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Standardized metrics to quantify solar energy-land relationships: A global systematic review

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Standardized metrics to quantify solar energy-land relationships: A global systematic review. / Cagle, Alexander E.; Shepherd, Morgan; Grodsky, Steven M. et al.
In: Frontiers in Sustainability, Vol. 3, 1035705, 27.02.2023.

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Harvard

Cagle, AE, Shepherd, M, Grodsky, SM, Armstrong, A, Jordaan, SM & Hernandez, RR 2023, 'Standardized metrics to quantify solar energy-land relationships: A global systematic review', Frontiers in Sustainability, vol. 3, 1035705. https://doi.org/10.3389/frsus.2022.1035705

APA

Cagle, A. E., Shepherd, M., Grodsky, S. M., Armstrong, A., Jordaan, S. M., & Hernandez, R. R. (2023). Standardized metrics to quantify solar energy-land relationships: A global systematic review. Frontiers in Sustainability, 3, Article 1035705. https://doi.org/10.3389/frsus.2022.1035705

Vancouver

Cagle AE, Shepherd M, Grodsky SM, Armstrong A, Jordaan SM, Hernandez RR. Standardized metrics to quantify solar energy-land relationships: A global systematic review. Frontiers in Sustainability. 2023 Feb 27;3:1035705. doi: 10.3389/frsus.2022.1035705

Author

Cagle, Alexander E. ; Shepherd, Morgan ; Grodsky, Steven M. et al. / Standardized metrics to quantify solar energy-land relationships : A global systematic review. In: Frontiers in Sustainability. 2023 ; Vol. 3.

Bibtex

@article{1996e830554a46499ae371d1527b9ead,
title = "Standardized metrics to quantify solar energy-land relationships: A global systematic review",
abstract = "Ground-mounted solar energy installations, including photovoltaics (PV) and concentrating solar power (CSP), can have significant environmental, ecological, and sociocultural effects via land-use and land-cover change (LULCC). Research in disciplines ranging from engineering to environmental policy seeks to quantify solar energy-land (SE-land) interactions to better understand the comprehensive impacts of solar energy installations on society. However, increasing evidence shows that scholars across research disciplines employ disparate metrics to quantify SE-land interactions. While solar energy deployment helps to achieve progress toward sustainable development goals (SDG 7- affordable and clean energy), the inconsistent use of metrics to describe SE-land interactions may inhibit the understanding of the total environmental and ecological impacts of solar energy installations, potentially causing barriers to achieve concurrent SDG's such as life on land (SDG 15). We systematically reviewed 608 sources on SE-land relationships globally to identify and assess the most frequent metric terms and units used in published studies. In total, we identified 51 unique metric terms and 34 different units of measure describing SE-land relationships across 18 countries of author origin. We organized these findings into three distinct metric categories: (1) capacity-based (i.e., nominal), (2) generation-based, and (3) human population-based. We used the most frequently reported terms and units in each category to inform a standardized suite of metrics, which are: land-use efficiency (W/m2), annual and lifetime land transformation (m2/Wh), and solar footprint (m2/capita). This framework can facilitate greater consistency in the reporting of SE-land metrics and improved capacity for comparison and aggregations of trends, including SE-land modeling projections. Our study addresses the need for standardization while acknowledging the role for future methodological advancements. The results of our study may help guide scholars toward a common vernacular and application of metrics to inform decisions about solar energy development.",
keywords = "Sustainability, land-use and land-cover change, renewable energy, electricity, energy transition, solar energy, metrics",
author = "Cagle, {Alexander E.} and Morgan Shepherd and Grodsky, {Steven M.} and Alona Armstrong and Jordaan, {Sarah M.} and Hernandez, {Rebecca R.}",
year = "2023",
month = feb,
day = "27",
doi = "10.3389/frsus.2022.1035705",
language = "English",
volume = "3",
journal = "Frontiers in Sustainability",
issn = "2673-4524",
publisher = "Frontiers Media",

}

RIS

TY - JOUR

T1 - Standardized metrics to quantify solar energy-land relationships

T2 - A global systematic review

AU - Cagle, Alexander E.

AU - Shepherd, Morgan

AU - Grodsky, Steven M.

AU - Armstrong, Alona

AU - Jordaan, Sarah M.

AU - Hernandez, Rebecca R.

PY - 2023/2/27

Y1 - 2023/2/27

N2 - Ground-mounted solar energy installations, including photovoltaics (PV) and concentrating solar power (CSP), can have significant environmental, ecological, and sociocultural effects via land-use and land-cover change (LULCC). Research in disciplines ranging from engineering to environmental policy seeks to quantify solar energy-land (SE-land) interactions to better understand the comprehensive impacts of solar energy installations on society. However, increasing evidence shows that scholars across research disciplines employ disparate metrics to quantify SE-land interactions. While solar energy deployment helps to achieve progress toward sustainable development goals (SDG 7- affordable and clean energy), the inconsistent use of metrics to describe SE-land interactions may inhibit the understanding of the total environmental and ecological impacts of solar energy installations, potentially causing barriers to achieve concurrent SDG's such as life on land (SDG 15). We systematically reviewed 608 sources on SE-land relationships globally to identify and assess the most frequent metric terms and units used in published studies. In total, we identified 51 unique metric terms and 34 different units of measure describing SE-land relationships across 18 countries of author origin. We organized these findings into three distinct metric categories: (1) capacity-based (i.e., nominal), (2) generation-based, and (3) human population-based. We used the most frequently reported terms and units in each category to inform a standardized suite of metrics, which are: land-use efficiency (W/m2), annual and lifetime land transformation (m2/Wh), and solar footprint (m2/capita). This framework can facilitate greater consistency in the reporting of SE-land metrics and improved capacity for comparison and aggregations of trends, including SE-land modeling projections. Our study addresses the need for standardization while acknowledging the role for future methodological advancements. The results of our study may help guide scholars toward a common vernacular and application of metrics to inform decisions about solar energy development.

AB - Ground-mounted solar energy installations, including photovoltaics (PV) and concentrating solar power (CSP), can have significant environmental, ecological, and sociocultural effects via land-use and land-cover change (LULCC). Research in disciplines ranging from engineering to environmental policy seeks to quantify solar energy-land (SE-land) interactions to better understand the comprehensive impacts of solar energy installations on society. However, increasing evidence shows that scholars across research disciplines employ disparate metrics to quantify SE-land interactions. While solar energy deployment helps to achieve progress toward sustainable development goals (SDG 7- affordable and clean energy), the inconsistent use of metrics to describe SE-land interactions may inhibit the understanding of the total environmental and ecological impacts of solar energy installations, potentially causing barriers to achieve concurrent SDG's such as life on land (SDG 15). We systematically reviewed 608 sources on SE-land relationships globally to identify and assess the most frequent metric terms and units used in published studies. In total, we identified 51 unique metric terms and 34 different units of measure describing SE-land relationships across 18 countries of author origin. We organized these findings into three distinct metric categories: (1) capacity-based (i.e., nominal), (2) generation-based, and (3) human population-based. We used the most frequently reported terms and units in each category to inform a standardized suite of metrics, which are: land-use efficiency (W/m2), annual and lifetime land transformation (m2/Wh), and solar footprint (m2/capita). This framework can facilitate greater consistency in the reporting of SE-land metrics and improved capacity for comparison and aggregations of trends, including SE-land modeling projections. Our study addresses the need for standardization while acknowledging the role for future methodological advancements. The results of our study may help guide scholars toward a common vernacular and application of metrics to inform decisions about solar energy development.

KW - Sustainability

KW - land-use and land-cover change

KW - renewable energy

KW - electricity

KW - energy transition

KW - solar energy

KW - metrics

U2 - 10.3389/frsus.2022.1035705

DO - 10.3389/frsus.2022.1035705

M3 - Journal article

VL - 3

JO - Frontiers in Sustainability

JF - Frontiers in Sustainability

SN - 2673-4524

M1 - 1035705

ER -