Your search keyword '"Neumeier, John J."' showing total 7 results

1. Anisotropic Dielectric Relaxation in Single Crystal H$_{2}$O Ice Ih from 80-250 K

Author

Buckingham, David T. W., Neumeier, John J., and Schmidt, V. Hugo

Subjects

Condensed Matter - Materials Science

Abstract

Three properties of the dielectric relaxation in ultra-pure single crystalline H$_{2}$O ice Ih were probed at temperatures between 80-250 K; the thermally stimulated depolarization current, static electrical conductivity, and dielectric relaxation time. The measurements were made with a guarded parallel-plate capacitor constructed of fused quartz with Au electrodes. The data agree with relaxation-based models and provide for the determination of activation energies, which suggest that relaxation in ice is dominated by Bjerrum defects below 140 K. Furthermore, anisotropy in the dielectric relaxation data reveals that molecular reorientations along the crystallographic $c$-axis are energetically favored over those along the $a$-axis between 80-140 K. These results lend support for the postulate of a shared origin between the dielectric relaxation dynamics and the thermodynamic partial proton-ordering in ice near 100 K, and suggest a preference for ordering along the $c$-axis., Comment: 20 pages, 6 figures, 2 tables

Published

2017

2. Inhomogeneous magnetism in La-doped CaMnO3. (I) Nanometric-scale spin clusters and long-range spin canting

Author

Granado, Eduardo, Ling, Chris D., Neumeier, John J., Lynn, Jeff W., and Argyriou, Dimitri N.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

Neutron measurements on Ca{1-x}La{x}MnO3 (0.00 <= x <= 0.20) reveal the development of a liquid-like spatial distribution of magnetic droplets of average size ~10 Angstroms, the concentration of which is proportional to x (one cluster per ~60 doped electrons). In addition, a long-range ordered ferromagnetic component is observed for ~0.05 < x < ~0.14. This component is perpendicularly coupled to the simple G-type antiferromagnetic (G-AFM) structure of the undoped compound, which is a signature of a G-AFM + FM spin-canted state. The possible relationship between cluster formation and the stabilization of a long-range spin-canting for intermediate doping is discussed., Comment: Submitted to Physical Review B

Published

2003

3. From Ta2S5 Wires to Ta2O5 and Ta2O5–xSx

Author

Benjamin, Shermane M., primary, Rieders, Nathaniel F., additional, Smith, Michael G., additional, and Neumeier, John J., additional

Published

2021

4. From Ta2S5 Wires to Ta2O5 and Ta2O5–xSx.

Author

Benjamin, Shermane M., Rieders, Nathaniel F., Smith, Michael G., and Neumeier, John J.

Published

2021

5. Possible Phase Transition in H2O Ice Ih Near 110 K

Author

Buckingham, David T. W., Sueli H. Masunaga, Gile, Forrest C., and Neumeier, John J.

Published

2015

6. High-Resolution Thermal Expansion Measurements of H2O Ice

Author

Buckingham, David, Sueli H. Masunaga, Gile, Forrest C., and Neumeier, John J.

Published

2014

7. From Ta 2 S 5 Wires to Ta 2 O 5 and Ta 2 O 5- x S x .

Author

Benjamin SM, Rieders NF, Smith MG, and Neumeier JJ

Abstract

Synthesis routes to forming novel materials are oftentimes complicated and indirect. For example, Ta 2 S 5 has only been found as an unwanted byproduct of certain chemical reactions, and its properties were unknown. However, here we demonstrate the growth of Ta 2 S 5 wires with steel-like tensile strength, which are also precursors for the first controlled synthesis of long, mesoscopic Ta 2 O 5 wires and superconducting Ta 2 O 5- x S x wires. Single-crystal wires of tantalum pentasulfide, Ta 2 S 5 , were first grown using vapor transport from polycrystalline XTa 2 S 5 , sulfur, and TeCl 4 in fused-quartz tubes, where X = Ba or Sr. Crystals form as long wires with lengths on the order of a few centimeters and varying cross sections as small as 25 μm 2 . They were found to have steel-like tensile strength, and their crystal structure was determined using X-ray diffraction to be monoclinic with space group P 2/ m and with lattice parameters a = 9.91(7) Å, b = 3.82(5) Å, and c = 20.92(2) Å. Electrical resistivity measurements reveal Ta 2 S 5 to be a narrow band gap semiconductor with E g = 110 meV, while a Debye temperature Θ D = 97.0(5) K is observed in specific heat. Tantalum pentasulfide wires were then converted to insulating tantalum pentoxide (Ta 2 O 5 ) wires after calcinating them for 30 min in air at 900 °C. Finally, tantalum pentoxide wires were converted to tantalum oxysulfide (Ta 2 O 5- x S x ) wires after annealing them in CS 2 vapor for 30 min at 900 °C. The oxysulfide crystal structure was determined using X-ray diffraction to be that of β-Ta 2 O 5 . Electrical and magnetic measurements reveal Ta 2 O 5- x S x to be metallic and superconducting with T c = 3 K., Competing Interests: The authors declare no competing financial interest., (© 2021 The Authors. Published by American Chemical Society.)

Published

2021