Forecasting meteorological impacts on the environmental sustainability of a large-scale solar plant via artificial intelligence-based life cycle assessment

Although large-scale solar (LSS) is a promising renewable energy technology, it causes adverse impacts on the ecosystem, human health, and resource depletion throughout its upstream (i.e., raw material extraction to solar panel production) and downstream (i.e., plant demolition and waste management)...

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Published in:Science of the Total Environment
Main Author: Wan M.J.; Phuang Z.X.; Hoy Z.X.; Dahlan N.Y.; Azmi A.M.; Woon K.S.
Format: Article
Language:English
Published: Elsevier B.V. 2024
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85179011303&doi=10.1016%2fj.scitotenv.2023.168779&partnerID=40&md5=ae7b74df7dd91d52b17eb28cdc0b8206
id 2-s2.0-85179011303
spelling 2-s2.0-85179011303
Wan M.J.; Phuang Z.X.; Hoy Z.X.; Dahlan N.Y.; Azmi A.M.; Woon K.S.
Forecasting meteorological impacts on the environmental sustainability of a large-scale solar plant via artificial intelligence-based life cycle assessment
2024
Science of the Total Environment
912

10.1016/j.scitotenv.2023.168779
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85179011303&doi=10.1016%2fj.scitotenv.2023.168779&partnerID=40&md5=ae7b74df7dd91d52b17eb28cdc0b8206
Although large-scale solar (LSS) is a promising renewable energy technology, it causes adverse impacts on the ecosystem, human health, and resource depletion throughout its upstream (i.e., raw material extraction to solar panel production) and downstream (i.e., plant demolition and waste management) processes. The LSS operational performance also fluctuates due to meteorological conditions, leading to uncertainty in electricity generation and raising concerns about its overall environmental performance. Hitherto, there has been no evidence-backed study that evaluates the ecological sustainability of LSS with the consideration of meteorological uncertainties. In this study, a novel integrated Life Cycle Assessment (LCA) and Artificial Neural Network (ANN) framework is developed to forecast the meteorological impacts on LSS's electricity generation and its life cycle environmental sustainability. For LCA, 18 impact categories and three damage categories are characterised and assessed by ReCiPe 2016 via SimaPro v. 9.1. For ANN, a feedforward neural network is applied via Neural Designer 5.9.3. Taking an LSS plant in Malaysia as a case study, the photovoltaic panel production stage contributes the highest environmental impact in LSS (30 % of human health, 30 % of ecosystem quality, and 34 % of resource scarcity). Aluminium recycling reduces by 10 % for human health, 10 % for ecosystem quality, and 9 % for resource scarcity. The emissions avoided by the forecasted LSS-generated electricity offset the environmental burden for human health, ecosystem quality, and resource scarcity 12–68 times, 13–73 times, and 18–98 times, respectively. The developed ANN-LCA framework can provide LSS stakeholders with data-backed insights to effectively design an environmentally conscious LSS facility, considering meteorological influences. © 2023 Elsevier B.V.
Elsevier B.V.
489697
English
Article

author Wan M.J.; Phuang Z.X.; Hoy Z.X.; Dahlan N.Y.; Azmi A.M.; Woon K.S.
spellingShingle Wan M.J.; Phuang Z.X.; Hoy Z.X.; Dahlan N.Y.; Azmi A.M.; Woon K.S.
Forecasting meteorological impacts on the environmental sustainability of a large-scale solar plant via artificial intelligence-based life cycle assessment
author_facet Wan M.J.; Phuang Z.X.; Hoy Z.X.; Dahlan N.Y.; Azmi A.M.; Woon K.S.
author_sort Wan M.J.; Phuang Z.X.; Hoy Z.X.; Dahlan N.Y.; Azmi A.M.; Woon K.S.
title Forecasting meteorological impacts on the environmental sustainability of a large-scale solar plant via artificial intelligence-based life cycle assessment
title_short Forecasting meteorological impacts on the environmental sustainability of a large-scale solar plant via artificial intelligence-based life cycle assessment
title_full Forecasting meteorological impacts on the environmental sustainability of a large-scale solar plant via artificial intelligence-based life cycle assessment
title_fullStr Forecasting meteorological impacts on the environmental sustainability of a large-scale solar plant via artificial intelligence-based life cycle assessment
title_full_unstemmed Forecasting meteorological impacts on the environmental sustainability of a large-scale solar plant via artificial intelligence-based life cycle assessment
title_sort Forecasting meteorological impacts on the environmental sustainability of a large-scale solar plant via artificial intelligence-based life cycle assessment
publishDate 2024
container_title Science of the Total Environment
container_volume 912
container_issue
doi_str_mv 10.1016/j.scitotenv.2023.168779
url https://www.scopus.com/inward/record.uri?eid=2-s2.0-85179011303&doi=10.1016%2fj.scitotenv.2023.168779&partnerID=40&md5=ae7b74df7dd91d52b17eb28cdc0b8206
description Although large-scale solar (LSS) is a promising renewable energy technology, it causes adverse impacts on the ecosystem, human health, and resource depletion throughout its upstream (i.e., raw material extraction to solar panel production) and downstream (i.e., plant demolition and waste management) processes. The LSS operational performance also fluctuates due to meteorological conditions, leading to uncertainty in electricity generation and raising concerns about its overall environmental performance. Hitherto, there has been no evidence-backed study that evaluates the ecological sustainability of LSS with the consideration of meteorological uncertainties. In this study, a novel integrated Life Cycle Assessment (LCA) and Artificial Neural Network (ANN) framework is developed to forecast the meteorological impacts on LSS's electricity generation and its life cycle environmental sustainability. For LCA, 18 impact categories and three damage categories are characterised and assessed by ReCiPe 2016 via SimaPro v. 9.1. For ANN, a feedforward neural network is applied via Neural Designer 5.9.3. Taking an LSS plant in Malaysia as a case study, the photovoltaic panel production stage contributes the highest environmental impact in LSS (30 % of human health, 30 % of ecosystem quality, and 34 % of resource scarcity). Aluminium recycling reduces by 10 % for human health, 10 % for ecosystem quality, and 9 % for resource scarcity. The emissions avoided by the forecasted LSS-generated electricity offset the environmental burden for human health, ecosystem quality, and resource scarcity 12–68 times, 13–73 times, and 18–98 times, respectively. The developed ANN-LCA framework can provide LSS stakeholders with data-backed insights to effectively design an environmentally conscious LSS facility, considering meteorological influences. © 2023 Elsevier B.V.
publisher Elsevier B.V.
issn 489697
language English
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