Litcius/Paper detail

A Particle-Driven, Ultrafast-Cured Strategy for Tuning the Network Cavity Size of Membranes with Outstanding Pervaporation Performance

Zhihao Si, Guozhen Li, Ze Wang, Di Cai, Shufeng Li, Jan Baeyens, Peiyong Qin

2020ACS Applied Materials & Interfaces38 citationsDOI

Abstract

Poly(dimethylsiloxane) (PDMS) membranes are widely used for bioethanol separation. However, the network cavity size r 3 of PDMS membranes is generally smaller than the ethanol kinetic radius (0.225 nm), which limits the transport of ethanol molecules and weakens the pervaporation performance. Herein, we proposed a particle-driven, ultrafast-cured strategy to overcome the above key issue: (1) Incorporating particles into PDMS for preventing polymer chains from packing tightly, (2) freezing particles within a PDMS layer by the ultrafast UV-cross-linking for improving its distribution and increasing the chain extension of the polymer, and (3) covalently bonding particles with PDMS to enhance their compatibility. Consequently, r 3 was increased to 0.262 nm, and an extremely high loading membrane (50 wt %) with an ultrashort curing time (20 s) was prepared, which is difficult to be realized by the conventional thermally driven approach. As a result, a separation factor of 13.4 with a total flux of 2207 g m –2 h –1 for separating ethanol from a 5 wt % aqueous solution at 60 °C was obtained. This strategy shows the feasibility of recovery of different bioalcohols and the large-scale continuous membrane preparation.

Topics & Concepts

Materials sciencePervaporationMembraneParticle sizeParticle (ecology)Ultrashort pulseNanotechnologyChemical engineeringOpticsEngineeringGeologyLaserPhysicsPermeationBiologyOceanographyGeneticsMembrane Separation and Gas TransportMembrane Separation TechnologiesGraphene research and applications
A Particle-Driven, Ultrafast-Cured Strategy for Tuning the Network Cavity Size of Membranes with Outstanding Pervaporation Performance | Litcius