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Martinez, C.; Aguilar, C.; Briones, E.; Guzman, D.; Zelaya, E.; Troncoso, L.; Roja, P.A. |
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Effects of Zr on the amorphization of Cu-Ni-Zr alloys prepared by mechanical alloying |
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2018 |
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Journal of Alloys and Compounds |
Abbreviated Journal |
J. Alloys Compd. |
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765 |
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771-781 |
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BULK METALLIC GLASSES; SOLID-SOLUTION; CRYSTALLINE; FABRICATION; EVOLUTION; POWDERS; SYSTEM; NB; TI |
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Abstract |
This work presents the effects of high energy milling with different Ni and Zr ratios on the amorphization of ternary Cu-Ni-Zr alloys (initially, Cu-43Ni-7Zr, Cu-12Ni-31Zr, Cu-33Ni-7Zr, and Cu-12Ni-23Zr; and later, Cu-23Ni-15Zr and Cu-11Ni-7Zr). Microstructure was determined using X-Ray diffraction and electron microscopy. Results were compared to thermodynamic models. In the ternary alloys under study, the lattice parameter of the Cu-Ni solid solution was generally correlated to the amounts of nickel incorporated into the Cu lattice. However, longer milling times reduced that lattice parameter and facilitated Zr insertion into the solid solution. For example, after 5 h of milling time, microstructural analysis showed the formation of a solid solution with cubic structure in Cu-43Ni-7Zr. This pattern is consistent with the presence of a lattice parameter between that of Cu and Ni (alpha-phase); in contrast, the Cu-33Ni-7Zr alloy showed an alpha-phase and another similar to Zr. Results suggest that, as the amount of nickel increases, the ability to form an amorphous phase decreases. Additionally, experimental and thermodynamic data showed a solid-solution formation stage, followed by an amorphous phase formation stage that occurred as milling time and Zr content increased. (C) 2018 Published by Elsevier B.V. |
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0925-8388 |
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WOS:000444341900095 |
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UAI @ alexi.delcanto @ |
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1406 |
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Raj, B.G.S.; Mangalaraja, R.V.; Vinoth, V.; Pugazhenthiran, N.; Herrera, F.V.; Jauhar, R.M.; Anandan, S. |
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Title |
Facile sonochemical synthesis of nanostructured FeWO4-rGO and CuCo2O4 nanocomposite for high-rate capability and stable asymmetric (CuCo2O4//FeWO4-rGO) supercapacitors |
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2023 |
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Journal of Alloys and Compounds |
Abbreviated Journal |
J. Alloys Compd. |
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968 |
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172156 |
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Asymmetric supercapacitors; Energy density; Energy storage; FeWO4-rGO; Sonochemical |
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The present work reports iron tungstate (FeWO4) nanostructures with reduced graphene oxide (rGO) as a novel anode material for enhancing the electrochemical properties of asymmetric supercapacitors. The FeWO4-rGO composite nanostructures were successfully synthesized by the one-pot sonochemical method. The synthesized nanocomposites crystal structure and phase purity were investigated using the powder X-ray diffraction (XRD) technique. The Fourier transform infrared (FT-IR) spectrograms demonstrate the presence of functional groups in the composite. The composite's morphology was examined using the high-resolution transmission electron microscopy (HR-TEM) and the field emission scanning electron microscopy (FE-SEM), and it was observed that the FeWO4 nanostructures were uniformly distributed on the reduced graphene oxide surface. The cyclic voltammetry (CV), galvanostatic charge-discharge (GCD), and electrochemical impedance spectroscopy (EIS) analyses were used to evaluate the electrochemical performance. After 5000 cycles at 10 mA cm(-2), the FeWO4-rGO composite achieved a better rate of efficiency and outstanding cycling performance, with capacitance retained at 68% and 77.8%, respectively. In 1 M Na2SO4, an asymmetric device (CuCo2O4//FeWO4-rGO composite) achieved a high energy density of 21.5 W.h Kg(-1) and a power density of 147 W Kg(-1). In the FeWO4-rGO nanocomposite, the reduced graphene oxide could enhance the conductivity and the free diffusion processes for the quick ion transport and easy ion access to the storage sites. The obtained results indicated that the FeWO4-rGO nanocomposite could be a good anode electrode material for the next-generation energy storage applications. |
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0925-8388 |
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WOS:001081720600001 |
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UAI @ alexi.delcanto @ |
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1902 |
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