618 research outputs found
A zinc transporter gene required for development of the nervous system.
The essentiality of zinc for normal brain development is well established. It has been suggested that primary and secondary zinc deficiencies can contribute to the occurrence of numerous human birth defects, including many involving the central nervous system. In a recent study, we searched for zinc transporter genes that were critical for neurodevelopment. We confirmed that ZIP12 is a zinc transporter encoded by the gene slc39a12 that is highly expressed in the central nervous systems of human, mouse, and frog (Xenopus tropicalis).Using loss-of-function methods, we determined that ZIP12 is required for neuronal differentiation and neurite outgrowth and necessary for neurulation and embryonic viability. These results highlight an essential need for zinc regulation during embryogenesis and nervous system development. We suggest that slc39a12 is a candidate gene for inherited neurodevelopmental defects in humans
Bifurcated polarization rotation in bismuth-based piezoelectrics
ABO3 perovskite-type solid solutions display a large variety of structural and physical properties, which can be tuned by chemical composition or external parameters such as temperature, pressure, strain, electric, or magnetic fields. Some solid solutions show remarkably enhanced physical properties including colossal magnetoresistance or giant piezoelectricity. It has been recognized that structural distortions, competing on the local level, are key to understanding and tuning these remarkable properties, yet, it remains a challenge to experimentally observe such local structural details. Here, from neutron pair-distribution analysis, a temperature-dependent 3D atomic-level model of the lead-free piezoelectric perovskite Na0.5Bi0.5TiO3 (NBT) is reported. The statistical analysis of this model shows how local distortions compete, how this competition develops with temperature, and, in particular, how different polar displacements of Bi3+ cations coexist as a bifurcated polarization, highlighting the interest of Bi-based materials in the search for new lead-free piezoelectrics
Orbital Dimer Model for Spin-Glass State in YMoO
The formation of a spin glass usually requires both structural disorder and
frustrated magnetic interactions. Consequently, the origin of spin-glass
behaviour in YMoO in which magnetic Mo ions occupy a
frustrated pyrochlore lattice with minimal compositional disorder has been
a longstanding question. Here, we use neutron and X-ray pair-distribution
function (PDF) analysis to develop a disorder model that resolves apparent
incompatibilities between previously-reported PDF, EXAFS and NMR studies and
provides a new and physical mechanism for spin-glass formation. We show that
Mo ions displace according to a local "2-in/2-out" rule on each Mo
tetrahedron, driven by orbital dimerisation of Jahn-Teller active Mo
ions. Long-range orbital order is prevented by the macroscopic degeneracy of
dimer coverings permitted by the pyrochlore lattice. Cooperative O
displacements yield a distribution of MoOMo angles, which in turn
introduces disorder into magnetic interactions. Our study demonstrates
experimentally how frustration of atomic displacements can assume the role of
compositional disorder in driving a spin-glass transition.Comment: 6 pages, 3 figure
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Ionic liquid facilitated melting of the metal-organic framework ZIF-8.
Hybrid glasses from melt-quenched metal-organic frameworks (MOFs) have been emerging as a new class of materials, which combine the functional properties of crystalline MOFs with the processability of glasses. However, only a handful of the crystalline MOFs are meltable. Porosity and metal-linker interaction strength have both been identified as crucial parameters in the trade-off between thermal decomposition of the organic linker and, more desirably, melting. For example, the inability of the prototypical zeolitic imidazolate framework (ZIF) ZIF-8 to melt, is ascribed to the instability of the organic linker upon dissociation from the metal center. Here, we demonstrate that the incorporation of an ionic liquid (IL) into the porous interior of ZIF-8 provides a means to reduce its melting temperature to below its thermal decomposition temperature. Our structural studies show that the prevention of decomposition, and successful melting, is due to the IL interactions stabilizing the rapidly dissociating ZIF-8 linkers upon heating. This understanding may act as a general guide for extending the range of meltable MOF materials and, hence, the chemical and structural variety of MOF-derived glasses
Superstructure and Correlated Na+ Hopping in a Layered Mg-Substituted Sodium Manganate Battery Cathode are Driven by Local Electroneutrality
Acknowledgments ARTICLE SECTIONSJump To E.N.B. acknowledges funding from the Engineering Physical Sciences Research Council (EPSRC) via the National Productivity Interest Fund (NPIF) 2018 (EP/S515334/1). J.D.B. acknowledges funding from the Faraday Institution (EP/S003053/1, FIRG016). The authors also thank the Science and Technology Facilities Council (STFC) and ISIS Neutron and Muon source for neutron data (experiment no.: RB2010350). Additional thanks are given to the staff scientists at beamline I11 of the Diamond Light Source for synchrotron data using block allocation group time under proposal CY34243. This work also utilized the ARCHER UK National Supercomputing Service via our membership in the UKâs HEC Materials Chemistry Consortium, funded by the EPSRC (EP/L000202). The research was also carried out at the Center for Functional Nanomaterials, Brookhaven National Laboratory, through the U.S. Department of Energy, Office of Basic Energy Sciences, Contract DE-AC02-98CH10866. E.N.B. would also like to thank A. Van der Ven and M.A. Jones for illuminating discussions.Peer reviewedPublisher PD
Dimensional crossover of correlated anion disorder in oxynitride perovskites
A simple crossover from two-dimensional to three-dimensional
correlated disorder of O and N atoms on a cubic lattice has been
discovered within the Ba1xSrxTaO2N series of perovskite oxynitrides.
The crossover is driven by lattice expansion as x decreases, and provides
a rapid increase in entropy due to a change from subextensive to
extensive configurational entropy regimes.We thank STFC, UK for support for H. J. and provision of
ISIS beamtime, and EPSRC for additional support. This work was
also supported by the Ministerio de Economia y Competitividad
(MINECO), Spain through Project MAT2017-86616-R, the
Severo Ochoa Program SEV-2015-0496, and Fellowship support
to AB (MAT2011-24757). We thank the ALBA synchrotron for the
provision of beamtime and Prof. Rosa Palacin, Dr Carlos
Frontera (ICMAB-CSIC) and Dr F. Fauth (ALBA) for assistance
with data collection.Peer reviewe
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