Fang Wu scite author profile

Two-dimensional (2D) ferromagnetic semiconductors have been recognized as the cornerstone for next-generation electric devices, but the development is highly limited by the weak ferromagnetic coupling and low Curie temperature ( T). Here, we reported a general mechanism which can significantly enhance the ferromagnetic coupling in 2D semiconductors without introducing carriers. On the basis of a double-orbital model, we revealed that the superexchange-driven ferromagnetism is closely related to the virtual exchange gap, and lowering this gap by isovalent alloying can significantly enhance the ferromagnetic (FM) coupling. On the basis of the experimentally available two-dimensional CrI and CrGeTe, the FM coupling in two semiconducting alloy compounds CrWI and CrWGeTe monolayers are calculated to be enhanced by 3∼5 times without introducing any carriers. Furthermore, a room-temperature ferromagnetic semiconductor is achieved under a small in-plane strain (4%). Thus, our findings not only deepen the understanding of FM semiconductors but also open a new door for realistic spintronics.

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Atomically Thin Transition-Metal Dinitrides: High-Temperature Ferromagnetism and Half-Metallicity

Huang

et al. 2015

Nano Lett.

171

106

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High-temperature ferromagnetic two-dimensional (2D) materials with flat surfaces have been a long-sought goal due to their potential in spintronics applications. Through comprehensive first-principles calculations, we show that the recently synthesized MoN2 monolayer is such a material; it is ferromagnetic with a Curie temperature of nearly 420 K, which is higher than that of any flat 2D magnetic materials studied to date. This novel property, made possible by the electron-deficient nitrogen ions, render transition-metal dinitrides monolayers with unique electronic properties which can be switched from the ferromagnetic metals in MoN2, ZrN2, and TcN2 to half-metallic ones in YN2. Transition-metal dinitrides monolayers may, therefore, serve as good candidates for spintronics devices.

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Visible-Light-Absorption in Graphitic C₃N₄Bilayer: Enhanced by Interlayer Coupling

Liu

et al. 2012

J. Phys. Chem. Lett.

154

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Although graphitic C 3 N 4 (g-C 3 N 4 ) has been demonstrated to be a potential candidate for solar cell absorber and photovoltaic materials, the application has been limited by the low photoconversion efficiency in the visible range. Here, we explored that a g-C 3 N 4 bilayer has much better visible-light adsorption than a single layer via first-principles calculations, and the calculated optical adsorption threshold of bilayer significantly shifts downward by 0.8 eV, which is induced by the interlayer coupling. Additionally, we also found that the optical energy gap of bilayer can be engineered by the external electric field. The insights obtained in this study are general and will be helpful for future studies of twodimensional solar cell absorber and photovoltaic materials.

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CeO₂ Nanorods and Gold Nanocrystals Supported on CeO₂ Nanorods as Catalyst

et al. 2005

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The formation mechanism of uniform CeO2 structure at the nanometer scale via a wet-chemical reaction is of great interest in fundamental study as well as a variety of applications. In this work, large-scale well-crystallized CeO2 nanorods with uniform diameters in the range of 20-30 nm and lengths up to tens of micrometers are first synthesized through a hydrothermal synthetic route in 5 M KOH solution at 180 degrees C for 45 h without any templates and surfactants. The nanorod formation involves dehydration of CeO2 nanoparticles and orientation growth along the 110 direction in KOH solution. Subsequently, gold nanoparticles with crystallite sizes between 10 and 20 nm are loaded on the surface of CeO2 nanorods using HAuCl4 solution as the gold source and NaBH4 solution as a reducing agent. The synthesized Au/CeO2 nanorods demonstrate a higher catalytic activity in CO oxidation than the pure CeO2 nanorods.

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Fang Wu

Toward Intrinsic Room-Temperature Ferromagnetism in Two-Dimensional Semiconductors

Atomically Thin Transition-Metal Dinitrides: High-Temperature Ferromagnetism and Half-Metallicity

Visible-Light-Absorption in Graphitic C₃N₄Bilayer: Enhanced by Interlayer Coupling

CeO₂ Nanorods and Gold Nanocrystals Supported on CeO₂ Nanorods as Catalyst

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Fang Wu

Toward Intrinsic Room-Temperature Ferromagnetism in Two-Dimensional Semiconductors

Atomically Thin Transition-Metal Dinitrides: High-Temperature Ferromagnetism and Half-Metallicity

Visible-Light-Absorption in Graphitic C3N4Bilayer: Enhanced by Interlayer Coupling

CeO2 Nanorods and Gold Nanocrystals Supported on CeO2 Nanorods as Catalyst

Contact Info

Product

Resources

About

Visible-Light-Absorption in Graphitic C₃N₄Bilayer: Enhanced by Interlayer Coupling

CeO₂ Nanorods and Gold Nanocrystals Supported on CeO₂ Nanorods as Catalyst