Juejing Liu scite author profile

Conventional nanomaterials in electrochemical nonenzymatic sensing face huge challenge due to their complex size-, surface-, and composition-dependent catalytic properties and low active site density. In this work, we designed a single-atom Pt supported on Ni(OH)2 nanoplates/nitrogen-doped graphene (Pt1/Ni(OH)2/NG) as the first example for constructing a single-atom catalyst based electrochemical nonenzymatic glucose sensor. The resulting Pt1/Ni(OH)2/NG exhibited a low anode peak potential of 0.48 V and high sensitivity of 220.75 μA mM–1 cm–2 toward glucose, which are 45 mV lower and 12 times higher than those of Ni(OH)2, respectively. The catalyst also showed excellent selectivity for several important interferences, short response time of 4.6 s, and high stability over 4 weeks. Experimental and density functional theory (DFT) calculated results reveal that the improved performance of Pt1/Ni(OH)2/NG could be attributed to stronger binding strength of glucose on single-atom Pt active centers and their surrounding Ni atoms, combined with fast electron transfer ability by the adding of the highly conductive NG. This research sheds light on the applications of SACs in the field of electrochemical nonenzymatic sensing.

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A protein-functionalized microfiber/protein nanofiber Bi-layered air filter with synergistically enhanced filtration performance by a viable method

Liu

Dunne

Fan

et al. 2019

Separation and Purification Technology

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Toward High‐Performance Metal–Organic‐Framework‐Based Quasi‐Solid‐State Electrolytes: Tunable Structures and Electrochemical Properties

et al. 2023

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Metal–organic frameworks (MOFs) have been reported as promising materials for electrochemical applications owing to their tunable porous structures and ion‐sieving capability. However, it remains challenging to rationally design MOF‐based electrolytes for high‐energy lithium batteries. In this work, by combining advanced characterization and modeling tools, a series of nanocrystalline MOFs is designed, and the effects of pore apertures and open metal sites on ion‐transport properties and electrochemical stability of MOF quasi‐solid‐state electrolytes are systematically studied. It isdemonstrated that MOFs with non‐redox‐active metal centers can lead to a much wider electrochemical stability window than those with redox‐active centers. Furthermore, the pore aperture of MOFs is found to be a dominating factor that determines the uptake of lithium salt and thus ionic conductivity. The ab initio molecular dynamics simulations further demonstrate that open metal sites of MOFs can facilitate the dissociation of lithium salt and immobilize anions via Lewis acid–base interaction, leading to good lithium‐ion mobility and high transference number. The MOF quasi‐solid‐state electrolyte demonstrates great battery performance with commercial LiFePO4 and LiCoO2 cathodes at 30 °C. This work provides new insights into structure–property relationships between tunable structure and electrochemical properties of MOFs that can lead to the development of advanced quasi‐solid‐state electrolytes for high‐energy lithium batteries.

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A Bimodal Protein Fabric Enabled via In Situ Diffusion for High-Performance Air Filtration

Liu

Ding

Dunne

et al. 2020

Environ. Sci. Technol.

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Design and fabrication of bimodal structures are essential for successful development of advanced air filters with ultralow airflow resistance. To realize this goal, simplified processing procedures are necessary for meeting the practical needs. Here, a bimodal protein fabric with high-performance air filtration, and effectively lowered airflow resistance is reported. The various functional groups of proteins provide versatile interactions with pollutants. By utilizing a novel and cost-effective "cross-axial" configuration with an optimized condition (75°of contacting angle between solution nozzle and cospinning solvent nozzle), the diffusion in Taylor cone is in situ controlled, which results in the successful production of bimodal protein fabric. The bimodal protein fabric (16.7 g/ m 2 areal density) is demonstrated to show excellent filtration performance for removing particulate matter (PM) pollutants and only causes 17.1 Pa air pressure drop. The study of multilayered protein fabric air filters shows a further improvement in filtration performance of removing 97% of PM 0.3 and 99% of PM 2.5 with a low airflow resistance (34.9 Pa). More importantly, the four-layered bimodal protein fabric shows an exceptional long-term performance and maintains a high removal efficiency in the humid environment. This study presents an effective and viable strategy for fabricating bimodal fibrous materials for advanced air filtration.

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Pt1/Ni6Co1 layered double hydroxides/N-doped graphene for electrochemical non-enzymatic glucose sensing by synergistic enhancement of single atoms and doping

et al. 2022

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Juejing Liu

Single-Atom Pt Boosting Electrochemical Nonenzymatic Glucose Sensing on Ni(OH)₂/N-Doped Graphene

A protein-functionalized microfiber/protein nanofiber Bi-layered air filter with synergistically enhanced filtration performance by a viable method

Toward High‐Performance Metal–Organic‐Framework‐Based Quasi‐Solid‐State Electrolytes: Tunable Structures and Electrochemical Properties

A Bimodal Protein Fabric Enabled via In Situ Diffusion for High-Performance Air Filtration

Pt1/Ni6Co1 layered double hydroxides/N-doped graphene for electrochemical non-enzymatic glucose sensing by synergistic enhancement of single atoms and doping

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Juejing Liu

Single-Atom Pt Boosting Electrochemical Nonenzymatic Glucose Sensing on Ni(OH)2/N-Doped Graphene

A protein-functionalized microfiber/protein nanofiber Bi-layered air filter with synergistically enhanced filtration performance by a viable method

Toward High‐Performance Metal–Organic‐Framework‐Based Quasi‐Solid‐State Electrolytes: Tunable Structures and Electrochemical Properties

A Bimodal Protein Fabric Enabled via In Situ Diffusion for High-Performance Air Filtration

Pt1/Ni6Co1 layered double hydroxides/N-doped graphene for electrochemical non-enzymatic glucose sensing by synergistic enhancement of single atoms and doping

Contact Info

Product

Resources

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Single-Atom Pt Boosting Electrochemical Nonenzymatic Glucose Sensing on Ni(OH)₂/N-Doped Graphene