Xinli Fan scite author profile

We introduce a simple but efficient electronic fitness function (EFF) that describes the electronic aspect of the thermoelectric performance. This EFF finds materials that overcome the inverse relationship between σ and S based on the complexity of the electronic structures regardless of specific origin (e.g., isosurface corrugation, valley degeneracy, heavy-light bands mixture, valley anisotropy or reduced dimensionality). This function is well suited for application in high throughput screening. We applied this function to 75 different thermoelectric and potential thermoelectric materials including full-and half-Heuslers, binary semiconductors and Zintl phases. We find an efficient screening using this transport function. The EFF identifies known high performance p-and n-type Zintl phases and half-Heuslers. In addition, we find some previously unstudied phases with superior EFF. arXiv:1708.04499v2 [cond-mat.mtrl-sci]

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In Situ Observation and Electrochemical Study of Encapsulated Sulfur Nanoparticles by MoS₂ Flakes

Tang

et al. 2017

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Sulfur is an attractive cathode material for next-generation lithium batteries due to its high theoretical capacity and low cost. However, dissolution of its lithiated product (lithium polysulfides) into the electrolyte limits the practical application of lithium sulfur batteries. Here we demonstrate that sulfur particles can be hermetically encapsulated by leveraging on the unique properties of two-dimensional materials such as molybdenum disulfide (MoS). The high flexibility and strong van der Waals force in MoS nanoflakes allows effective encapsulation of the sulfur particles and prevent its sublimation during in situ TEM studies. We observe that the lithium diffusivities in the encapsulated sulfur particles are in the order of 10 m s. Composite electrodes made from the MoS-encapsulated sulfur spheres show outstanding electrochemical performance, with an initial capacity of 1660 mAh g and long cycle life of more than 1000 cycles.

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Achieving delafossite analog by in situ electrochemical self-reconstruction as an oxygen-evolving catalyst

Liu

Wang

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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Development of novel and robust oxygen evolution reaction (OER) catalysts with well-modulated atomic and electronic structure remains a challenge. Compared to the well-known metal hydroxides or (oxyhydr)oxides with lamellar structure, delafossites (ABO2) are characterized by alternating layers of A cations and edge-sharing BO2 octahedra, but are rarely used in OER due to their poor electron conductivity and intrinsic activity. Here, we propose a delafossite analog by mutation of metal oxyhydroxide and delafossite based on first-principles calculations. Modulation on the electronic structure due to distortion of the original crystal field of the BO2 layers is calculated to enhance electron conductivity and catalytic activity. Inspired by the theoretical design, we have experimentally realized the delafossite analog by electrochemical self-reconstruction (ECSR). Operando X-ray absorption spectroscopy and other experimental techniques reveal the formation of delafossite analog with Ag intercalated into bimetallic cobalt–iron (oxyhydr)oxide layers from a metastable precursor through amorphization. Benefitting from the featured local electronic and geometric structures, the delafossite analog shows superior OER activity, affording a current density of 10 mA⋅cm−2 at an overpotential of 187 mV and an excellent stability (300 h) in alkaline conditions.

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Xinli Fan

On the origin of the high coarsening resistance of Ω plates in Al–Cu–Mg–Ag Alloys

Electronic fitness function for screening semiconductors as thermoelectric materials

In Situ Observation and Electrochemical Study of Encapsulated Sulfur Nanoparticles by MoS₂ Flakes

Achieving delafossite analog by in situ electrochemical self-reconstruction as an oxygen-evolving catalyst

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Xinli Fan

On the origin of the high coarsening resistance of Ω plates in Al–Cu–Mg–Ag Alloys

Electronic fitness function for screening semiconductors as thermoelectric materials

In Situ Observation and Electrochemical Study of Encapsulated Sulfur Nanoparticles by MoS2 Flakes

Achieving delafossite analog by in situ electrochemical self-reconstruction as an oxygen-evolving catalyst

Contact Info

Product

Resources

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In Situ Observation and Electrochemical Study of Encapsulated Sulfur Nanoparticles by MoS₂ Flakes