5 Papers
Gregory Staib is an academic researcher from Commonwealth Scientific and Industrial Research Organisation. The author has contributed to research in topics: Sorption & Diffusion (business). The author has an hindex of 5, co-authored 5 publications. Previous affiliations of Gregory Staib include Griffith University.
Chat about Author
Papers
First international inter-laboratory comparison of high-pressure CH4, CO2 and C2H6 sorption isotherms on carbonaceous shales
Matus Gasparik,Thomas Rexer,Andrew C. Aplin,Pierre Billemont,Guy De Weireld,Yves Gensterblum,Mathieu Henry,Bernhard M. Krooss,Shaobo Liu,Xingzhi Ma,Richard Sakurovs,Zhiguang Song,Gregory Staib,K. Mark Thomas,Sibo Wang,Tongwei Zhang +15 more
TL;DR: In this paper, an inter-laboratory study of high-pressure gas sorption measurements on two carbonaceous shales has been conducted in order to assess the reproducibility of the sorption isotherms and identify possible sources of error.
152
A pressure and concentration dependence of CO2 diffusion in two Australian bituminous coals
TL;DR: In this article, experimental CO 2 kinetic sorption data was obtained for two Australian bituminous coals over a range of pressure conditions and analysed using three different models, including unipore, bidisperse and Fickian diffusion-relaxation models.
110
Kinetics of coal swelling in gases: Influence of gas pressure, gas type and coal type
TL;DR: In this article, the authors investigated the physical mechanism responsible for gas-induced swelling in coal and found that swelling rates are influenced by gas type, including CO2 and CH4, Xe and ethane.
34
Dispersive diffusion of gases in coals. Part I: Model development
TL;DR: In this article, the authors developed a model that assumes a distribution of characteristic times for diffusion in coal, which couples a characteristic rate parameter, k ∅, with a stretching parameter, β (0).
Dispersive diffusion of gases in coals. Part II: An assessment of previously proposed physical mechanisms of diffusion in coal
TL;DR: In this article, the authors investigated the rates of gas sorption in an Australian, high-volatile, bituminous coal as a function of particle size, temperature and gas type on sorption kinetics.