Assessment of CO₂ Purity and Recovery in Absorption from Natural Gas Wells

Authors

  • Vibianti Dwi Pratiwi Department of Chemical Engineering, Institut Teknologi Nasional Bandung, 40124, Indonesia
  • Dyah Setyo Pertiwi Department of Chemical Engineering, Institut Teknologi Nasional Bandung, 40124, Indonesia
  • Choerudin Choerudin Department of Chemical Engineering, Institut Teknologi Nasional Bandung, 40124, Indonesia
  • Johanes Francoise Department of Chemical Engineering, Institut Teknologi Nasional Bandung, 40124, Indonesia
  • Hugo Hugo Department of Chemical Engineering, National Cheng Kung University, 701401, Taiwan

Abstract

One potential technology to mitigate emissions is Carbon Capture and Storage (CCS) technology. Carbon capture and purification technology is one of the key requirements in the CCSU system, which necessitates a high level of CO2 purity as a raw material for production. In utilizing CO2, different CO2 capture technologies are required to achieve the required purity according to utility standards. Absorption technology is one of the most common and effective methods. In this study, absorption technology was used to capture carbon from gas wells with different concentrations of 10%, 20%, 30%, and 40%. Researchers analyzed the effectiveness of solvents in the CO2 gas absorption process from various CO2 concentrations simulated using Aspen Hysys V.15.0. The simulation results showed the highest purity obtained in the CO2 variation in the 40% feed at 86.58%. In comparison, the highest recovery was found in the CO2 variation of 30% at 99.85%. Although the recovery obtained was high, this study still requires review because the purity achieved was still below the CCUS requirement standard.

References

E. Lismiyah, M. Marselina, A. R. Taher, T. Gunarto, and N. Aida, Jurnal Riset Ilmu Ekonomi 4, 27 (2024)

D. M. Nihayah, I. Mafruhah, L. Hakim, and S. Suryanto, Economies 10, (2022)

V. Dwi Pratiwi, R. Renanto, J. Juwari, R. Panca Anugraha, and R. Arifi n, E3S Web of Conferences 481, 02001 (2024)

F. H. Hendriyansyah, R. Nendry, W. Permatasari, and V. D. Pratiwi, Reaktor 23, 16 (2023)

D. Jenderal, P. Perubahan, I. Kementerian, L. Hidup, and D. Kehutanan, STRATEGI PENCAPAIAN NDC 2030 Dan LTS LCCR 2050 (n.d.)

IEA, Technology Perspectives Energy Special Report on Carbon Capture Utilisation and Storage CCUS in Clean Energy Transitions (2020)

R. Handogo, Juwari, A. Altway, and Annasit, in IOP Conference Series: Materials Science and Engineering 742 (IOP Publishing, 2020), pp. 1–13

A. Mualim, H. Huda, A. Altway, J. P. Sutikno, and R. Handogo, J Clean Prod 291, (2021)

V. Dwi Pratiwi, R. Handogo, R. P. Anugraha, J. Juwari, and R. Arifi n, Chem Eng Commun 211, 1431 (2024)

F. Shokrollahi, K. K. Lau, B. Partoon, and A. M. Smith, J Nat Gas Sci Eng 98, (2022)

V. D. Pratiwi, R. Renanto, J. Juwari, A. Altway, and R. P. Anugraha, Journal of Chemical Technology and Metallurgy 59, 935 (2024)

R. P. Anugraha, V. D. Pratiwi, R. Renanto, J. Juwari, A. N. Islami, and M. Y. Bakhtiar, Chemical Engineering Research and Design 202, 226 (2024)

A. A. Putra, R. Handogo, and R. Gani, Evaluation and Comparison of Carbon Dioxide Capture Using MEA and DEA (2016)

A. A. Putra, Juwari, and R. Handogo, in AIP Conf Proc (American Institute of Physics Inc., 2017)

R. Renanto, T. N. Andhin, and J. Juwari, The Open Chemical Engineering Journal 19, (2025)

A. Mualim, Juwari, A. Altway, and Renanto, Process Integration and Optimization for Sustainability (2022)

R. Handogo, A. Mualim, J. P. Sutikno, and A. Altway, ECS Trans 107, 8593 (2022)

S. Kim, Y. Kim, S. Y. Oh, M. J. Park, and W. B. Lee, J Nat Gas Sci Eng 96, (2021)

U. Pasarai, D. DSM Saputra, and N. Firdaus, Scientifi c Contributions Oil and Gas 44, 97 (2021)

B. T. H. Marbun, D. Santoso, W. G. A. Kadir, A. Wibowo, P. Suardana, H. Prabowo, D. Susilo, D. Sasongko, S. Z. Sinaga, B. A. Purbantanu, J. M. Palilu, and R. Sule, Energy Reports 7, 1598 (2021)

A. Mualim, J. P. Sutikno, A. Altway, and R. Handogo, in (Atlantis Press International B.V., 2022)

P. Panja, T. X. Pack, and M. Deo, Chem Eng Commun 208, 1344 (2021)

H. T. Oh, J. C. Lee, and C. H. Lee, Fuel 314, 122768 (2022)

E. C. Costa, C. C. Ferreira, A. L. B. dos Santos, H. da Silva Vargens, E. G. O. Menezes, V. M. B. Cunha, M. P. da Silva, A. A. Mâncio, N. T. Machado, and M. E. Araújo, Journal of Supercritical Fluids 140, 101 (2018)

M. B. Haider, P. Maheshwari, and R. Kumar, J Environ Chem Eng 9, (2021)

S. T. Sultana and M. R. Amin, Journal of Chemical Engineering 26, 47 (2012)

R. Febrianti, S. R. Trianingtias, V. D. Pratiwi, and G. P. Gemilar, in (2024), pp. 115–127

J. Zhao, Q. Zhang, W. Hao, and Q. Su, Process Safety and Environmental Protection 174, 1023 (2023)

Downloads

Published

2026-02-12

Issue

FOITIC 2025

Section

FOITIC 2025