eprintid: 15578 rev_number: 2 eprint_status: archive userid: 1 dir: disk0/00/01/55/78 datestamp: 2023-11-10 03:30:12 lastmod: 2023-11-10 03:30:12 status_changed: 2023-11-10 01:59:50 type: conference_item metadata_visibility: show creators_name: Yusof, M.A.M. creators_name: Ibrahim, M.A. creators_name: Mohamed, M.A. creators_name: Akhir, N.A.M. creators_name: Saaid, I.M. creators_name: Ahamed, M.N.Z. creators_name: Idris, A.K. creators_name: Matali, A.A.A.A. title: Predictive Modelling of CO2 Injectivity Impairment due to Salt Precipitation and Fines Migration During Sequestration ispublished: pub keywords: Floods; Gasoline; Jamming; Oil well flooding; Particle size; Precipitation (chemical); Sandstone; Silica; Sodium chloride, Change modeling; Co 2 injections; Fines migration; Injection flow rate; Injectivity; Particles concentration; Permeability reduction; Predictive models; Salt precipitation; Supercritical CO 2, Carbon dioxide note: cited By 9; Conference of 2021 International Petroleum Technology Conference, IPTC 2021 ; Conference Date: 23 March 2021 Through 1 April 2021; Conference Code:187135 abstract: Recent studies indicated that reactive interactions between carbon dioxide (CO2), brine, and rock during CO2 sequestration can cause salt precipitation and fines migration. These mechanisms can severely impair the permeability of sandstone which directly affect the injectivity of supercritical CO2 (scCO2). Previous CO2 injectivity change models are ascribed by porosity change due to salt precipitation without considering the alteration contributed by the migration of particles. Therefore, this paper presents the application of response surface methodology to predict the CO2 injectivity change resulting from the combination of salt precipitation and fines migration. The impacts of independent and combined interactions between CO2, brine, and rock parameters were also evaluated by injecting scCO2 into brine saturated sandstone. The core samples were saturated with NaCl brine with salinity between 6, 000 ppm to 100, 000 ppm. The 0.1, 0.3, and 0.5 wt. of different-sized hydrophilic silicon dioxide particles (0.005, 0.015, and 0.060 μm) were added to evaluate the effect of fines migration on CO2 injectivity alteration. The pressure drop profiles were recorded throughout the injection process and the CO2 injectivity alteration was represented by the ratio between the initial and final injectivity. The experimental results showed that brine salinity has a greater individual influence on permeability reduction as compared to the influence of particles (jamming ratio and particle concentration) and scCO2 injection flow rate. Moreover, the presence of both fines migration and salt precipitation during CO2 injection was also found to intensify the permeability reduction by 10, and reaching up to threefold with increasing brine salinity and particle size. The most significant reductions in permeability were observed at higher brine salinities, as more salts are being precipitated out which, in turn, reduces the available pore spaces and leads to a higher jamming ratio. Thus, more particles were blocked and plugged especially at the slimmer pore throats. Based on comprehensive 45 core flooding experimental data, the newly developed model was able to capture a precise correlation between four input variables (brine salinity, injection flow rate, jamming ratio, and particle concentration) and CO2 injectivity changes. The relationship was also statistically validated with reported data from five case studies. Copyright © 2021, International Petroleum Technology Conference. date: 2021 publisher: International Petroleum Technology Conference (IPTC) official_url: https://www.scopus.com/inward/record.uri?eid=2-s2.0-85123068875&doi=10.2523%2fIPTC-21483-MS&partnerID=40&md5=6af3af88bbbe601e6a7754cf22a94ab7 id_number: 10.2523/IPTC-21483-MS full_text_status: none publication: International Petroleum Technology Conference, IPTC 2021 refereed: TRUE isbn: 9781613997314 citation: Yusof, M.A.M. and Ibrahim, M.A. and Mohamed, M.A. and Akhir, N.A.M. and Saaid, I.M. and Ahamed, M.N.Z. and Idris, A.K. and Matali, A.A.A.A. (2021) Predictive Modelling of CO2 Injectivity Impairment due to Salt Precipitation and Fines Migration During Sequestration. In: UNSPECIFIED.