Abby Goldman scite author profile

The "lone" 6s electron pair often plays a key role in determining the structure and physical properties of compounds containing sixth-row elements in their lower oxidation states: Tl(+), Pb(2+), and Bi(3+) with the [Xe]4f(14)5d(10)6s(2) electronic configuration. The lone pairs on these ions are associated with reduced structural symmetries, including ferroelectric instabilities and other important phenomena. Here we consider the isoelectronic auride Au(-) ion with the [Xe]4f(14)5d(10)6s(2) electronic configuration. Ab initio density functional theory methods are employed to probe the effect of the 6s lone pair in alkali-metal aurides (KAu, RbAu, and CsAu) with the CsCl structure. The dielectric constants, Born effective charges, and structural instabilities suggest that the 6s lone pair on the Au(-) anion is stereochemically inert to minor mechanical and electrical perturbation. Pressures greater than 14 GPa, however, lead to reorganization of the electronic structure of CsAu and activate lone-pair involvement and Au-Au interactions in bonding, resulting in a transformation from the cubic CsCl structure type to an orthorhombic Cmcm structure featuring zigzag Au-Au chains.

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Magnetic ordering and magnetodielectric phenomena in CoSeO₄

Melot¹,

Goldman²,

Darago³

et al. 2010

J. Phys.: Condens. Matter

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CoSeO(4) has a structure consisting of edge-sharing chains of Co(2+) octahedra which are held together by SeO(4)(2-) tetrahedra via shared oxygen atoms at the edges of the octahedra. DC magnetization measurements indicate a transition to an ordered state below 30 K. Powder neutron diffraction refinements suggest an ordered state with two unique antiferromagnetic chains within the unit cell. Isothermal magnetization measurements indicate a temperature-dependent field-induced magnetic transition below the ordering temperature. From neutron diffraction, we find that this corresponds to a realignment of spins from the canted configuration towards the c-axis. The dielectric constant shows a change in slope at the magnetic ordering temperature indicating an interplay between the spin and charge degrees of freedom.

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Manipulation of magnetization states of ferromagnetic nanorings by an applied azimuthal Oersted field

Yang

Pradhan

Goldman

et al. 2011

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We manipulate the magnetic states of ferromagnetic nanorings with an azimuthal Oersted field directed along the ring circumference. The circular field is generated by passing current through an atomic force microscope tip positioned at the center of the ring, and can directly control the chirality of the vortex state. We demonstrate switching from an onion state to a vortex state and between two vortex states, using magnetic force microscopy to image the resulting magnetic states. The understanding of the magnetization switching behavior in an azimuthal Oersted field could improve practical magnetic data storage devices.

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Multiple 360° domain wall switching in thin ferromagnetic nanorings in a circular magnetic field

Goldman

Licht

Sun

et al. 2012

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Micromagnetic simulations of the vortex switching process of thin ferromagnetic rings under the application of a circular field, as if created from a current-carrying wire passing through the ring center, reveal that for rings with sub-micron dimensions and thicknesses on the order of the exchange length, the vortex to vortex switching process occurs through the nucleation and annihilation of multiple 360° domain walls (DWs). The DWs can be characterized by their circulation relative to the vortex circulation; the DWs form in pairs with opposite topological indices. The DW with the same circulation annihilates first, which has a smaller energy barrier to overcome before annihilating. The contributions from both the exchange energy and demagnetization energy must be considered to predict which DW will annihilate first. Either wall could be annihilated by offsetting the current toward the wall being targeted.

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Bio Focus: Hierarchical structure of spider dragline silk prevents spinning

Goldman¹

2017

MRS Bull.

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Abby Goldman

On the Stereochemical Inertness of the Auride Lone Pair: Ab Initio Studies of AAu (A = K, Rb, Cs)

Magnetic ordering and magnetodielectric phenomena in CoSeO₄

Manipulation of magnetization states of ferromagnetic nanorings by an applied azimuthal Oersted field

Multiple 360° domain wall switching in thin ferromagnetic nanorings in a circular magnetic field

Bio Focus: Hierarchical structure of spider dragline silk prevents spinning

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Abby Goldman

On the Stereochemical Inertness of the Auride Lone Pair: Ab Initio Studies of AAu (A = K, Rb, Cs)

Magnetic ordering and magnetodielectric phenomena in CoSeO4

Manipulation of magnetization states of ferromagnetic nanorings by an applied azimuthal Oersted field

Multiple 360° domain wall switching in thin ferromagnetic nanorings in a circular magnetic field

Bio Focus: Hierarchical structure of spider dragline silk prevents spinning

Contact Info

Product

Resources

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Magnetic ordering and magnetodielectric phenomena in CoSeO₄