<> "The repository administrator has not yet configured an RDF license."^^ . <> . . . "High-temperature CO2 removal from CH4 using silica membrane: experimental and neural network modeling"^^ . "Inorganic membranes can operate under harsh conditions. However, successful synthesis of inorganic membranes is still challenging, and its performance depends on many factors. This work reports the effect of dip-coating duration, inlet pressure, and inlet flow rate on the flux, permeability, and selectivity of silica membranes. A silica membrane was prepared by the deposition of silica sol onto porous alumina support. The permeability test was conducted at 100 °C using a single gas of CO2 and CH4. The highest flux was observed at the maximum inlet pressure and inlet flow rate for the membrane prepared at the minimum dip-coating duration. The neural network modeling of the membrane predicted permeabilities showed a considerably high validity regression (R � 0.99) of the predicted data linked to the experimental sets. The separation factor (α) was the highest at the maximum dip-coating duration. The synthesized silica membrane has potential for CO2/CH4 separation under harsh operating conditions. © 2019 Society of Chemical Industry and John Wiley & Sons, Ltd. © 2019 Society of Chemical Industry and John Wiley & Sons, Ltd."^^ . "2019" . . "9" . "5" . . "John Wiley and Sons Inc"^^ . . . "Greenhouse Gases: Science and Technology"^^ . . . "21523878" . . . . . . . . . . . . . . . . . . . . . . . . . . . . "H."^^ . "Abdul Mannan"^^ . "H. Abdul Mannan"^^ . . "F.A."^^ . "Abdulkareem"^^ . "F.A. Abdulkareem"^^ . . "M.A."^^ . "Bustam"^^ . "M.A. Bustam"^^ . . "M.A."^^ . "Assiri"^^ . "M.A. Assiri"^^ . . "A."^^ . "Irfan"^^ . "A. Irfan"^^ . . "S."^^ . "Ullah"^^ . "S. Ullah"^^ . . "A.G."^^ . "Al-Sehemi"^^ . "A.G. Al-Sehemi"^^ . . "S."^^ . "Saqib"^^ . "S. Saqib"^^ . . . . . "HTML Summary of #11278 \n\nHigh-temperature CO2 removal from CH4 using silica membrane: experimental and neural network modeling\n\n" . "text/html" . .