Waste camellia seed shell was placed in the fluidized bed tubular reactor and carbonized at 700 degrees C for the preparation of a carbon material. The obtained-carbon material was simultaneously modified by La3+ and concentrated sulfuric acid for the synthesis of a novel solid Bronsted acid catalyst SO42-/La3+/C by performing impregnation method. Physical and chemical properties and structural characteristics of the SO42-/La3+/C catalyst were characterized and analyzed by several methods. The catalytic activity and stability of SO42-/La3+/C were evaluated from the catalytic synthesis of biodiesel via esterification of oleic acid and methanol. The highest conversion of oleic acid was 98.37 wt% when the mass ratio of catalyst/reactant, mass ratio of methanol to oleic acid, reaction temperature and reaction time were fixed at 0.75 wt%, 9:1, 62 degrees C and 5 h, respectively. Additionally in terms of reusability, the conversion of oleic acid was still 81.9 wt% after SO42-/La3+/C catalyst had been recycled for ten times. The high catalytic activity and stability can be ascribed to the formation of a Six-coordination bond from the interactions of SO42-/La3+, C-OH oxygen of the carboxyl group and H2O. Hence, SO42-/La3+/C will exhibit strong Bronsted acidity and keep high stability in a reaction medium with large amount of H2O. (C) 2017 Elsevier Ltd. All rights reserved.