J. E. Shield scite author profile

J. E. Shield

5Publications

53Citation Statements Received

25Citation Statements Given

How they've been cited

124

How they cite others

Affiliations

University of Nebraska–Lincoln, University of Utah, Iowa State University

Publications

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Structural and magnetic properties of Pr-alloyed MnBi nanostructures

Kharel¹,

Shah²,

Li³

et al. 2013

J. Phys. D: Appl. Phys.

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The structural and magnetic properties of Pr-alloyed MnBi (short MnBi-Pr) nanostructures with a range of Pr concentrations are investigated. The nanostructures include thin films having Pr concentrations 0, 2, 3, 5, and 9 at.% and melt-spun ribbons having Pr concentrations 0%, 2%, 4%, and 6%, respectively. Addition of Pr into the MnBi lattice has produced a significant change in the magnetic properties of these nanostructures, including an increase in coercivity and structural phase transition temperature, and a decrease in saturation magnetization and anisotropy energy. The highest value of coercivity measured in the films is 23 kOe and in the ribbons is 5.6 kOe. The observed magnetic properties are explained as the consequences of competing ferromagnetic and antiferromagnetic interactions.

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Microstructures and phase formation in rapidly solidified Sm–Fe and Sm–Fe–Ti–C alloys

Shield

Branagan

1998

Journal of Magnetism and Magnetic Materials

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Anisotropy of W in Fe and Co

et al. 2011

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Influence of Copper Oxide on Femtosecond Laser Surface Processed Copper Pool Boiling Heat Transfer Surfaces

Kruse

Tsubaki

Zuhlke

et al. 2019

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Pool boiling heat transfer with the use of femtosecond laser surface processing (FLSP) on copper surfaces has been studied. FLSP creates a self-organized micro/nanostructured surface. In the previous pool boiling heat transfer studies with stainless steel FLSP surfaces, enhancements in critical heat flux (CHF) and heat transfer coefficients (HTCs) were observed compared to the polished reference surface. However, this study shows that copper FLSP surfaces exhibit reductions in both CHF and HTCs consistently. This reduction in heat transfer performance is a result of an oxide layer that covers the surface of the microstructures and acts as an insulator due to its low thermal conductivity. The oxide layer was observed and measured with the use of a focused ion beam milling process and found to have thickness of a few microns. The thickness of this oxide layer was found to be related to the laser fluence parameter. As the fluence increased, the oxide layer thickness increased and the heat transfer performance decreased. For a specific test surface, the oxide layer was selectively removed by a chemical etching process. The removal of the oxide layer resulted in an enhancement in the HTC compared to the polished reference surface. Although the original FLSP copper surfaces were unable to outperform the polished reference curve, this experiment illustrates how an oxide layer can significantly affect heat transfer results and dominate other surface characteristics (such as increased surface area and wicking) that typically lead to heat transfer enhancement.

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Erratum: “L1 structure formation in slow-cooled Fe-Au nanoclusters” [Appl. Phys. Lett. 100, 211911 (2012)]

Mukherjee

Zhang

Kramer

et al. 2012

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J. E. Shield

Structural and magnetic properties of Pr-alloyed MnBi nanostructures

Microstructures and phase formation in rapidly solidified Sm–Fe and Sm–Fe–Ti–C alloys

Anisotropy of W in Fe and Co

Influence of Copper Oxide on Femtosecond Laser Surface Processed Copper Pool Boiling Heat Transfer Surfaces

Erratum: “L1 structure formation in slow-cooled Fe-Au nanoclusters” [Appl. Phys. Lett. 100, 211911 (2012)]

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