Your search keyword '"Moceri, Matteo"' showing total 4 results

1. Attainment of high critical current in thick BaZrO3-doped YBa2Cu3O7 multilayer nanocomposite films.

Author

Ogunjimi, Victor, Panth, Mohan, Sebastian, Mary Ann, Shen, Jianan, Moceri, Matteo, Ebbing, Charles, Haugan, Timothy, Wang, Haiyan, Aafiya, and Wu, Judy

Subjects

CRITICAL currents, THIN films, MAGNETIC fields, KIRKENDALL effect, LOW temperatures

Abstract

High critical current (Ic) in high magnetic fields (B) with minimal variations with respect to the orientation of the B field is demanded by many applications such as high-field magnets for fusion systems. Motivated by this, this work studies 6 vol. % BaZrO3/YBa2Cu3O7 (BZO/YBCO) multilayer nanocomposite films by stacking two 10 nm thick Ca0.3Y0.7Ba2Cu3O7 (CaY-123) spacers with three BZO/YBCO layers of thickness varied from 50 to 330 nm to make the total film thickness of 150–1000 nm. The Ca diffusion from the spacers into BZO/YBCO was shown to dramatically enhance pinning efficiency of c-axis aligned BZO nanorods, which yields high and almost thickness independent critical current density (Jc) in the BZO/YBCO multilayer nanocomposite films. Remarkably, enhanced Jc was observed in these multilayer samples at a wide temperature range of 20–80 K and magnetic fields up to 9.0 T. In particular, the thicker BZO/YBCO multilayer films outperform their thinner counterparts in both higher value and less anisotropy of Jc at lower temperatures and higher fields. At 20 K and 9.0 T, Ic is up to 654 A/cm-width at B//c in the 6% multilayer (1000 nm) sample, which is close to 753 A/cm-width at B//ab due to the intrinsic pinning. This result illustrates the critical role of the Ca cation diffusion into the YBCO lattice in achieving high and isotropic pinning in thick BZO/YBCO multilayer films. [ABSTRACT FROM AUTHOR]

Published

2024

2. Zirconium nanoparticle coating development for FCCI diffusion barrier in nuclear cladding

Author

Hamilton, Sarah, Childs, Mason, Bhattacharya, Sumit, Yacout, Abdellatif, Moceri, Matteo, and Sudderth, Laura

Published

2023

3. Thermally Stable 3D‐Metamaterial Designs with Advanced Hyperbolic Dispersion Manipulation and Magnetic Anisotropy.

Author

Song, Jiawei, Zhang, Di, Moceri, Matteo, Dou, Hongyi, Zhang, Xinghang, and Wang, Haiyan

Subjects

3-D films, METAMATERIALS, DISPERSION (Chemistry), X-ray diffraction, THERMAL stability, MAGNETIC anisotropy, PERPENDICULAR magnetic anisotropy

Abstract

Hybrid metamaterials (HMs) have attracted significant research interests owing to their unique optical properties and their ability to manipulate light‐matter interaction in a novel and controlled fashion beyond what any single material offers. Especially 3D HMs are of great interest due to their potential to provide advanced and precise control of such light‐matter interaction in nanoscale. In this study, a set of 3D HM nanocomposite films are designed by integrating three phases, i.e., vertically aligned CoFe2 nanosheets within the matrix of TiN/TaN multilayers. By increasing the number of TiN/TaN multilayers from 2 to 19, a high degree of tunability in optical property has been demonstrated, including well‐tailored optical permittivity, and tunable hyperbolic dispersion from Type‐II to Type‐I. Ferromagnetic CoFe2 nanosheets introduces novel magnetic responses, such as magnetic anisotropy and enhanced coercivity. Furthermore, in situ heating X‐ray diffraction (XRD) suggests good thermal stability of the 3D nanocomposite films up to the measured temperature of 600 °C. This three‐phase 3D nanocomposite design offers more flexibility in HM designs, multifunctionalities, and phase stability, compared with the typical two‐phase HMs toward future metamaterials by design. [ABSTRACT FROM AUTHOR]

Published

2024

4. Epitaxial Thin Film Growth on Recycled SrTiO3 Substrates Toward Sustainable Processing of Complex Oxides.

Author

Shen, Jianan, Quigley, Lizabeth, Barnard, James P., Lu, Ping, Tsai, Benson Kunhung, Zemlyanov, Dmitry, Zhang, Yizhi, Sheng, Xuanyu, Gan, Jeremy, Moceri, Matteo, Hu, Zedong, Huang, Jialong, Shen, Chao, Deitz, Julia, Zhang, Xinghang, and Wang, Haiyan

Subjects

*YTTRIUM iron garnet, *SCANNING transmission electron microscopy, *OXIDE coating, *SUBSTRATES (Materials science), *THIN films

Abstract

Complex oxide thin films cover a range of physical properties and multifunctionalities that are critical for logic, memory, and optical devices. Typically, the high‐quality epitaxial growth of these complex oxide thin films requires single crystalline oxide substrates such as SrTiO3 (STO), MgO, LaAlO3, a‐Al2O3, and many others. Recent successes in transferring these complex oxides as free‐standing films not only offer great opportunities in integrating complex oxides on other devices, but also present enormous opportunities in recycling the deposited substrates after transfer for cost‐effective and sustainable processing of complex oxide thin films. In this work, the surface modification effects introduced on the recycled STO are investigated, and their impacts on the microstructure and properties of subsequently grown epitaxial oxide thin films are assessed and compared with those grown on the pristine substrates. Detailed analyses using high‐resolution scanning transmission electron microscopy and geometric phase analysis demonstrate distinct strain states on the surfaces of the recycled STO versus the pristine substrates, suggesting a pre‐strain state in the recycled STO substrates due to the previous deposition layer. These findings offer opportunities in growing highly mismatched oxide films on the recycled STO substrates with enhanced physical properties. Specifically, yttrium iron garnet (Y3Fe5O12) films grown on recycled STO present different ferromagnetic responses compared to that on the pristine substrates, underscoring the effects of surface modification. The study demonstrates the feasibility of reuse and redeposition using recycled substrates. Via careful handling and preparation, high‐quality epitaxial thin films can be grown on recycled substrates with comparable or even better structural and physical properties toward sustainable process of complex oxide devices. [ABSTRACT FROM AUTHOR]

Published

2024