Shuai Yan scite author profile

Materials in metastable states, such as amorphous ice and supercooled condensed matter, often exhibit exotic phenomena. To date, achieving metastability is usually accomplished by rapid quenching through a thermodynamic path function, namely, heating-cooling cycles. However, heat can be detrimental to organic-containing materials because it can induce degradation. Alternatively, the application of pressure can be used to achieve metastable states that are inaccessible via heating-cooling cycles. Here we report metastable states of 2D organic-inorganic hybrid perovskites reached through structural amorphization under compression followed by recrystallization via decompression. Remarkably, such pressure-derived metastable states in 2D hybrid perovskites exhibit enduring bandgap narrowing by as much as 8.2% with stability under ambient conditions. The achieved metastable states in 2D hybrid perovskites via compression-decompression cycles offer an alternative pathway toward manipulating the properties of these "soft" materials.

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Lithiation‐Enabled High‐Density Nitrogen Vacancies Electrocatalyze CO₂ to C₂ Products

Chen

Luo

et al. 2021

Advanced Materials

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Electrochemical CO2 reduction to produce valuable C2 products is attractive but still suffers with relatively poor selectivity and stability at high current densities, mainly due to the low efficiency in the coupling of two *CO intermediates. Herein, it is demonstrated that high‐density nitrogen vacancies formed on cubic copper nitrite (Cu3Nx) feature as efficient electrocatalytic centers for CO–CO coupling to form the key OCCO* intermediate toward C2 products. Cu3Nx with different nitrogen densities are fabricated by an electrochemical lithium tuning strategy, and density functional theory calculations indicate that the adsorption energies of CO* and the energy barriers of forming key C2 intermediates are strongly correlated with nitrogen vacancy density. The Cu3Nx catalyst with abundant nitrogen vacancies presents one of the highest Faradaic efficiencies toward C2 products of 81.7 ± 2.3% at −1.15 V versus reversible hydrogen electrode (without ohmic correction), corresponding to the partial current density for C2 production as −307 ± 9 mA cm−2. An outstanding electrochemical stability is also demonstrated at high current densities, substantially exceeding CuOx catalysts with oxygen vacancies. The work suggests an attractive approach to create stable anion vacancies as catalytic centers toward multicarbon products in electrochemical CO2 reduction.

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Electron Localization and Lattice Strain Induced by Surface Lithium Doping Enable Ampere‐Level Electrosynthesis of Formate from CO₂

et al. 2021

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The electrochemical CO 2 conversion to formate is a promising approach for reducing CO 2 level and obtaining value-added chemicals, but its partial current density is still insufficient to meet the industrial demands. Herein, we developed a surface-lithium-doped tin (s-SnLi) catalyst by controlled electrochemical lithiation. Density functional theory calculations indicated that the Li dopants introduced electron localization and lattice strains on the Sn surface, thus enhancing both activity and selectivity of the CO 2 electroreduction to formate. The s-SnLi electrocatalyst exhibited one of the best CO 2 -to-formate performances, with a partial current density of À1.0 A cm À2 for producing formate and a corresponding Faradaic efficiency of 92 %. Furthermore, Zn-CO 2 batteries equipped with the s-SnLi catalyst displayed one of the highest power densities of 1.24 mW cm À2 and an outstanding stability of > 800 cycles. Our work suggests a promising approach to incorporate electron localization and lattice strain for the catalytic sites to achieve efficient CO 2 -to-formate electrosynthesis toward potential commercialization.

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Label‐Free Imaging of Nanoparticle Uptake Competition in Single Cells by Hyperspectral Stimulated Raman Scattering

Bin

Yan

Xiao

et al. 2017

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Imaging and quantification of nanoparticles in single cells in their most natural condition are expected to facilitate the biotechnological applications of nanoparticles and allow for better assessment of their biosafety risks. However, current imaging modalities either require tedious sample preparation or only apply to nanoparticles with specific physicochemical characteristics. Here, the emerging hyperspectral stimulated Raman scattering (SRS) microscopy, as a label-free and nondestructive imaging method, is used for the first time to investigate the subcellular distribution of nanoparticles in the protozoan Tetrahymena thermophila. The two frequently studied nanoparticles, polyacrylate-coated α-Fe O and TiO , are found to have different subcellular distribution pattern as a result of their dissimilar uptake routes. Significant uptake competition between these two types of nanoparticles is further discovered, which should be paid attention to in future bioapplications of nanoparticles. Overall, this study illustrates the great promise of hyperspectral SRS as an analytical imaging tool in nanobiotechnology and nanotoxicology.

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Shuai Yan

Isothermal pressure-derived metastable states in 2D hybrid perovskites showing enduring bandgap narrowing

Lithiation‐Enabled High‐Density Nitrogen Vacancies Electrocatalyze CO₂ to C₂ Products

Electron Localization and Lattice Strain Induced by Surface Lithium Doping Enable Ampere‐Level Electrosynthesis of Formate from CO₂

Label‐Free Imaging of Nanoparticle Uptake Competition in Single Cells by Hyperspectral Stimulated Raman Scattering

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Shuai Yan

Isothermal pressure-derived metastable states in 2D hybrid perovskites showing enduring bandgap narrowing

Lithiation‐Enabled High‐Density Nitrogen Vacancies Electrocatalyze CO2 to C2 Products

Electron Localization and Lattice Strain Induced by Surface Lithium Doping Enable Ampere‐Level Electrosynthesis of Formate from CO2

Label‐Free Imaging of Nanoparticle Uptake Competition in Single Cells by Hyperspectral Stimulated Raman Scattering

Contact Info

Product

Resources

About

Lithiation‐Enabled High‐Density Nitrogen Vacancies Electrocatalyze CO₂ to C₂ Products

Electron Localization and Lattice Strain Induced by Surface Lithium Doping Enable Ampere‐Level Electrosynthesis of Formate from CO₂