Soot surface area evolution during air oxidation as evaluated by small angle X-ray scattering and CO2 adsorption Original Research Article

The total surface area of two diesel engine produced soots, a high volatile content NIST standard (termed NIST) and a low volatile content soot (termed NEU), were determined with CO2 adsorption and small angle X-ray scattering (SAXS), as a function of the extent of oxidation. During initial volatilization of condensables of the NIST and NEU soots in a thermogravimetric analyzer, in helium at 1073 K, their CO2 surface areas increased sharply from 49 m2/g to 273 m2/g and from 96 m2/g to 367 m2/g, respectively. During oxidation, the CO2 surface area increased by an additional 100–150 m2/g, until 50% conversion was reached. Thereafter, the CO2 surface area was relatively constant with conversion for the NIST soot, but decreased to 150 m2/g for the NEU soot. Three porosity regimes were assumed for the calculation of SAXS areas; they were based on (a) constant density (shrinking core), (b) constant diameter, and (c) an observed (with a TEM) diameter variation. The best agreement between the CO2 and SAXS surfaces area occurred for the constant density assumption, in contrast to the actual measured diameter variation. By applying fractal surface analysis to the SAXS data, this discrepancy is ascribed to the opening up of internal volume to reaction volatilization of condensables and oxidation.