superconductor.

Author

Chowdhury, Debanjan, Swingle, Brian, Berg, Erez, and Sachdev, Subir

Subjects

*CRITICAL point (Thermodynamics), *SUPERCONDUCTORS, *QUANTUM theory, *MATHEMATICAL singularities, *SYMMETRY breaking, *PHASE transitions

Published

2013

15. Distinguishing between Quantum and Classical Markovian Dephasing Dissipation.

Author

Seif, Alireza, Yu-Xin Wang, and Clerk, Aashish A.

Subjects

*QUBITS, *SYMMETRY breaking, *SYMMETRY

Abstract

Understanding whether dissipation in an open quantum system is truly quantum is a question of both fundamental and practical interest. We consider n qubits subject to correlated Markovian dephasing and present a sufficient condition for when bath-induced dissipation can generate system entanglement and hence must be considered quantum. Surprisingly, we find that the presence or absence of time-reversal symmetry plays a crucial role: broken time-reversal symmetry is required for dissipative entanglement generation. Further, simply having nonzero bath susceptibilities is not enough for the dissipation to be quantum. We also present an explicit experimental protocol for identifying truly quantum dephasing dissipation and lay the groundwork for studying more complex dissipative systems and finding optimal noise mitigating strategies. [ABSTRACT FROM AUTHOR]

Published

2022

16. Gapping Fragile Topological Bands by Interactions.

Author

Turner, Ari M., Berg, Erez, and Stern, Ady

Subjects

*BOUND states, *SPACE-time symmetries, *DEGREES of freedom, *BAND gaps, *MAGIC angle spinning, *SYMMETRY breaking, *ELECTRON-electron interactions

Abstract

We consider the stability of fragile topological bands protected by space-time inversion symmetry in the presence of strong electron-electron interactions. At the single-particle level, the topological nature of the bands prevents the opening of a gap between them. In contrast, we show that when the fragile bands are half filled, interactions can open a gap in the many-body spectrum without breaking any symmetry or mixing degrees of freedom from remote bands. Furthermore, the resulting ground state is not topologically ordered. Thus, a fragile topological band structure does not present an obstruction to forming a "featureless insulator" ground state. Our construction relies on the formation of fermionic bound states of two electrons and one hole known as "trions." The trions form a band whose coupling to the electronic band enables the gap opening. This result may be relevant to the gapped state indicated by recent experiments in magic angle twisted bilayer graphene at charge neutrality. [ABSTRACT FROM AUTHOR]

Published

2022

17. Structural Amorphization-Induced Topological Order.

Author

Citian Wang, Ting Cheng, Zhirong Liu, Feng Liu, and Huaqing Huang

Subjects

*AMORPHIZATION, *PHASE transitions, *SYMMETRY breaking, *MEDIA studies, *CRYSTALS

Abstract

Electronic properties of crystals are inherently pertained to crystalline symmetry, so that amorphization that lowers and breaks symmetry is detrimental. One important crystalline property is electron band topology which is known to be weakened and destroyed by structural disorder. Here, we report a counterintuitive theoretical discovery that atomic structural disorder by amorphization can in fact induce electronic order of topology in an otherwise topologically trivial crystal. The resulting nontrivial topology is characterized by a nonzero spin Bott index, associated with robust topological edge states and quantized conductance. The underlying topological phase transition (TPT) from a trivial crystal to a topological amorphous is analyzed by mapping out a phase diagram in the degree of structural disorder using an effective medium theory. The atomic disorder is revealed to induce topological order by renormalizing the spectral gap toward nontriviality near the phase boundary. As a concrete example, we further show such TPT in amorphous stanane by first-principles calculations. Our findings point to possible observation of an electronic ordering transition accompanied by a structural disorder transition. [ABSTRACT FROM AUTHOR]

Published

2022

18. Spontaneous Symmetry Breaking in a Coherently Driven Nanophotonic Bose-Hubbard Dimer.

Author

Garbin, B., Giraldo, A., Peters, K. J. H., Broderick, N. G. R., Spakman, A., Raineri, F., Levenson, A., Rodriguez, S. R. K., Krauskopf, B., and Yacomotti, A. M.

Subjects

*SYMMETRY breaking, *MIRROR symmetry, *OPTICAL resonators, *PHOTONIC crystals, *PHOTON correlation

Abstract

We report on the first experimental observation of spontaneous mirror symmetry breaking (SSB) in coherently driven-dissipative coupled optical cavities. SSB is observed as the breaking of the spatial or mirror Z2 symmetry between two symmetrically pumped and evanescently coupled photonic crystal nanocavities, and manifests itself as random intensity localization in one of the two cavities. We show that, in a system featuring repulsive boson interactions (U>0), the observation of a pure pitchfork bifurcation requires negative photon hopping energies (J<0), which we have realized in our photonic crystal molecule. SSB is observed over a wide range of the two-dimensional parameter space of driving intensity and detuning, where we also find a region that exhibits bistable symmetric behavior. Our results pave the way for the experimental study of limit cycles and deterministic chaos arising from SSB, as well as the study of nonclassical photon correlations close to SSB transitions. [ABSTRACT FROM AUTHOR]

Published

2022

19. Circular Dichroism of Emergent Chiral Stacking Orders in Quasi-One-Dimensional Charge Density Waves.

Author

Sun-Woo Kim, Hyun-Jung Kim, Sangmo Cheon, and Tae-Hwan Kim

Subjects

*CHARGE density waves, *MIRROR symmetry, *LUMINESCENCE measurement, *OPTICAL properties, *SYMMETRY breaking, *CIRCULAR dichroism, *SCANNING tunneling microscopy

Abstract

Chirality-driven optical properties in charge density waves are of fundamental and practical importance. Here, we investigate the interaction between circularly polarized light and emergent chiral stacking orders in quasi-one-dimensional (quasi-1D) charge-density waves (CDWs) with density-functional theory calculations. In our specific system, self-assembled In nanowires on a Si(111) surface, spontaneous mirror symmetry breaking leads to four symmetrically distinct degenerate quasi-1D CDW structures, which exhibit geometrical chirality. Such geometrical chirality may naturally induce optically active phenomena even when the quasi-1D CDW structures are stacked perpendicular to the CDW chain direction. Indeed, we find that left- and right-chiral stacking orders show distinct circular dichroism responses while a nonchiral stacking order has no circular dichroism. Such optical responses are attributed to the existence of glide mirror symmetry of the CDW stacking orders. Our findings suggest that the CDW chiral stacking orders can lead to diverse active optical phenomena such as chirality-dependent circular dichroism, which can be observed in scanning tunneling luminescence measurements with circularly polarized light. [ABSTRACT FROM AUTHOR]

Published

2022

20. Spontaneous Tilt of Single-Clamped Thermal Elastic Sheets.

Author

Zhitao Chen, Duanduan Wan, and Bowick, Mark J.

Subjects

*MOLECULAR dynamics, *PHASE diagrams, *SYMMETRY breaking

Abstract

Very thin elastic sheets, even at zero temperature, exhibit nonlinear elastic response by virtue of their dominant bending modes. Their behavior is even richer at finite temperature. Here, we use molecular dynamics to study the vibrations of a thermally fluctuating two-dimensional elastic sheet with one end clamped at its zero-temperature length. We uncover a tilted phase in which the sheet fluctuates about a mean configuration inclined with respect to the horizontal, thus breaking reflection symmetry. We determine the phase behavior as a function of the aspect ratio of the sheet and the temperature. We show that tilt may be viewed as a type of transverse buckling instability induced by clamping coupled to thermal fluctuations and develop an analytic model that predicts the tilted and untilted regions of the phase diagram. Qualitative agreement is found with the molecular dynamics simulations. Unusual response driven by control of purely geometric quantities like the aspect ratio, as opposed to external fields, offers a very rich playground for two-dimensional mechanical metamaterials. [ABSTRACT FROM AUTHOR]

Published

2022

21. Model of Persistent Breaking of Discrete Symmetry.

Author

Chai, Noam, Dymarsky, Anatoly, and Smolkin, Michael

Subjects

*DISCRETE symmetries, *SYMMETRY breaking, *PERTURBATION theory, *HIGH temperatures

Abstract

We show there exist UV-complete field-theoretic models in general dimension, including 2+1, with the spontaneous breaking of a global symmetry, which persists to the arbitrarily high temperatures. Our example is a conformal vector model with the O(N)×Z2 symmetry at zero temperature. Using conformal perturbation theory we establish Z2 symmetry is broken at finite temperature for N>17. Similar to recent constructions of [N. Chai et al., Phys. Rev. D 102, 065014 (2020)., N. Chai et al., Phys. Rev. Lett. 125, 131603 (2020).], in the infinite N limit our model has a nontrivial conformal manifold, a moduli space of vacua, which gets deformed at finite temperature. Furthermore, in this regime the model admits a persistent breaking of O(N) in 2+1 dimensions, therefore providing another example where the Coleman-Hohenberg-Mermin-Wagner theorem can be bypassed. [ABSTRACT FROM AUTHOR]

Published

2022

22. Fate of ℂℙN-1 Fixed Points with q Monopoles.

Author

Block, Matthew S., Melko, Roger G., and Kaul, Ribhu K.

Subjects

*MAGNETIC monopoles, *QUANTUM Monte Carlo method, *VALENCE bond calculation, *SYMMETRY breaking, *GEOMETRIC quantum phases

Abstract

We present an extensive quantum Monte Carlo study of the Néel to valence-bond solid (VBS) phase transition on rectangular- and honeycomb-lattice SU(N) antiferromagnets in sign-problem-free models. We find that in contrast to the honeycomb lattice and previously studied square-lattice systems, on the rectangular lattice for small N, a first-order Néel-VBS transition is realized. On increasing N⩾4, we observe that the transition becomes continuous and with the same universal exponents as found on the honeycomb and square lattices (studied here for N=5, 7, 10), providing strong support for a deconfined quantum critical point. Combining our new results with previous numerical and analytical studies, we present a general phase diagram of the stability of ℂℙN-1 fixed points with q monopoles. [ABSTRACT FROM AUTHOR]

Published

2013

23. Chiral Superfluid States in Hybrid Graphene Heterostructures.

Author

Junhua Zhang and Rossi, E.

Subjects

*SUPERFLUIDITY, *CHIRALITY, *ELECTRIC properties of graphene, *SYMMETRY breaking, *HETEROSTRUCTURES, *DEGENERATE perturbation theory

Abstract

We study the "hybrid" heterostructure formed by one sheet of single-layer graphene (SLG) and one sheet of bilayer graphene (BLG) separated by a thin film of dielectric material. In general, it is expected that interlayer interactions can drive the system to a spontaneously broken-symmetry state characterized by interlayer phase coherence. The peculiarity of the SLG-BLG heterostructure is that the electrons in the two layers have different chiralities. We find that this difference causes the spontaneously broken-symmetry state to be N-fold degenerate. Moreover, we find that some of the degenerate states are chiral superfluid states, topologically distinct from the usual layer ferromagnetism. The chiral nature of the ground state opens the possibility to realize protected midgap states. The N-fold degeneracy of the ground state makes the physics of SLG-BLG hybrid systems analogous to the physics of 3He, in particular given the recent discovery of chiral superfluid states in this system. [ABSTRACT FROM AUTHOR]

Published

2013

24. Higgs Seesaw Mechanism as a Source for Dark Energy.

Author

Krauss, Lawrence M. and Dent, James B.

Subjects

*HIGGS bosons, *DARK energy, *NEUTRINOS, *NEUTRINO mass, *ENERGY density, *SYMMETRY breaking

Abstract

Motivated by the seesaw mechanism for neutrinos which naturally generates small neutrino masses, we explore how a small grand-unified-theory-scale mixing between the standard model Higgs boson and an otherwise massless hidden sector scalar can naturally generate a small mass and vacuum expectation value for the new scalar which produces a false vacuum energy density contribution comparable to that of the observed dark energy dominating the current expansion of the Universe. This provides a simple and natural mechanism for producing the correct scale for dark energy, even if it does not address the long-standing question of why much larger dark energy contributions are not produced from the visible sector. The new scalar produces no discernible signatures in existing terrestrial experiments so that one may have to rely on other cosmological tests of this idea. [ABSTRACT FROM AUTHOR]

Published

2013

25. Observation of Self-Induced Optical Vortex Precession.

Author

Ketara, Mohamed El and Brasselet, Etienne

Subjects

*SELF-induced transparency, *LIQUID crystals, *SYMMETRY breaking, *HALL effect, *GALVANOMAGNETIC effects

Abstract

We report on the observation of self-induced precession of an optical vortex as a result of the nonlinear interaction between light and liquid crystals. The phenomenon corresponds to an instability for the spin-orbit interaction of light that manifests as a spontaneous axial symmetry breaking, which leads to the orbital motion of the optical vortex around the beam propagation. A nonlinear spin Hall effect of light is experimentally identified, thereby unveiling an original demonstration of spin to extrinsic orbital light angular momentum self-conversion. [ABSTRACT FROM AUTHOR]

Published

2013

26. Broken Symmetries, Zero-Energy Modes, and Quantum Transport in Disordered Graphene: From Supermetallic to Insulating Regimes.

Author

Cresti, Alessandro, Ortmann, Frank, Louvet, Thibaud, Van Tuan, Dinh, and Roche, Stephan

Subjects

*ELECTRIC properties of graphene, *SYMMETRY breaking, *KLEIN paradox, *QUANTUM Hall effect, *ANDERSON localization, *SCANNING tunneling microscopy

Abstract

The role of defect-induced zero-energy modes on charge transport in graphene is investigated using Kubo and Landauer transport calculations. By tuning the density of random distributions of monovacancies either equally populating the two sublattices or exclusively located on a single sublattice, all conduction regimes are covered from direct tunneling through evanescent modes to mesoscopic transport in bulk disordered graphene. Depending on the transport measurement geometry, defect density, and broken sublattice symmetry, the Dirac-point conductivity is either exceptionally robust against disorder (supermetallic state) or suppressed through a gap opening or by algebraic localization of zero-energy modes, whereas weak localization and the Anderson insulating regime are obtained for higher energies. These findings clarify the contribution of zero-energy modes to transport at the Dirac point, hitherto controversial. [ABSTRACT FROM AUTHOR]

Published

2013

27. Exchange-Coupling-Induced Symmetry Breaking in Topological Insulators.

Author

Peng Wei, Katmis, Ferhat, Assaf, Badih A., Steinberg, Hadar, Jarillo-Herrero, Pablo, Heiman, Donald, and Moodera, Jagadeesh S.

Subjects

*SYMMETRY breaking, *TOPOLOGICAL insulators, *MAGNETOELECTRIC effect, *FERROMAGNETISM, *QUANTUM Hall effect

Abstract

An exchange gap in the Dirac surface states of a topological insulator (TI) is necessary for observing the predicted unique features such as the topological magnetoelectric effect as well as to confine Majorana fermions. We experimentally demonstrate proximity-induced ferromagnetism in a TI, combining a ferromagnetic insulator EuS layer with Bi2Se3, without introducing defects. By magnetic and magneto-transport studies, including anomalous Hall effect and magnetoresistance measurements, we show the emergence of a ferromagnetic phase in TI, a step forward in unveiling their exotic properties. [ABSTRACT FROM AUTHOR]

Published

2013

28. Real-Time Manifestation of Strongly Coupled Spin and Charge Order Parameters in Stripe-Ordered La1.75Sr0.25NiO4 Nickelate Crystals Using Time-Resolved Resonant X-Ray Diffraction.

Author

Chuang, Y. D., Lee, W. S., Kung, Y. F., Sorini, A. P., Moritz, B., Moore, R. G., Patthey, L., Trigo, M., Lu, D. H., Kirchmann, P. S., Yi, M., Krupin, O., Langner, M., Zhu, Y., Zhou, S. Y., Reis, D. A., Huse, N., Robinson, J. S., Kaindl, R. A., and Schoenlein, R. W.

Subjects

*NICKEL electrometallurgy, *X-ray diffraction, *SYMMETRY breaking, *ANTIFERROMAGNETISM, *SPIN-spin interactions

Abstract

We investigate the order parameter dynamics of the stripe-ordered nickelate, La1.75Sr0.25NiO4, using time-resolved resonant x-ray diffraction. In spite of distinct spin and charge energy scales, the two order parameters' amplitude dynamics are found to be linked together due to strong coupling. Additionally, the vector nature of the spin sector introduces a longer reorientation time scale which is absent in the charge sector. These findings demonstrate that the correlation linking the symmetry-broken states does not unbind during the nonequilibrium process, and the time scales are not necessarily associated with the characteristic energy scales of individual degrees of freedom. [ABSTRACT FROM AUTHOR]

Published

2013

29. Atomic Quantum Simulation of U(N) and SU(N) Non-Abelian Lattice Gauge Theories.

Author

Banerjee, D., Bögli, M., Dalmonte, M., Rico, E., Stebler, P., Wiese, U.-J., and Zoller, P.

Subjects

*SIMULATION methods & models, *LATTICE gauge theories, *ALKALINE earth compounds, *OPTICAL lattices, *CHIRALITY of nuclear particles, *SYMMETRY breaking

Abstract

Using ultracold alkaline-earth atoms in optical lattices, we construct a quantum simulator for U(N) and SU(N) lattice gauge theories with fermionic matter based on quantum link models. These systems share qualitative features with QCD, including chiral symmetry breaking and restoration at nonzero temperature or baryon density. Unlike classical simulations, a quantum simulator does not suffer from sign problems and can address the corresponding chiral dynamics in real time. [ABSTRACT FROM AUTHOR]

Published

2013

30. Sharp Raman Anomalies and Broken Adiabaticity at a Pressure Induced Transition from Band to Topological Insulator in Sb2Se3.

Author

Bera, Achintya, Pal, Koushik, Muthu, D. V. S., Sen, Somaditya, Guptasarma, Prasenjit, Waghmare, U. V., and Sood, A. K.

Subjects

*RAMAN effect, *SYMMETRY breaking, *PRESSURE, *PHASE transitions, *ENERGY bands, *TOPOLOGICAL insulators, *ANTIMONY, *ELECTRIC insulators & insulation

Abstract

The nontrivial electronic topology of a topological insulator is thus far known to display signatures in a robust metallic state at the surface. Here, we establish vibrational anomalies in Raman spectra of the bulk that signify changes in electronic topology: an E² phonon softens unusually and its linewidth exhibits an asymmetric peak at the pressure induced electronic topological transition (ETT) in Sb2Se3 crystal. Our first-principles calculations confirm the electronic transition from band to topological insulating state with reversal of parity of electronic bands passing through a metallic state at the ETT, but do not capture the phonon anomalies which involve breakdown of adiabatic approximation due to strongly coupled dynamics of phonons and electrons. Treating this within a four-band model of topological insulators, we elucidate how nonadiabatic renormalization of phonons constitutes readily measurable bulk signatures of an ETT, which will facilitate efforts to develop topological insulators by modifying a band insulator. [ABSTRACT FROM AUTHOR]

Published

2013

31. Superspin Glass Mediated Giant Spontaneous Exchange Bias in a Nanocomposite of BiFeO3-Bi2Fe4O9.

Author

Maity, Tuhin, Goswami, Sudipta, Bhattacharya, Dipten, and Roy, Saibal

Subjects

*SPIN glasses, *NANOCOMPOSITE materials, *FERRITES, *TEMPERATURE effect, *COOLING, *SYMMETRY breaking, *ANISOTROPY

Abstract

We observe an enormous spontaneous exchange bias (~300-600 Oe)--measured in an unmagnetized state following zero-field cooling--in a nanocomposite of BiFe03 (~94%)-Bi2Fe409 (~6%) over a temperature range 5-300 K. Depending on the path followed in tracing the hysteresis loop--positive (p) or negative (n)--as well as the maximum field applied, the exchange bias (HE) varies significantly with | -- HEp | > | HEn |. The temperature dependence of HE is nonmonotonic. It increases, initially, till ~150 K and then decreases as the blocking temperature TB is approached. All these rich features appear to be originating from the spontaneous symmetry breaking and consequent onset of unidirectional anisotropy driven by "superinteraction bias coupling" between the ferromagnetic core of Bi2Fe4O9 (of average size ~19 nm) and the canted antiferromagnetic structure of BiFeO3 (of average size --112 nm) via superspin glass moments at the shell. [ABSTRACT FROM AUTHOR]

Published

2013

32. Nonlinear Symmetry Breaking Induced by Third-Order Dispersion in Optical Fiber Cavities.

Author

Leo, François, Mussot, Arnaud, Kockaert, Pascal, Emplit, Philippe, Haelterman, Marc, and Taki, Majid

Subjects

*SYMMETRY breaking, *NONLINEAR systems, *DISPERSION (Chemistry), *OPTICAL fibers, *NUMERICAL analysis, *PHYSICS experiments, *SPECTRUM analysis

Abstract

We study analytically, numerically, and experimentally the nonlinear symmetry breaking induced by broken reflection symmetry in an optical fiber system. In particular, we investigate the modulation instability regime and reveal the key role of the third-order dispersion on the asymmetry in the spectrum of the dissipative structures. Our theory explains early observations, and the predictions are in excellent agreement with our experimental findings. [ABSTRACT FROM AUTHOR]

Published

2013

33. Spontaneous Time-Reversal Symmetry Breaking for Spinless Fermions on a Triangular Lattice.

Author

Tieleman, O., Dutta, O., Lewenstein, M., and Eckardt, A.

Subjects

*SYMMETRY breaking, *TIME reversal, *FERMIONS, *NUCLEAR spin, *OPTICAL lattices, *MATHEMATICAL models

Abstract

As a minimal fermionic model with kinetic frustration, we study a system of spinless fermions in the lowest band of a triangular lattice with nearest-neighbor repulsion. We find that the combination of interactions and kinetic frustration leads to spontaneous symmetry breaking in various ways. Time-reversal symmetry can be broken by two types of loop current patterns, a chiral one and one that breaks the translational lattice symmetry. Moreover, the translational symmetry can also be broken by a density wave forming a kagome pattern or by a Peierls-type trimerization characterized by enhanced correlations among the sites of certain triangular plaquettes (giving a plaquette-centered density wave). We map out the phase diagram as it results from leading-order Ginzburg-Landau mean-field theory. Several experi-mental realizations of the type of system under study are possible with ultracold atoms in optical lattices. [ABSTRACT FROM AUTHOR]

Published

2013

34. Optical Diode Made from a Moving Photonic Crystal.

Author

Wang, Da-Wei, Zhou, Hai-Tao, Guo, Miao-Jun, Zhang, Jun-Xiang, Evers, Jorg, and Zhu, Shi-Yao

Subjects

*PHOTONIC crystals, *DIODES, *OPTICAL information processing, *SYMMETRY breaking, *MAGNETIC fields, *REFRACTIVE index

Abstract

Optical diodes controlling the flow of light are of principal significance for optical information processing. They transmit light from an input to an output, but not in the reverse direction. This breaking of time reversal symmetry is conventionally achieved via Faraday or nonlinear effects. For applications in a quantum network, features such as the abilities of all-optical control, on-chip integration, and single-photon operation are important. Here we propose an all-optical optical diode which requires neither magnetic fields nor strong input fields. It is based on a "moving" photonic crystal generated in a three-level electromagnetically induced transparency medium in which the refractive index of a weak probe is modulated by the moving periodic intensity of a strong standing coupling field with two detuned counterpropagating components. Because of the Doppler effect, the frequency range of the crystal's band gap for the probe copropagating with the moving crystal is shifted from that for the counter-propagating probe. This mechanism is experimentally demonstrated in a room temperature Cs vapor cell. [ABSTRACT FROM AUTHOR]

Published

2013

35. Substrate-Induced Symmetry Breaking in Silicene.

Author

Chun-Liang Lin, Arafune, Ryuichi, Kawahara, Kazuaki, Kanno, Mao, Tsukahara, Noriyuki, Minamitani, Emi, Yousoo Kim, Kawai, Maki, and Takagi, Noriaki

Subjects

*SUBSTRATES (Materials science), *SYMMETRY breaking, *HONEYCOMB structures, *MAGNETIC fields, *DENSITY functionals

Abstract

We demonstrate that silicene, a 2D honeycomb lattice consisting of Si atoms, loses its Dirac fermion characteristics due to substrate-induced symmetry breaking when synthesized on the Ag(111) surface. No Landau level sequences appear in the tunneling spectra under a magnetic field, and density functional theory calculations show that the band structure is drastically modified by the hybridization between the Si and Ag atoms. This is the first direct example demonstrating the lack of Dirac fermions in a single layer honeycomb lattice due to significant symmetry breaking. [ABSTRACT FROM AUTHOR]

Published

2013

36. Classical Time Crystals.

Author

Shapere, Alfred and Wilczek, Frank

Subjects

*DYNAMICAL systems, *QUANTUM theory, *ENERGY levels (Quantum mechanics), *FORCE & energy, *MATHEMATICAL singularities, *LAGRANGE equations, *SYMMETRY breaking

Abstract

We consider the possibility that classical dynamical systems display motion in their lowest-energy state, forming a time analogue of crystalline spatial order. Challenges facing that idea are identified and overcome. We display arbitrary orbits of an angular variable as lowest-energy trajectories for nonsingular Lagrangian systems. Dynamics within orbits of broken symmetry provide a natural arena for formation of time crystals. We exhibit models of that kind, including a model with traveling density waves. [ABSTRACT FROM AUTHOR]

Published

2012

37. Symmetry Protected Topological Order and Spin Susceptibility in Superfluid ³He-B.

Author

Mizushima, Takeshi, Sato, Masatoshi, and Machida, Kazushige

Subjects

*SYMMETRY breaking, *NUCLEAR spin, *SUPERFLUIDITY, *HELIUM, *MAGNETIC fields, *ZEEMAN effect, *CRITICALITY (Nuclear engineering)

Abstract

We here demonstrate that the superfluid 3He-ß under a magnetic field in a particular direction stays topological due to a discrete symmetry, that is, in a symmetry protected topological order. Because of the symmetry protected topological order, helical surface Majorana fermions in the Β phase remain gapless and their Ising spin character persists. We unveil that the competition between the Zeeman magnetic field and dipole interaction involves an anomalous quantum phase transition in which a topological phase transition takes place together with spontaneous symmetry breaking. Based on the quasiclassical theory, we illustrate that the phase transition is accompanied by anisotropic quantum criticality of spin susceptibilities on the surface, which is detectable in NMR experiments. [ABSTRACT FROM AUTHOR]

Published

2012

38. Quantum Time Crystals.

Author

Wilczek, Frank

Subjects

*QUANTUM theory, *SYMMETRY breaking, *MATHEMATICAL models, *MATHEMATICAL physics, *SYMMETRY (Physics), *CRYSTALLOGRAPHY

Abstract

Some subtleties and apparent difficulties associated with the notion of spontaneous breaking of time-translation symmetry in quantum mechanics are identified and resolved. A model exhibiting that phenomenon is displayed. The possibility and significance of breaking of imaginary time-translation symmetry is discussed. [ABSTRACT FROM AUTHOR]

Published

2012

39. Space-Time Crystals of Trapped Ions.

Author

Li, Tongcang, Gong, Zhe-Xuan, Yin, Zhang-Qi, and Quan, H. T.

Subjects

*ION traps, *SYMMETRY breaking, *MAGNETIC fields, *TEMPERATURE effect, *MANY-body problem, *QUANTUM theory, *COULOMB potential

Abstract

Spontaneous symmetry breaking can lead to the formation of time crystals, as well as spatial crystals. Here we propose a space-time crystal of trapped ions and a method to realize it experimentally by confining ions in a ring-shaped trapping potential with a static magnetic field. The ions spontaneously form a spatial ring crystal due to Coulomb repulsion. This ion crystal can rotate persistently at the lowest quantum energy state in magnetic fields with fractional fluxes. The persistent rotation of trapped ions produces the temporal order, leading to the formation of a space-time crystal. We show that these space-time crystals are robust for direct experimental observation. We also study the effects of finite temperatures on the persistent rotation. The proposed space-time crystals of trapped ions provide a new dimension for exploring many-body physics and emerging properties of matter. [ABSTRACT FROM AUTHOR]

Published

2012

40. Autonomous Motility of Active Filaments due to Spontaneous Flow-Symmetry Breaking.

Author

Jayaraman, Gayathri, Ramachandran, Sanoop, Ghose, Somdeb, Laskar, Abhrajit, Bhamla, M. Saad, Kumar, P. B. Sunil, and Adhikari, R.

Subjects

*SYMMETRY breaking, *STOKES equations, *HYDRODYNAMICS, *SIMULATION methods & models, *ELASTICITY, *STRAINS & stresses (Mechanics), *CONFORMATIONAL analysis, *FLUCTUATIONS (Physics)

Abstract

We simulate the nonlocal Stokesian hydrodynamics of an elastic filament which is active due a permanent distribution of stresslets along its contour. A bending instability of an initially straight filament spontaneously breaks flow symmetry and leads to autonomous filament motion which, depending on conformational symmetry, can be translational or rotational. At high ratios of activity to elasticity, the linear instability develops into nonlinear fluctuating states with large amplitude deformations. The dynamics of these states can be qualitatively understood as a superposition of translational and rotational motion associated with filament conformational modes of opposite symmetry. Our results can be tested in molecular-motor filament mixtures, synthetic chains of autocatalytic particles, or other linearly connected systems where chemical energy is converted to mechanical energy in a fluid environment. [ABSTRACT FROM AUTHOR]

Published

2012

41. Super-Rough Glassy Phase of the Random Field XY Model in Two Dimensions.

Author

Perret, Anthony, Ristivojevic, Zoran, Doussal, Pierre Le, Schehr, Grégory, and Wiese, Kay J.

Subjects

*PHASE equilibrium, *HEISENBERG model, *RENORMALIZATION group, *NUMERICAL analysis, *POLYNOMIALS, *ALGORITHMS, *TEMPERATURE effect, *SYMMETRY breaking

Abstract

We study both analytically, using the renormalization group (RG) to two loop order, and numerically, using an exact polynomial algorithm, the disorder-induced glass phase of the two-dimensional XY model with quenched random symmetry-breaking fields and without vortices. In the super-rough glassy phase, i.e., below the critical temperature Tc, the disorder and thermally averaged correlation function B(r) of the phase field ff(x), B(r) = ([0(x) - ff(x + r)]2) behaves, for r » a, as B(r) » A(r)ln2(r/a) where r = |r| and a is a microscopic length scale. We derive the RG equations up to cubic order in r = (Tc -- T)/Tc and predict the universal amplitude A(T) = 2T2 - 2r3 + 0(x4). The universality of A(r) results from non-trivial cancellations between nonuniversal constants of RG equations. Using an exact polynomial algorithm on an equivalent dimer version of the model we compute A(T) numerically and obtain a remarkable agreement with our analytical prediction, up to r » 0.5. [ABSTRACT FROM AUTHOR]

Published

2012

42. Spontaneous Symmetry Breaking of a Hinged Flapping Filament Generates Lift.

Author

Bagheri, Shervin, Mazzino, Andrea, and Bottaro, Alessandro

Subjects

*SYMMETRY breaking, *ELASTICITY, *FILAMENTOUS fungi, *VORTEX motion, *VON Karman equations, *DRAG (Aerodynamics), *FORCE & energy

Abstract

Elastic filamentous structures found on swimming and flying organisms are versatile in function, rendering their precise contribution to locomotion difficult to assess. We show in this Letter that a single passive filament hinged on the rear of a bluff body placed in a stream can generate a net lift force without increasing the mean drag force on the body. This is a consequence of spontaneous symmetry breaking in the filament's flapping dynamics. The phenomenon is related to a resonance between the frequency associated with the von Karman vortex street developing behind the bluff body and the natural frequency of the free bending vibrations of the filament. [ABSTRACT FROM AUTHOR]

Published

2012

43. Scale Hierarchy in Hořava-Lifshitz Gravity: Strong Constraint from Synchrotron Radiation in the Crab Nebula.

Author

Liberati, Stefano, Maccione, Luca, and Sotiriou, Thomas P.

Subjects

*QUANTUM gravity, *CONSTRAINTS (Physics), *SYNCHROTRON radiation, *OPERATOR theory, *SYMMETRY breaking, *CP violation, *CRAB Nebula

Abstract

Horava-Lifshitz gravity models contain higher-order operators suppressed by a characteristic scale, which is required to be parametrically smaller than the Planck scale. We show that recomputed synchrotron radiation constraints from the Crab Nebula suffice to exclude the possibility that this scale is of the same order of magnitude as the Lorentz breaking scale in the matter sector. This highlights the need for a mechanism that suppresses the percolation of Lorentz violation in the matter sector and is effective for higher-order operators as well. [ABSTRACT FROM AUTHOR]

Published

2012

44. Stimulation of the Fluctuation Superconductivity by PT Symmetry.

Author

Chtchelkatchev, N. M., Golubov, A. A., Baturina, T. I., and Vinokur, V. M.

Subjects

*FLUCTUATIONS (Physics), *SUPERCONDUCTIVITY, *PHASE transitions, *HAMILTONIAN systems, *HILBERT space, *SYMMETRY breaking, *TEMPERATURE effect

Abstract

We discuss fluctuations near the second-order phase transition where the free energy has an additional non-Hermitian term. The spectrum of the fluctuations changes when the odd-parity potential amplitude exceeds the critical value corresponding to the PT-symmetry breakdown in the topological structure of the Hilbert space of the effective non-Hermitian Hamiltonian. We calculate the fluctuation contribution to the differential resistance of a superconducting weak link and find the manifestation of the PT-symmetry breaking in its temperature evolution. We successfully validate our theory by carrying out measurements of far from equilibrium transport in mesoscale-patterned superconducting wires. [ABSTRACT FROM AUTHOR]

Published

2012

45. Non-Abelian Gauge Fields and Topological Insulators in Shaken Optical Lattices.

Author

Hauke, Philipp, Tieleman, Olivier, Celi, Alessio, Ölschläger, Christoph, Simonet, Juliette, Struck, Julian, Weinberg, Malte, Windpassinger, Patrick, Sengstock, Klaus, Lewenstein, Maciej, and Eckardt, André

Subjects

*GAUGE field theory, *NONABELIAN groups, *OPTICAL lattices, *ELECTRIC insulators & insulation, *QUANTUM Hall effect, *SYMMETRY breaking

Abstract

Time-periodic driving like lattice shaking offers a low-demanding method to generate artificial gauge fields in optical lattices. We identify the relevant symmetries that have to be broken by the driving function for that purpose and demonstrate the power of this method by making concrete proposals for its application to two-dimensional lattice systems: We show how to tune frustration and how to create and control band touching points like Dirac cones in the shaken kagome lattice. We propose the realization of a topological and a quantum spin Hall insulator in a shaken spin-dependent hexagonal lattice. We describe how strong artificial magnetic fields can be achieved for example in a square lattice by employing superlattice modulation. Finally, exemplified on a shaken spin-dependent square lattice, we develop a method to create strong non-Abelian gauge fields. [ABSTRACT FROM AUTHOR]

Published

2012

46. Oriented Rotational Wave-Packet Dynamics Studies via High Harmonic Generation.

Author

Frumker, E., Hebeisen, C. T., Kajumba, N., Bertrand, J. B., Wörner, H. J., Spanner, M., Villeneuve, D. M., Naumov, A., and Corkum, P. B.

Subjects

*SHEAR waves, *WAVE packets, *DYNAMICS, *FEMTOSECOND pulses, *SECOND harmonic generation, *SYMMETRY breaking, *RADIATION

Abstract

We produce oriented rotational wave packets in CO and measure their characteristics via high harmonic generation. The wave packet is created using an intense, femtosecond laser pulse and its second harmonic. A delayed 800 nm pulse probes the wave packet, generating even-order high harmonics that arise from the broken symmetry induced by the orientation dynamics. The even-order harmonic radiation that we measure appears on a zero background, enabling us to accurately follow the temporal evolution of the wave packet. Our measurements reveal that, for the conditions optimum for harmonic generation, the orientation is produced by preferential ionization which depletes the sample of molecules of one orientation. [ABSTRACT FROM AUTHOR]

Published

2012

47. Assisted Finite-Rate Adiabatic Passage Across a Quantum Critical Point: Exact Solution for the Quantum Ising Model.

Author

Campo, Adolfo del, Rams, Marek M., and Zurek, Wojciech H.

Subjects

*ADIABATIC processes, *QUANTUM theory, *CRITICAL point (Thermodynamics), *ISING model, *SYMMETRY breaking, *QUANTUM phase transitions, *HAMILTONIAN systems

Abstract

The dynamics of a quantum phase transition is inextricably woven with the formation of excitations, as a result of critical slowing down in the neighborhood of the critical point. We design a transitionless quantum driving through a quantum critical point, allowing one to access the ground state of the broken-symmetry phase by a finite-rate quench of the control parameter. The method is illustrated in the one-dimensional quantum Ising model in a transverse field. Driving through the critical point is assisted by an auxiliary Hamiltonian, for which the interplay between the range of the interaction and the modes where excitations are suppressed is elucidated. [ABSTRACT FROM AUTHOR]

Published

2012

48. Geometric Mechanics of Curved Crease Origami.

Author

Dias, Marcelo A., Dudte, Levi H., Mahadevan, L., and Santangelo, Christian D.

Subjects

*COMPUTER simulation, *PAPER, *ASYMPTOTIC expansions, *CURVATURE, *OSCILLATIONS, *SYMMETRY breaking, *TORSION

Abstract

Folding a sheet of paper along a curve can lead to structures seen in decorative art and utilitarian packing boxes. Here we present a theory for the simplest such structure: an annular circular strip that is folded along a central circular curve to form a three-dimensional buckled structure driven by geometrical frustration. We quantify this shape in terms of the radius of the circle, the dihedral angle of the fold, and the mechanical properties of the sheet of paper and the fold itself. When the sheet is isometrically deformed everywhere except along the fold itself, stiff folds result in creases with constant curvature and oscillatory torsion. However, relatively softer folds inherit the broken symmetry of the buckled shape with oscillatory curvature and torsion. Our asymptotic analysis of the isometrically deformed state is corroborated by numerical simulations that allow us to generalize our analysis to study structures with multiple curved creases. [ABSTRACT FROM AUTHOR]

Published

2012

49. Andreev Bound States in a One-Dimensional Topological Superconductor.

Author

Liu, Xiong-Jun

Subjects

*BOUND states, *ANDREEV reflection, *CHARGE transfer, *SYMMETRY breaking, *FERMIONS, *HOLES (Electron deficiencies), *TUNNELING spectroscopy, *TOPOLOGY, *SUPERCONDUCTORS

Abstract

We study the charge character of the Andreev bound states (ABSs) in one-dimensional topological superconductors with spatial inversion symmetry (SIS) breaking. Despite the absence of the SIS, we show a hidden symmetry for the Bogoliubov-de Gennes equations around Fermi points in addition to the particle-hole symmetry. This hidden symmetry protects that the charge of the ABSs is solely dependent on the corresponding Fermi velocities. On the other hand, if the SIS is present, the ABSs are charge neutral, similar to Majorana fermions. We also propose that the charge of the ABSs can be experimentally measured in the tunneling transport spectroscopy from the resonant differential tunneling conductance. [ABSTRACT FROM AUTHOR]

Published

2012

50. Coulomb Energy Difference as a Probe of Isospin-Symmetry Breaking in the Upper fp-Shell Nuclei.

Author

Kaneko, K., Mizusaki, T., Sun, Y., Tazaki, S., and de Angelis, G.

Subjects

*COULOMB potential, *NUCLEAR energy, *ISOBARIC spin, *SYMMETRY breaking, *NUCLEAR shell theory, *COLLISIONS (Nuclear physics), *NUCLEAR excitation, *SPIN-orbit interactions, *ELECTROMAGNETISM

Abstract

The anomaly in Coulomb energy differences (CEDs) between the isospin T = 1 states in the odd-odd N = Z nucleus 70Br and the analogue states in its even-even partner 70Se has remained a puzzle. This is a direct manifestation of isospin-symmetry breaking in effective nuclear interactions. Here, we perform large-scale shell-model calculations for nuclei with A = 66 to 78 using the new filter diagonalization method based on the Sakurai-Sugiura algorithm. The calculations reproduce well the experimental CED. The observed negative CED for A = 70 are accounted for by the cross-shell neutron excitations from the fp shell to the g9/2 intruder orbit with the enhanced electromagnetic spin-orbit contribution at this special nucleon number. [ABSTRACT FROM AUTHOR]

Published

2012