646 research outputs found
Excitonic pairing between nodal fermions
We study excitonic pairing in nodal fermion systems characterized by a
vanishing quasiparticle density of states at the pointlike Fermi surface and a
concomitant lack of screening for long-range interactions. By solving the gap
equation for the excitonic order parameter, we obtain a critical value of the
interaction strength for a variety of power-law interactions and densities of
states. We compute the free energy and analyze possible phase transitions, thus
shedding further light on the unusual pairing properties of this peculiar class
of strongly correlated systems.Comment: 9 pages, 7 figures, minor revisions made, final versio
Spin dynamics of the quasi two dimensional spin-1/2 quantum magnet Cs_2CuCl_4
We study dynamical properties of the anisotropic triangular quantum
antiferromagnet Cs_2CuCl_4. Inelastic neutron scattering measurements have
established that the dynamical spin correlations cannot be understood within a
linear spin wave analysis. We go beyond linear spin wave theory by taking
interactions between magnons into account in a 1/S expansion. We determine the
dynamical structure factor and carry out extensive comparisons with
experimental data. We find that compared to linear spin wave theory a
significant fraction of the scattering intensity is shifted to higher energies
and strong scattering continua are present. However, the 1/S expansion fails to
account for the experimentally observed large quantum renormalization of the
exchange energies.Comment: 13 pages, 11 figures, higher quality figures can be obtained from the
author
Ground states of a frustrated spin-1/2 antifferomagnet: Cs_2CuCl_4 in a magnetic field
We present detailed calculations of the magnetic ground state properties of
CsCuCl in an applied magnetic field, and compare our results with
recent experiments. The material is described by a spin Hamiltonian, determined
with precision in high field measurements, in which the main interaction is
antiferromagnetic Heisenberg exchange between neighboring spins on an
anisotropic triangular lattice. An additional, weak Dzyaloshinkii-Moriya
interaction introduces easy-plane anisotropy, so that behavior is different for
transverse and longitudinal field directions. We determine the phase diagram as
a function of field strength for both field directions at zero temperature,
using a classical approximation as a first step. Building on this, we calculate
the effect of quantum fluctuations on the ordering wavevector and components of
the ordered moments, using both linear spinwave theory and a mapping to a Bose
gas which gives exact results when the magnetization is almost saturated. Many
aspects of the experimental data are well accounted for by this approach.Comment: 13 Pages, 9 Figure
Commensurate and incommensurate ground states of Cs_2CuCl_4 in a magnetic field
We present calculations of the magnetic ground state of Cs_2CuCl_4 in an
applied magnetic field, with the aim of understanding the commensurately
ordered state that has been discovered in recent experiments. This layered
material is a realization of a Heisenberg antiferromagnet on an anisotropic
triangular lattice. Its behavior in a magnetic field depends on field
orientation, because of weak Dzyaloshinskii-Moriya interactions.We study the
system by mapping the spin-1/2 Heisenberg Hamiltonian onto a Bose gas with hard
core repulsion. This Bose gas is dilute, and calculations are controlled, close
to the saturation field. We find a zero-temperature transition between
incommensurate and commensurate phases as longitudinal field strength is
varied, but only incommensurate order in a transverse field. Results for both
field orientations are consistent with experiment.Comment: 5 Pages, 3 Figure
Activation by SLAM Family Receptors Contributes to NK Cell Mediated "Missing-Self" Recognition.
Natural Killer (NK) cells attack normal hematopoietic cells that do not express inhibitory MHC class I (MHC-I) molecules, but the ligands that activate NK cells remain incompletely defined. Here we show that the expression of the Signaling Lymphocyte Activation Molecule (SLAM) family members CD48 and Ly9 (CD229) by MHC-I-deficient tumor cells significantly contributes to NK cell activation. When NK cells develop in the presence of T cells or B cells that lack inhibitory MHC-I but express activating CD48 and Ly9 ligands, the NK cells' ability to respond to MHC-I-deficient tumor cells is severely compromised. In this situation, NK cells express normal levels of the corresponding activation receptors 2B4 (CD244) and Ly9 but these receptors are non-functional. This provides a partial explanation for the tolerance of NK cells to MHC-I-deficient cells in vivo. Activating signaling via 2B4 is restored when MHC-I-deficient T cells are removed, indicating that interactions with MHC-I-deficient T cells dominantly, but not permanently, impair the function of the 2B4 NK cell activation receptor. These data identify an important role of SLAM family receptors for NK cell mediated "missing-self" reactivity and suggest that NK cell tolerance in MHC-I mosaic mice is in part explained by an acquired dysfunction of SLAM family receptors
Vortex lattice stability in the SO(5) model
We study the energetics of superconducting vortices in the SO(5) model for
high- materials proposed by Zhang. We show that for a wide range of
parameters normally corresponding to type II superconductivity, the free energy
per unit flux \FF(m) of a vortex with flux quanta is a decreasing
function of , provided the doping is close to its critical value. This
implies that the Abrikosov lattice is unstable, a behaviour typical of type I
superconductors. For dopings far from the critical value, \FF(m) can become
very flat, indicating a less rigid vortex lattice, which would melt at a lower
temperature than expected for a BCS superconductor.Comment: 4 pp, revtex, 5 figure
Weak Ferromagnetism and Excitonic Condensates
We investigate a model of excitonic ordering (i.e electron-hole pair
condensation) appropriate for the divalent hexaborides. We show that the
inclusion of imperfectly nested electron hole Fermi surfaces can lead to the
formation of an undoped excitonic metal phase. In addition, we find that weak
ferromagnetism with compensated moments arises as a result of gapless
excitations. We study the effect of the low lying excitations on the density of
states, Fermi surface topology and optical conductivity and compare to
available experimental data.Comment: 10 Pages, 8 Figures, RevTe
Quasiparticles in the 111 state and its compressible ancestors
We investigate the relationship of the spontaneously inter-layer coherent
``111''state of quantum Hall bilayers at total filling factor \nu=1 to
``mutual'' composite fermions, in which vortices in one layer are bound to
electrons in the other. Pairing of the mutual composite fermions leads to the
low-energy properties of the 111 state, as we explicitly demonstrate using
field-theoretic techniques. Interpreting this relationship as a mechanism for
inter-layer coherence leads naturally to two candidate states with
non-quantized Hall conductance: the mutual composite Fermi liquid, and an
inter-layer coherent charge e Wigner crystal. The experimental behavior of the
interlayer tunneling conductance and resistivity tensors are discussed for
these states.Comment: 4 Pages, RevTe
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