PDF
Abstract
This study evaluates the environmental sustainability of brackish water desalination using photo-electrodialysis (photo-ED). A cradle-to-gate life cycle assessment (LCA) was conducted for a small-scale theoretical photo-ED desalination plant in Qatar. The system employs a Pt/Ir-coated titanium photo-anode that harnesses sunlight to drive ion transport. The assessment covers brackish water extraction, pre-treatment, photo-ED cell operation, and post-treatment. Life cycle impact assessment (LCIA) results indicate a global warming potential (GWP) of 2.65 kg CO2 eq/m3 of freshwater produced, with operational electricity contributing 94% of this impact. Additional environmental impact categories assessed include acidification potential (AP), eutrophication potential (EP), freshwater aquatic ecotoxicity (FAE), abiotic depletion potential (ADP), and terrestrial ecotoxicity (TE). Operational electricity was the dominant contributor to all categories except ADP. Moreover, the use of platinum, ruthenium, and iridium in the electrode coating process significantly increased FAE and TE impacts. A sensitivity analysis of electricity sources reveals that replacing conventional electricity with renewable wind energy can reduce the GWP to 0.325 kg CO2 eq/m3. These findings highlight the potential of green energy in mitigating environmental impacts.
Keywords
Desalination
/
life cycle assessment
/
photo-electrodialysis
/
sustainability
Cite this article
Download citation ▾
Namra Mir, Yusuf Bicer.
Life cycle assessment of photo-electrodialysis for freshwater production: A Qatar-based study.
Carbon Footprints, 2025, 4(4): 23 DOI:10.20517/cf.2025.16
| [1] |
Water scarcity. Available from: https://www.unicef.org/wash/water-scarcity [Last accessed on 27 Aug 2025]
|
| [2] |
Tashtoush B,Al Ghadi M,Morosuk T.Renewable energy integration in water desalination: State-of-the-art review and comparative analysis.Appl Energy2023;352:121950
|
| [3] |
Boretti A.Reassessing the projections of the world water development report.NPJ Clean Water2019;2:39
|
| [4] |
Ghimire U,Gude VG.Transitioning wastewater treatment plants toward circular economy and energy sustainability.ACS Omega2021;6:11794-803 PMCID:PMC8154022
|
| [5] |
Mir N.Thermodynamic modeling of a combined photo-electrodialysis-chloralkali system for sustainable desalination.Desalination2021;499:114822
|
| [6] |
Khan MI,Mondal AN.Preparation of anion exchange membranes from BPPO and dimethylethanolamine for electrodialysis.Desalination2017;402:10-8
|
| [7] |
Patel SK,Westerhoff P.The potential of electrodialysis as a cost-effective alternative to reverse osmosis for brackish water desalination.Water Res2024;250:121009
|
| [8] |
Mir N.Integration of electrodialysis with renewable energy sources for sustainable freshwater production: a review.J Environ Manag2021;289:112496
|
| [9] |
Gonzalez A,Ushak S.Assessment of pilot-scale water purification module with electrodialysis technology and solar energy.Appl Energy2017;206:1643-52
|
| [10] |
Campione A,Calise F,Galluzzo M.Coupling electrodialysis desalination with photovoltaic and wind energy systems for energy storage: dynamic simulations and control strategy.Energy Convers Manag2020;216:112940
|
| [11] |
He W,Amrose S,Peters IM.Preliminary field test results from a photovoltaic electrodialysis brackish water desalination system in rural India; 2018.
|
| [12] |
Rheinländer J.Photovoltaic reverse osmosis and electrodialysis.Green Energy Technol2009;189-211
|
| [13] |
Malek P,Schulte-Herbrüggen H.Decentralized desalination of brackish water using an electrodialysis system directly powered by wind energy.Desalination2016;377:54-64
|
| [14] |
Veza JM,Castellano F.Electrodialysis desalination designed for wind energy (on-grid tests).Desalination2001;141:53-61
|
| [15] |
Liang M,Wei Q.The progress and prospect of the solar-driven photoelectrochemical desalination.Renew Sustain Energy Rev2022;155:111864
|
| [16] |
Bensaadi S,Amrane A.Dialysis and photo-electrodialysis processes using new synthesized polymeric membranes for the selective removal of bivalent cations.J Environ Chem Eng2017;5:1037-47
|
| [17] |
Murphy GW.Desalination by photoelectrodialysis.J Electrochem Soc1980;127:2088-90
|
| [18] |
Hamane D,Kaouah F,Kerdjoudj H.Adsorption/photo-electrodialysis combination system for Pb2+ removal using bentonite/membrane/semiconductor.J Environ Chem Eng2015;3:60-9
|
| [19] |
Cherif AY,Amara M,Kerdjoudj H.Synthesis of modified polymer inclusion membranes for photo-electrodeposition of cadmium using polarized electrodes.J Hazard Mater2012;227-8:386-93
|
| [20] |
Khiter A,Nasrallah N.Removal of lead by membrane photo-electrolysis.Sep Purif Technol2025;378:134565
|
| [21] |
Chaurasiya A,Shah G,Singh S.Carbon-based electrodes for photo-bio-electrocatalytic microbial fuel and electrolysis cells: advances and perspectives.Mater Horiz2025;Online ahead of print
|
| [22] |
Mir N,Bicer Y.Photo-electrodialysis for brackish water desalination: a life cycle sustainability assessment from experimental insights.Energy Technol2025;2402079
|
| [23] |
Elsaid K,Sayed ET,Wilberforce T.Environmental impact of desalination technologies: a review.Sci Total Environ2020;748:141528
|
| [24] |
Finnveden G,Ekvall T.Recent developments in life cycle assessment.J Environ Manag2009;91:1-21
|
| [25] |
Xu J,Xu G,Vail T.A critical review of ISO standards for seawater desalination: classification, applications, and future development.Sep Purif Technol2025;367:132898
|
| [26] |
Biswas WK.Improving the carbon footprint of water treatment with renewable energy: a Western Australian case study.Renewables2016;3:36
|
| [27] |
Mueller KE,Johnson JX,Call DF.Life cycle assessment of salinity gradient energy recovery using reverse electrodialysis.J Ind Ecol2021;25:1194-206
|
| [28] |
Rasmi K,George RP.Performance evaluation of platinum nanoparticle-coated titanium electrodes.Mater Perform2017;56:48-52
|
| [29] |
ISO 14040:2006. Environmental management - Life cycle assessment - Principles and framework. Available from: https://www.iso.org/standard/37456.html [Last accessed on 27 Aug 2025]
|
| [30] |
Mueller KE,Johnson JX,Call DF.Life cycle assessment of salinity gradient energy recovery using reverse electrodialysis.J Ind Ecol2021;25:1194-1206
|
| [31] |
Veerman J,Metz SJ.Reverse electrodialysis: evaluation of suitable electrode systems.J Appl Electrochem2010;40:1461-74
|
| [32] |
Mudali U, Raju V, Dayal R. Preparation and characterisation of platinum and platinum–iridium coated titanium electrodes.J Nucl Mater2000;277:49-56
|
| [33] |
Zeynali ME,Sadri HR.Effect of operating conditions on divinylbenzene production in diethyl benzene dehydrogenation reactor.Iran J Chem Chem Eng2018;15Available from: https://www.ijche.com/article_80773.html [Last accessed on 1 Sep 2025]
|
| [34] |
Camps M,Monthéard J.Chloromethylstyrene: synthesis, polymerization, transformations, applications.J Macromol Sci Part C1982;22:343-407
|
| [35] |
Chloroplatinic Acid Formula: Structure, Preparations and Properties. Available from: https://www.toppr.com/guides/chemistry-formulas/chloroplatinic-acid-formula/ [Last accessed on 27 Aug 2025].
|
| [36] |
Zhou J,Fane AG.Environmental life cycle assessment of brackish water reverse osmosis desalination for different electricity production models.Energy Environ Sci2011;4:2267-78
|
| [37] |
Fernandez-Gonzalez C,Ibañez R.Sustainability assessment of electrodialysis powered by photovoltaic solar energy for freshwater production.Renew Sustain Energy Rev2015;47:604-15
|
