565 research outputs found
Interdependence of magnetism and superconductivity in the borocarbide TmNi2B2C
We have discovered a new antiferromagnetic phase in TmNi2B2C by neutron
diffraction. The ordering vector is Q_A = (0.48,0,0) and the phase appears
above a critical in-plane magnetic field of 0.9 T. The field was applied in
order to test the assumption that the zero-field magnetic structure at Q_F =
(0.094,0.094,0) would change into a c-axis ferromagnet if superconductivity
were destroyed. We present theoretical calculations which show that two effects
are important: A suppression of the ferromagnetic component of the RKKY
exchange interaction in the superconducting phase, and a reduction of the
superconducting condensation energy due to the periodic modulation of the
moments at the wave vector Q_A
Deficits in Beam-Walking After Neonatal Motor Cortical Lesions are not Spared by Fetal Cortical Transplants in Rats
Adult rats that sustained unilateral motor cortical lesions at birth demonstrated deficits in traversing an elevated narrow beam. These deficits, manifested by hindlimb slips off the edge of the beam, were not spared in animals that received fetal cortical transplants into the lesion cavity immediately after lesion placement
Mermin-Ho vortex in ferromagnetic spinor Bose-Einstein condensates
The Mermin-Ho and Anderson-Toulouse coreless non-singular vortices are
demonstrated to be thermodynamically stable in ferromagnetic spinor
Bose-Einstein condensates with the hyperfine state F=1. The phase diagram is
established in a plane of the rotation drive vs the total magnetization by
comparing the energies for other competing non-axis-symmetric or singular
vortices. Their stability is also checked by evaluating collective modes.Comment: 4 pages, 4 figure
Life-long endurance exercise in humans:circulating levels of inflammatory markers and leg muscle size
Spontaneous symmetry breaking in a quenched ferromagnetic spinor Bose condensate
A central goal in condensed matter and modern atomic physics is the
exploration of many-body quantum phases and the universal characteristics of
quantum phase transitions in so far as they differ from those established for
thermal phase transitions. Compared with condensed-matter systems, atomic gases
are more precisely constructed and also provide the unique opportunity to
explore quantum dynamics far from equilibrium. Here we identify a second-order
quantum phase transition in a gaseous spinor Bose-Einstein condensate, a
quantum fluid in which superfluidity and magnetism, both associated with
symmetry breaking, are simultaneously realized. Rb spinor condensates
were rapidly quenched across this transition to a ferromagnetic state and
probed using in-situ magnetization imaging to observe spontaneous symmetry
breaking through the formation of spin textures, ferromagnetic domains and
domain walls. The observation of topological defects produced by this symmetry
breaking, identified as polar-core spin-vortices containing non-zero spin
current but no net mass current, represents the first phase-sensitive in-situ
detection of vortices in a gaseous superfluid.Comment: 6 pages, 4 figure
Energies and damping rates of elementary excitations in spin-1 Bose-Einstein condensed gases
Finite temperature Green's function technique is used to calculate the
energies and damping rates of elementary excitations of the homogeneous,
dilute, spin-1 Bose gases below the Bose-Einstein condensation temperature both
in the density and spin channels. For this purpose the self-consistent
dynamical Hartree-Fock model is formulated, which takes into account the direct
and exchange processes on equal footing by summing up certain classes of
Feynman diagrams. The model is shown to fulfil the Goldstone theorem and to
exhibit the hybridization of one-particle and collective excitations correctly.
The results are applied to the gases of ^{23}Na and ^{87}Rb atoms.Comment: 26 pages, 21 figures. Added 2 new figures, detailed discussio
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