TY - JOUR

T1 - Structure–selectivity relationship of a zirconia-based heterogeneous acid catalyst in the production of green mono- and dioleate product

AU - Kong, P.S.

AU - Pérès, Y.

AU - Cognet, P.

AU - Senocq, F.

AU - Daud, W.M.A.W.

AU - Aroua, M.K.

AU - Ahmad, H.

AU - Sankaran, R.

AU - Show, P.L.

PY - 2021/1/1

Y1 - 2021/1/1

N2 - Abstract: A novel catalytic technique is vital to produce mono- and dioleate (GMO and GDO) from bioglycerol: a renewable resource and by-product of biodiesel. The advantage of this invention is the direct production of GMO and GDO through catalytic approach compared to the conventional method that requires transesterification and distillation processes. In this paper, glycerol esterification with oleic acid using a catalyst was experimented. The process was carried out over a hydrophobic mesoporous zirconia–silica heterogeneous acid catalyst (ZrO2–SiO2–Me&Et–PhSO3H) with three types of sulphated zirconia catalysts (SO42−/ZrO 2) to produce high-selectivity GMO and GDO products. The catalytic performance of the hydrophobic ZrO 2–SiO 2–Me&Et–PhSO 3H catalyst was benchmarked with that of SO42−/ZrO 2 which was developed from three zirconium precursors. Results showed that the pore volume and hydrophobicity of the designed catalyst greatly could influence the product selectivity, thus enabling smaller substrates GMO and GDO to be dominated in the synthesis. This finding was supported by characterisation data obtained through N 2 adsorption–desorption, X-ray diffraction and scanning electron microscopy. In addition, a good correlation was found between pore volume (pore size) and product selectivity. High pore volume catalyst favoured GDO production under identical reaction conditions. Pore volume and size can be used to control product sensitivity. The hydrophobicity of the catalyst was found to improve the initial reaction rate effectively. 

AB - Abstract: A novel catalytic technique is vital to produce mono- and dioleate (GMO and GDO) from bioglycerol: a renewable resource and by-product of biodiesel. The advantage of this invention is the direct production of GMO and GDO through catalytic approach compared to the conventional method that requires transesterification and distillation processes. In this paper, glycerol esterification with oleic acid using a catalyst was experimented. The process was carried out over a hydrophobic mesoporous zirconia–silica heterogeneous acid catalyst (ZrO2–SiO2–Me&Et–PhSO3H) with three types of sulphated zirconia catalysts (SO42−/ZrO 2) to produce high-selectivity GMO and GDO products. The catalytic performance of the hydrophobic ZrO 2–SiO 2–Me&Et–PhSO 3H catalyst was benchmarked with that of SO42−/ZrO 2 which was developed from three zirconium precursors. Results showed that the pore volume and hydrophobicity of the designed catalyst greatly could influence the product selectivity, thus enabling smaller substrates GMO and GDO to be dominated in the synthesis. This finding was supported by characterisation data obtained through N 2 adsorption–desorption, X-ray diffraction and scanning electron microscopy. In addition, a good correlation was found between pore volume (pore size) and product selectivity. High pore volume catalyst favoured GDO production under identical reaction conditions. Pore volume and size can be used to control product sensitivity. The hydrophobicity of the catalyst was found to improve the initial reaction rate effectively. 

KW - Esterification

KW - Glycerol

KW - Hydrophobic silica–zirconia-based catalyst

KW - Selectivity

KW - Structural

KW - Sulphated zirconia

KW - Distillation

KW - Esters

KW - Hydrophobicity

KW - Pore size

KW - Scanning electron microscopy

KW - Silica

KW - Silicon

KW - Zirconia

KW - Catalytic performance

KW - Glycerol esterifications

KW - Heterogeneous acid catalysts

KW - Product selectivities

KW - Selectivity relationships

KW - Zirconium precursors

KW - Catalyst selectivity

U2 - 10.1007/s10098-020-01830-1

DO - 10.1007/s10098-020-01830-1

M3 - Journal article

VL - 23

SP - 19

EP - 29

JO - Clean Technologies and Environmental Policy

JF - Clean Technologies and Environmental Policy

ER -