Bo Li scite author profile

An enzyme, horseradish peroxidase (HRP), was adsorbed in the manner of the single immersion method on the silica mesoporous materials FSM-16, MCM-41, and SBA-15 with various pore diameters from 27 to 92 Å, and their enzymatic activities in an organic solvent and the thermal stabilities were studied. FSM-16 and MCM-41 showed a larger amount of adsorption of HRP than SBA-15 or silica gel when the pore sizes were larger than the 50 Å. The increased enzyme adsorption capacity may be due to the surface characteristics of FSM-16 and MCM-41, which would be consistent with the observed larger adsorption capacity of cationic pigment compared with anionic pigment for these materials. The immobilized HRP on FSM-16 and MCM-41 with pore diameter 50 Å showed the highest enzymatic activity in an organic toluene and thermal stability in aqueous solution at the temperature of 70 °C. The immobilized enzymes on the other mesoporous materials including large or small pore sized FSM-16 showed lower enzymatic activity in an organic solvent and thermal stability. Both surface character and size matching between pore sizes and the molecular diameters of HRP were important in achieving high enzymatic activity in organic solvent and high thermal stability.

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Immobilized enzymes in ordered mesoporous silica materials and improvement of their stability and catalytic activity in an organic solvent

Takahashi

Sasaki

et al. 2001

Microporous and Mesoporous Materials

274

179

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Electrochemical synthesis of luminescent MoS₂ quantum dots

et al. 2015

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Size-controlled synthesis of luminescent quantum dots of MoS2 (≤2 layers) with narrow size distribution, ranging from 2.5 to 6 nm, from their bulk material using a unique electrochemical etching of bulk MoS2 is demonstrated. Excitation-dependent photoluminescence emission is observed in the MoS2 QDs. "As-synthesized" MoS2 QDs also exhibit excellent electrocatalytic activity towards hydrogen evolution reactions.

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Enhancing catalytic activity and stability for CO₂ methanation on Ni@MOF-5 via control of active species dispersion

et al. 2015

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Bo Li

Catalytic Activity in Organic Solvents and Stability of Immobilized Enzymes Depend on the Pore Size and Surface Characteristics of Mesoporous Silica

Immobilized enzymes in ordered mesoporous silica materials and improvement of their stability and catalytic activity in an organic solvent

Electrochemical synthesis of luminescent MoS₂ quantum dots

Enhancing catalytic activity and stability for CO₂ methanation on Ni@MOF-5 via control of active species dispersion

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Bo Li

Catalytic Activity in Organic Solvents and Stability of Immobilized Enzymes Depend on the Pore Size and Surface Characteristics of Mesoporous Silica

Immobilized enzymes in ordered mesoporous silica materials and improvement of their stability and catalytic activity in an organic solvent

Electrochemical synthesis of luminescent MoS2 quantum dots

Enhancing catalytic activity and stability for CO2 methanation on Ni@MOF-5 via control of active species dispersion

Contact Info

Product

Resources

About

Electrochemical synthesis of luminescent MoS₂ quantum dots

Enhancing catalytic activity and stability for CO₂ methanation on Ni@MOF-5 via control of active species dispersion