@Article{ee.2026.077231,
AUTHOR = {Emmanuel E. Anyanwu, Obinna I. Anyanwu, Princewill Ikpeka},
TITLE = {Hybrid Life Cycle Assessment of a Nano-Enhanced Phase Change Material (NEPCM) Integrated Double-Effect Single-Slope Solar Still in Nigeria},
JOURNAL = {Energy Engineering},
VOLUME = {},
YEAR = {},
NUMBER = {},
PAGES = {{pages}},
URL = {http://www.techscience.com/energy/online/detail/26746},
ISSN = {1546-0118},
ABSTRACT = {Increasing demand for freshwater and the need to reduce the carbon intensity of conventional desalination have accelerated interest in solar-driven distillation technologies. This study performs a cradle-to-grave Life-Cycle Assessment (LCA) of a nano-enhanced, double-effect single-slope Solar Still fabricated in Nigeria to quantify its embodied environmental impacts and identify material-level hotspots. Modeling was conducted in openLCA v2.4.1 using the Australian Life-Cycle Inventory (2019) database as a proxy. The functional unit was defined as the production of 1 m<sup>3</sup> of freshwater distillate over a ten-year operational lifetime. From the analysis, the total Global Warming Potential (GWP<sub>100</sub>) of the fabricated Solar Still was 337.3 kg CO<sub>2</sub>-eq, which corresponds to a normalized carbon intensity of 25.21 kg CO<sub>2</sub>-eq m<sup>−3</sup> for a lifetime yield of 13.38 m<sup>3</sup>. Contribution analysis revealed that Al<sub>2</sub>O<sub>3</sub> nanoparticles (31.5%), paraffin wax PCM (22%), and galvanized steel (19%) and glass (13%) together account for more than 85% of total embodied emissions, confirming that the Solar-Still’s footprint is materials-dominated. When benchmarked against conventional desalination, the system’s carbon intensity lies above reverse osmosis but within the upper range of multi-stage flash distillation, with the advantage of zero operational emissions. Sensitivity analyses were performed to examine the influence of nano-enhanced PCM content, alumina concentration, and system lifespan on overall impacts. The novelty of this study lies in the hybrid-LCI approach adopted to provide a replicable framework for evaluating nanomaterial-enhanced renewable-energy systems in emerging regions. Key opportunities for improvement through bio-based or recyclable PCMs, low-impact nanomaterial synthesis, and design optimization to enhance productivity and material circularity were also highlighted in the study.},
DOI = {10.32604/ee.2026.077231}
}