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Nonlocality-controlled interaction of spatial solitons in nematic liquid crystals
We demonstrate experimentally that the interactions between a pair of
nonlocal spatial optical solitons in a nematic liquid crystal (NLC) can be
controlled by the degree of nonlocality. For a given beam width, the degree of
nonlocality can be modulated by varying the pretilt angle of NLC molecules via
the change of the bias. When the pretilt angle is smaller than pi/4, the
nonlocality is strong enough to guarantee the independence of the interactions
on the phase difference of the solitons. As the pretilt angle increases, the
degree of nonlocality decreases. When the degree is below its critical value,
the two solitons behavior in the way like their local counterpart: the two
in-phase solitons attract and the two out-of-phase solitons repulse.Comment: 3 pages, 4 figure
N-[(E)-4-Pyridylmethylene]-4-[(E)-4-(4-pyridylmethyleneamino)benzyl]aniline tetrahydrate
The title compound, C25H20N4·4H2O, crystallizes with the organic molecule lying on a twofold rotation axis through the methylene bridge C atom; there are also two water molecules in the asymmetric unit. The crystal structure is stabilized by C—H⋯O, O—H⋯O and O—H⋯N hydrogen bonds, linking the water molecules to each other and to the pyridine N atom
Distinct behaviors of suppression to superconductivity in induced by Fe and Co dopants
In the superconductor LaRuSi with the Kagome lattice of Ru, we have
successfully doped the Ru with Fe and Co atoms. Contrasting behaviors of
suppression to superconductivity is discovered between the Fe and the Co
dopants: Fe-impurities can suppress the superconductivity completely at a
doping level of only 3%, while the superconductivity is suppressed slowly with
the Co dopants. A systematic magnetization measurements indicate that the doped
Fe impurities lead to spin-polarized electrons yielding magnetic moments with
the magnitude of 1.6 \ per Fe, while the electrons given by the Co
dopants have the same density of states for spin-up and spin-down leading to
much weaker magnetic moments. It is the strong local magnetic moments given by
the Fe-dopants that suppress the superconductivity. The band structure
calculation further supports this conclusion.Comment: 6 pages, 7 figure
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