@article{scholars13757, pages = {1--10}, title = {The effect of composition on CO2 Freeze-Out and Critical Locus of Binary CO2{\^a}??CH4 Mixture}, journal = {Lecture Notes in Mechanical Engineering}, publisher = {Springer Science and Business Media Deutschland GmbH}, doi = {10.1007/978-981-15-5753-8{$_1$}}, year = {2020}, note = {cited By 1; Conference of 5th International Conference on Mechanical, Manufacturing and Plant Engineering, ICMMPE 2019 ; Conference Date: 19 November 2019 Through 21 November 2019; Conference Code:244879}, issn = {21954356}, author = {Babar, M. and Bustam, M. A. and Ali, A. H. and Maulud, A. S. and Abdulrahman, A.}, isbn = {9789811557521}, url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85091276125&doi=10.1007\%2f978-981-15-5753-8\%5f1&partnerID=40&md5=9713a1c5612a86e26bde68c0e12646fb}, abstract = {Cryogenic CO2 capture technology is one of the emerging technologies used for natural gas purification. Thermodynamic phase study of the natural gas has a significant effect on the cryogenic CO2 removal from natural gas. The present work describes the impact of composition on CO2 freeze-out and critical locus of the binary CO2{\^a}??CH4 mixtures with different CO2 content. Critical locus and CO2 freeze-out were modelled for nine binary CO2{\^a}??CH4 mixtures and were correlated with the composition of the binary mixtures. Aspen HYSYS version 8.0 with the Peng Robinson equation of state and Eureka modelling tool were used in the present research work. It was found that the predicted models can precisely calculate the CO2 freeze-out point and the critical locus of the mixtures. By comparing the calculated data with the reported experimental data, an excellent agreement was found. R-squared value for the models was 0.99, which shows the reliability of the models. The effect of composition on three-phase loci of the binary and multicomponent mixtures of CO2 with light H.C is recommended for future research. {\^A}{\copyright} Springer Nature Singapore Pte Ltd 2020.} }