Updated sustainability status of crystalline silicon‐based photovoltaic systems: Life‐cycle energy and environmental impact reduction trends

Updated sustainability status of crystalline silicon‐based photovoltaic systems: Life‐cycle energy and environmental impact reduction trends

This paper provides a comprehensive assessment of the current life‐cycle sustainability status of crystalline‐based photovoltaic (PV) systems. Specifically, single‐crystalline Si (sc‐Si) and multicrystalline Si (mc‐Si) PV systems are analyzed in terms of their environmental and energy performance, p...

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Veröffentlicht in:Progress in photovoltaics 2021-10, Vol.29 (10), p.1068-1077
Hauptverfasser: Fthenakis, Vasilis, Leccisi, Enrica
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Sprache:eng
Schlagworte:
Crystal structure
Crystallinity
Electric power grids
Energy
Environmental impact
environmental impacts
EPBT
EROI
Estimates
Irradiation
LCA, NEA, crystalline Si
Photovoltaic cells
Silicon
Sustainability
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description This paper provides a comprehensive assessment of the current life‐cycle sustainability status of crystalline‐based photovoltaic (PV) systems. Specifically, single‐crystalline Si (sc‐Si) and multicrystalline Si (mc‐Si) PV systems are analyzed in terms of their environmental and energy performance, providing breakdown contributions and comparisons with estimates published 6 years ago. Results clearly show the significant environmental improvement in the sc‐Si PV system production—mainly at the wafer stage—for which the impacts have been reduced by up to 50% in terms of carbon emissions and 42% in terms of acid gas emissions. The life‐cycle cumulative energy demand is estimated to be approximately 48% lower (for sc‐Si) and 24% lower (for mc‐Si) than previously reported estimates. Energy payback times of currently installed systems range from 1.3 (for c‐Si PV) and 1.5 years (mc‐Si PV) for fixed‐tilt ground‐mounted installations at low irradiation (1000 kWh/m2/year), to 0.6 years at high irradiation (2300 kWh/m2/year). The resulting energy returns on investment—expressed in terms of primary energy—range from 22 (at low irradiation) to 52 (at high irradiation) for sc‐Si PV systems and from 21 to 47 for mc‐Si PV systems. Furthermore, we examine the effects of cleaner electricity grids and grid efficiency improvements on these environmental and energy indicators. A comprehensive assessment of the updated life‐cycle sustainability status of crystalline‐based photovoltaic (PV) systems is provided. The life‐cycle cumulative energy demand is approximately 48% lower (for single‐crystalline Si [sc‐Si]) and 24% lower (for multicrystalline Si [mc‐Si]) than previously reported estimates. The main improvements are in the sc‐Si PV system production—mainly at the wafer stage—for which the impacts have been reduced by up to 50% in terms of carbon emissions and 42% in terms of acid gas emissions.
doi_str_mv 10.1002/pip.3441
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Specifically, single‐crystalline Si (sc‐Si) and multicrystalline Si (mc‐Si) PV systems are analyzed in terms of their environmental and energy performance, providing breakdown contributions and comparisons with estimates published 6 years ago. Results clearly show the significant environmental improvement in the sc‐Si PV system production—mainly at the wafer stage—for which the impacts have been reduced by up to 50% in terms of carbon emissions and 42% in terms of acid gas emissions. The life‐cycle cumulative energy demand is estimated to be approximately 48% lower (for sc‐Si) and 24% lower (for mc‐Si) than previously reported estimates. Energy payback times of currently installed systems range from 1.3 (for c‐Si PV) and 1.5 years (mc‐Si PV) for fixed‐tilt ground‐mounted installations at low irradiation (1000 kWh/m2/year), to 0.6 years at high irradiation (2300 kWh/m2/year). The resulting energy returns on investment—expressed in terms of primary energy—range from 22 (at low irradiation) to 52 (at high irradiation) for sc‐Si PV systems and from 21 to 47 for mc‐Si PV systems. Furthermore, we examine the effects of cleaner electricity grids and grid efficiency improvements on these environmental and energy indicators. A comprehensive assessment of the updated life‐cycle sustainability status of crystalline‐based photovoltaic (PV) systems is provided. The life‐cycle cumulative energy demand is approximately 48% lower (for single‐crystalline Si [sc‐Si]) and 24% lower (for multicrystalline Si [mc‐Si]) than previously reported estimates. 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Specifically, single‐crystalline Si (sc‐Si) and multicrystalline Si (mc‐Si) PV systems are analyzed in terms of their environmental and energy performance, providing breakdown contributions and comparisons with estimates published 6 years ago. Results clearly show the significant environmental improvement in the sc‐Si PV system production—mainly at the wafer stage—for which the impacts have been reduced by up to 50% in terms of carbon emissions and 42% in terms of acid gas emissions. The life‐cycle cumulative energy demand is estimated to be approximately 48% lower (for sc‐Si) and 24% lower (for mc‐Si) than previously reported estimates. Energy payback times of currently installed systems range from 1.3 (for c‐Si PV) and 1.5 years (mc‐Si PV) for fixed‐tilt ground‐mounted installations at low irradiation (1000 kWh/m2/year), to 0.6 years at high irradiation (2300 kWh/m2/year). The resulting energy returns on investment—expressed in terms of primary energy—range from 22 (at low irradiation) to 52 (at high irradiation) for sc‐Si PV systems and from 21 to 47 for mc‐Si PV systems. Furthermore, we examine the effects of cleaner electricity grids and grid efficiency improvements on these environmental and energy indicators. A comprehensive assessment of the updated life‐cycle sustainability status of crystalline‐based photovoltaic (PV) systems is provided. The life‐cycle cumulative energy demand is approximately 48% lower (for single‐crystalline Si [sc‐Si]) and 24% lower (for multicrystalline Si [mc‐Si]) than previously reported estimates. 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Specifically, single‐crystalline Si (sc‐Si) and multicrystalline Si (mc‐Si) PV systems are analyzed in terms of their environmental and energy performance, providing breakdown contributions and comparisons with estimates published 6 years ago. Results clearly show the significant environmental improvement in the sc‐Si PV system production—mainly at the wafer stage—for which the impacts have been reduced by up to 50% in terms of carbon emissions and 42% in terms of acid gas emissions. The life‐cycle cumulative energy demand is estimated to be approximately 48% lower (for sc‐Si) and 24% lower (for mc‐Si) than previously reported estimates. Energy payback times of currently installed systems range from 1.3 (for c‐Si PV) and 1.5 years (mc‐Si PV) for fixed‐tilt ground‐mounted installations at low irradiation (1000 kWh/m2/year), to 0.6 years at high irradiation (2300 kWh/m2/year). The resulting energy returns on investment—expressed in terms of primary energy—range from 22 (at low irradiation) to 52 (at high irradiation) for sc‐Si PV systems and from 21 to 47 for mc‐Si PV systems. Furthermore, we examine the effects of cleaner electricity grids and grid efficiency improvements on these environmental and energy indicators. A comprehensive assessment of the updated life‐cycle sustainability status of crystalline‐based photovoltaic (PV) systems is provided. The life‐cycle cumulative energy demand is approximately 48% lower (for single‐crystalline Si [sc‐Si]) and 24% lower (for multicrystalline Si [mc‐Si]) than previously reported estimates. 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subjects Crystal structure
Crystallinity
Electric power grids
Energy
Environmental impact
environmental impacts
EPBT
EROI
Estimates
Irradiation
LCA, NEA, crystalline Si
Photovoltaic cells
Silicon
Sustainability
title Updated sustainability status of crystalline silicon‐based photovoltaic systems: Life‐cycle energy and environmental impact reduction trends
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