Assessment of the life cycle of photovoltaic solar technologies for sustainable energy transitions: Implications for climate policy and low-carbon system integration

Publication Type

Journal Article

Name of Author

• Wakiang Emile Latchiba, Condensed Matter Research Group, Department of Physics, University of NairobiFollow
• Sebastian Waita, Condensed Matter Research Group, Department of Physics, University of Nairobi
• Julius M. Mwabora, Condensed Matter Research Group, Department of Physics, University of Nairobi

Publication Date (Issue Year)

2026

Journal Name

Resources, Environment and Sustainability

Abstract

The rapid expansion of photovoltaic (PV) deployment demands integrated environmental and economic evaluation of emerging technologies. This study compares crystalline silicon (c-Si), perovskite, and hybrid perovskitesilicon tandem PV systems using a cradle-to-grave Life Cycle Assessment (LCA) combined with Techno-economic Analysis (TEA) to measure environmental impacts, resource efficiency, and cost performance. Environmental indicators include life cycle greenhouse gas emissions, total energy demand, water use, and overall impact, while economic performance is assessed through levelized cost of electricity (LCOE). Sensitivity analysis explores the effects of energy payback time (EPBT), material efficiency, and perovskite stability. Results show manufacturing as the main hotspot, contributing most to life cycle emissions and energy consumption across all configurations. The hybrid tandem system shows the lowest total environmental impact (~973 impact units) compared to C-Si (~1378), achieving about a 29.4% reduction thanks to low-temperature perovskite processing, improved tandem efficiency, and lower energy (397 kWh) and water (607 L) use. Economically, circular economy practices like recycling and material recovery lower LCOE to $0.08/kWh, outperforming standalone technologies. Sensitivity analysis indicates that a 15% reduction in EPBT greatly boosts overall sustainability, while long-term perovskite stability remains a key uncertainty. These findings suggest that circular hybrid perovskite-silicon PV systems offer better combined environmental and economic benefits and serve as a promising path for fast, resourceefficient decarbonization of the electricity sector

Keywords

Photovoltaic, Perovskite solar cells, Hybrid tandem, PV Life cycle assessment, Circular economy, Sustainable energy transition, Climate policy, Carbon footprint

Rsif Scholar Name

Wakiang Emile Latchiba

Rsif Scholar Nationality

Chad

Cohort

Cohort 4

Thematic Area

Energy including Renewables

Africa Host University (AHU)

University of Nairobi (UoN), Kenya

Funding Statement

This work was funded by the Partnership for Applied Skills in Sciences, Engineering, and Technology—Regional Scholarship and Innovation Fund (PASET-RSIf) and the Carnegie Corporation of New York.

Recommended Citation

Latchiba, W. E., Waita, S., & Mwabora, J. M. (2026). Assessment of the life cycle of photovoltaic solar technologies for sustainable energy transitions: Implications for climate policy and low-carbon system integration. Resources, Environment and Sustainability https://doi.org/10.1016/j.resenv.2026.100328