Article ID Journal Published Year Pages File Type
230267 The Journal of Supercritical Fluids 2015 11 Pages PDF
Abstract

•Broad portfolio of hybrid alginate-based aerogels presented.•High surface area (≤812 m2/g) and excellent thermal insulation (λ ≥ 18.5 mW/m K).•CO2 induced gelation technique used to liberate cations for alginate crosslinking.•Entrapment of titania and silica in alginate aerogels demonstrated (aerogel glue).•CO2 induced gelation of cellulose and chitosan presented.

This paper presents a technique of manufacturing alginate-based hybrid aerogels. The technique involves mixing a second component (biopolymers or filler materials) in sodium alginate solution and crosslinking with carbonates of metals like calcium, strontium, cobalt, nickel, zinc and copper. Various biopolymers (lignin, starch, pectin, carrageenan, methyl and carboxymethyl cellulose, gellan gum, and gelatin), polymers (PVA, PEG, Pluronic P-123), inorganic (sodium silicate) and filler materials (titania and hydrophobic silica) were used as the second component. It is suggested to use pressurized carbon dioxide (5 MPa) for gelation and supercritical CO2 drying (10–12 MPa) to yield aerogels. Obtained aerogels are ultra-porous with low density (as low as 0.017 g/cm3), high specific surface area (200–800 m2/g) and pore volume (2.3–9.5 cm3/g for pore sizes < 150 nm). Basic examples expressing the applicability of these aerogels are demonstrated such as in the field of thermal insulation (thermal conductivity in the range 18.5–21.6 mW/m K). Extension of carbon dioxide gelation technique from metal-crosslinked alginate-based system to other biopolymers (cellulose and chitosan) is also demonstrated.

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Physical Sciences and Engineering Chemical Engineering Chemical Engineering (General)
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