| Title | Synergistic approach for carbon dioxide capture and reject brine treatment: Integrating selective electrodialysis and bipolar membrane electrodialysis |
|---|---|
| ID_Doc | 13102 |
| Authors | Mustafa, J; Ghasem, N; El-Naas, M; van der Bruggen, B; Al-Marzouqi, AH |
| Title | Synergistic approach for carbon dioxide capture and reject brine treatment: Integrating selective electrodialysis and bipolar membrane electrodialysis |
| Year | 2024 |
| Published | |
| Abstract | Reject brine and carbon dioxide are pollutants commonly released by industries. These pollutants often contain different types of ions, including monovalent and multivalent ions. Multivalent ions like calcium, magnesium, and sulfate can cause problems by fouling membranes and equipment. Therefore, it is important to separate these ions from the reject brine. In the context of the circular economy, it is crucial to both capture carbon dioxide and manage reject brine at the same time. To facilitate carbon dioxide capture and effective reject brine management, we propose an integrated approach that combines membrane-based technologies: selective electrodialysis (SED) and bipolar membrane electrodialysis (BMED). This integration aims to optimize the process for valorization, generating value-added products such as hydrochloric acid, carbonate/bicarbonate salts, irrigation standard water (suitable for plants that can survive in harsh conditions), and brine (sodium chloride purity of 93%). SED and BMED were separately optimized, and the effects of various factors on their performance were investigated. Several factors were considered to assess the energy consumption and separation efficiency of SED. These factors included current density, flow rate (diluate/concentrate), electrolyte flow rate, number of cell pairs, and membrane type. The energy consumption and performance of BMED were investigated by considering factors such as current density, cell pairs, and carbon dioxide flow rate. The results indicated that divalent cations, such as calcium and magnesium, are more readily rejected during selective electrodialysis than divalent anions, such as sulfate. Under optimum conditions, an average carbon dioxide capture efficiency of 51% was achieved through BMED. |
Similar Articles
| ID | Score | Article |
|---|---|---|
22276
|
Reig, M; Valderrama, C; Gibert, O; Cortina, JL Selectrodialysis and bipolar membrane electrodialysis combination for industrial process brines treatment: Monovalent-divalent ions separation and acid and base production(2016) | |
| 2460
|
Cournoyer, A; Bazinet, L Electrodialysis Processes an Answer to Industrial Sustainability: Toward the Concept of Eco-Circular Economy?-A Review(2023)Membranes, 13, 2 | |
| 14677
|
Cerrillo-Gonzalez, MD; Villen-Guzman, M; Rodriguez-Maroto, JM; Paz-Garcia, JM Metal Recovery from Wastewater Using Electrodialysis Separation(2024)Metals, 14, 1 | |
| 23206
|
Cassaro, C; Virruso, G; Culcasi, A; Cipollina, A; Tamburini, A; Micale, G Electrodialysis with Bipolar Membranes for the Sustainable Production of Chemicals from Seawater Brines at Pilot Plant Scale(2023)Acs Sustainable Chemistry & Engineering, 11, 7 | |
| 21846
|
Kyllönen, H; Järvelä, E; Torvinen, O; Grönroos, A Membrane concept for valorization of bicarbonate in sulfate-reduced effluent(2020) | |
| 22488
|
Herrero-Gonzalez, M; Diaz-Guridi, P; Dominguez-Ramos, A; Irabien, A; Ibañez, R Highly concentrated HCl and NaOH from brines using electrodialysis with bipolar membranes(2020) | |
| 15493
|
Wei, CY; Pan, SY; Lin, YI; Cao, TND Anaerobic swine digestate valorization via energy-efficient electrodialysis for nutrient recovery and water reclamation(2022) | |
| 17079
|
Herrero-Gonzalez, M; Ibañez, R Technical and Environmental Feasibilities of the Commercial Production of NaOH from Brine by Means of an Integrated EDBM and Evaporation Process(2022)Membranes, 12, 9 | |
| 12506
|
Reig, M; Casas, S; Valderrama, C; Gibert, O; Cortina, JL Integration of monopolar and bipolar electrodialysis for valorization of seawater reverse osmosis desalination brines: Production of strong acid and base(2016) | |
| 16669
|
Culcasi, A; Ktori, R; Pellegrino, A; Rodriguez-Pascual, M; van Loosdrecht, MCM; Tamburini, A; Cipollina, A; Xevgenos, D; Micale, G Towards sustainable production of minerals and chemicals through seawater brine treatment using Eutectic freeze crystallization and Electrodialysis with bipolar membranes(2022) |