Restricted accessResearch articleFirst published online 2025
Evaluating climate mitigation cost of power generation in Colombia: A novel approach to cost-benefit analysis when contemplating adoption of renewable energy technologies (REs)
Renewable energy technologies (REs) are crucial to reducing greenhouse gas (GHG) emissions and mitigating climate change. REs can impact the environment negatively, particularly if they occupy large land areas. It is necessary to compare the potential benefits of using land to install REs with the possible loss of carbon sequestration in ecosystems where REs are installed. This effect can be particularly high in tropical countries. Such potential loss of carbon sequestration is generally ignored when evaluating the environmental impacts of proposed REs. This study examined the trade-offs between the loss of carbon fixation from land use in operating and projected hydro, wind, and solar power plants and GHG emissions from thermal power. We used MODIS products and official data from national agencies to estimate non-fixed carbon in areas occupied by REs and national data on GHG emissions from thermal power generation. We conclude that wind plants have the highest land occupation impact, while solar plants have the lowest. Hydropower plants have the highest non-assimilated carbon impact (loss of carbon fixation), but these values are significantly lower than GHG emissions from thermal power. Our results indicate that, although there are negative impacts from devoting large areas to power generation from REs, the amount of carbon injected into the atmosphere while generating the same amount of power from non-renewable sources is significantly greater. We recommend that cost-benefit analyses for adopting REs incorporate new approaches to quantify, more accurately, the true value of adopting these new energy-production strategies at the national scale.
Hoegh-GuldbergOJacobDTaylorM, et al.Chapter 3: impacts of 1.5°C global warming on natural and human systems. Special Report, Intergovernmental Panel on Climate Change2018: 175–311.
2.
WangQGuoJLiR, et al.Exploring the role of nuclear energy in the energy transition: a comparative perspective of the effects of coal, oil, natural gas, renewable energy, and nuclear power on economic growth and carbon emissions. Environ Res2023; 221: 115290.
OwusuPAAsumadu-SarkodieS.A review of renewable energy sources, sustainability issues and climate change mitigation. Cogent Eng, 2016; 3: 1–14. DOI: https://doi.org/10.1080/23311916.2016.1167990
5.
DoğanBDrihaOMBalsalobre LorenteD, et al.The mitigating effects of economic complexity and renewable energy on carbon emissions in developed countries. Sustainable Development2021; 29: 1–12.
6.
MeleMGurrieriARMorelliG, et al.Nature and climate change effects on economic growth: an LSTM experiment on renewable energy resources. Environmental Science and Pollution Research2021; 28: 41127–41134.
7.
SharmaGDTiwariAKErkutB, et al.Exploring the nexus between non-renewable and renewable energy consumptions and economic development: evidence from panel estimations. Renewable Sustainable Energy Rev2021; 146: 111152.
WangQWangL.Renewable energy consumption and economic growth in OECD countries: A nonlinear panel data analysis. Energy, 2020; 207: 1–11. DOI: https://doi.org/10.1016/j.energy.2020.118200
10.
WangQZhangFLiR.Revisiting the environmental kuznets curve hypothesis in 208 counties: The roles of trade openness, human capital, renewable energy and natural resource rent. Environ Res, 2023; 216: 1–19. DOI: https://doi.org/10.1016/j.envres.2022.114637
11.
MagazzinoCCerulliGShahzadU, et al.The nexus between agricultural land use, urbanization, and greenhouse gas emissions: Novel implications from different stages of income levels. Atmos Pollut Res, 2023; 14: 1–11. DOI: https://doi.org/10.1016/j.apr.2023.101846
12.
MagazzinoCCerulliGHaouasI, et al.The drivers of GHG emissions: a novel approach to estimate emissions using nonparametric analysis. Gondwana Res2024; 127: 4–21.
13.
Jiménez-GarcíaFNRestrepo-FrancoAMMulcue-NietoLF. Estado de la investigación en energía en Colombia: una mirada desde los grupos de investigación. Revista Facultad de Ingeniería2019; 28: 9–26.
PazJdel JesusMKelmanR, et al.Vulnerabilidad al cambio climático y medidas de adaptación de los sistemas hidroeléctricos en los países andinos. 2019: 55.
LucenaFPHejaziMVasquez-arroyoE, et al.Interactions between climate change mitigation and adaptation: the case of hydropower in Brazil. Energy2018; 164: 1161–1177.
19.
Londoño PinedaAAVélez Rojas (Oscar)OAJonathanMP, et al.Evaluation of climate change adaptation in the energy generation sector in Colombia via a composite index — A monitoring tool for government policies and actions. J Environ Manage, 2019; 250. DOI: https://doi.org/10.1016/j.jenvman.2019.109453
20.
Restrepo-TrujilloJMoreno-ChuquenRJiménez-GarcíaFN. Strategies of expansion for electric power systems based on hydroelectric plants in the context of climate change: case of analysis of Colombia. International Journal of Energy Economics and Policy2020; 10: 66–74.
21.
OrtegaGAriasPAVillegasJC, et al.Present-day and future climate over central and South America according to CMIP5/CMIP6 models. Int J Climatol2021; 41: 6713–6735.
22.
AriasPAVillegasLDMesaOJ, et al.Methodological implications and inconsistencies of Colombia’s third national communication on climate change. Rev Acad Colomb Cienc Exactas Fis Nat2022; 46: 769–794.
23.
CorreaICAriasPAVieiraSC, et al.A drier Orinoco basin during the twenty-first century: the role of the Orinoco low-level jet. Clim Dyn2024; 62: 2369–2398.
Moreno RochaCMArenas BuelvasDDe la Hoz EscorciaS. Evaluation and ranking of energy alternatives for implementation in different geographic scenarios using decision methods: case study of Colombia. International Journal of Energy Economics and Policy2024; 14: 191–202.
26.
UPME. Sistema de Información Eléctrico Colombiano – SIEL. Unidad de Planeación Minero Energética, 2021, https://www1.upme.gov.co/siel.
27.
KumarSSaketRKDheerDK, et al.Reliability enhancement of electrical power system including impacts of renewable energy sources: a comprehensive review. IET Gener Transm Distrib2020; 14: 1799–1815.
28.
SayedETWilberforceTElsaidK, et al.A critical review on environmental impacts of renewable energy systems and mitigation strategies: wind, hydro, biomass and geothermal. Sci Total Environ2021; 766: 144505.
29.
WangQZhanL. Assessing the sustainability of renewable energy: an empirical analysis of selected 18 European countries. Sci Total Environ2019; 692: 529–545.
IoannidisRKoutsoyiannisD.A review of land use, visibility and public perception of renewable energy in the context of landscape impact. Appl Energy2020; 276: 1–22. DOI: https://doi.org/10.1016/j.apenergy.2020.115367
32.
LoveringJSwainMBlomqvistL, et al.Land-use intensity of electricity production and tomorrow’s energy landscape. PLoS One, 2022; 17: 1–17. DOI: https://doi.org/10.1371/journal.pone.0270155
33.
PoggiFFirminoAAmadoM. Planning renewable energy in rural areas: impacts on occupation and land use. Energy2018; 155: 630–640.
34.
Barron-GaffordGAPavao-ZuckermanMAMinorRL, et al.Agrivoltaics provide mutual benefits across the food–energy–water nexus in drylands. Nat Sustain2019; 2: 848–855.
35.
GasparatosADollCNHEstebanM, et al.Renewable energy and biodiversity: implications for transitioning to a green economy. Renewable Sustainable Energy Rev2017; 70: 161–184.
36.
ChaudharyAVeronesFDe BaanL, et al.Quantifying land use impacts on biodiversity: combining Species-area models and vulnerability indicators. Environ Sci Technol2015; 49: 9987–9995.
37.
HastikRBassoSGeitnerC, et al.Renewable energies and ecosystem service impacts. Renewable Sustainable Energy Rev2015; 48: 608–623.
38.
HernandezRREasterSBMurphy-MariscalML, et al.Environmental impacts of utility-scale solar energy. Renewable Sustainable Energy Rev2014; 29: 766–779.
39.
ScorzaFPilogalloASaganeitiL, et al.Comparing the territorial performances of renewable energy sources’ plants with an integrated ecosystem services loss assessment: A case study from the Basilicata region (Italy). Sustain Cities Soc2020; 56: 1–17. DOI: https://doi.org/10.1016/j.scs.2020.102082
40.
Martínez-MartínezYDewulfJCasas-LedónY. GIS-based site suitability analysis and ecosystem services approach for supporting renewable energy development in south-central Chile. Renew Energy2022; 182: 363–373.
41.
EspécieMde CarvalhoPNPinheiroMFB, et al.Ecosystem services and renewable power generation: a preliminary literature review. Renew Energy2019; 140: 39–51.
PerezL.M.DíazJ.Estimation of the carbon contained in the aerial forest biomass of two Andean forests in the departments of Santander and Cundinamarca. 2010.
44.
SullivanMJPTalbotJLewisSL, et al.Diversity and carbon storage across the tropical forest biome. Sci Rep2017; 7: 1–12.
AnwarzaiMANagasakaK. Utility-scale implementable potential of wind and solar energies for Afghanistan using GIS multi-criteria decision analysis. Renewable Sustainable Energy Rev2017; 71: 150–160.
47.
Capellán-pérezIDe CastroCArtoI. Assessing vulnerabilities and limits in the transition to renewable energies: land requirements under 100% solar energy scenarios. Renewable Sustainable Energy Rev2017; 77: 760–782.
48.
BonamenteEPellicciaLMericoMC, et al.The multifunctional environmental energy tower: carbon footprint and land use analysis of an integrated renewable energy plant. Sustainability2015; 7: 13564–13584.
49.
LudererGPehlMArvesenA, et al.Environmental co-benefits and adverse side-effects of alternative power sector decarbonization strategies. Nat Commun2019; 10: 1–13.
50.
KlinglerMAmeliNRickmanJ, et al.Large-scale green grabbing for wind and solar photovoltaic development in Brazil. Nature Sustainability2024; 7: 747–757.
51.
LiuXSuYLiZ, et al.Constructing ecological security patterns based on ecosystem services trade-offs and ecological sensitivity: A case study of Shenzhen metropolitan area, China. Ecol Indic2023; 154: 1–15. DOI: https://doi.org/10.1016/j.ecolind.2023.110626
52.
FriedlMSulla-MenasheD.MODIS/Terra+Aqua Land Cover Type Yearly L3 Global 500 m SIN Grid V061 [Data set]. 2022, https://lpdaac.usgs.gov/products/mcd12q1v061/ (accessed 2 February 2023).
EtterAArévaloPAmayaP.Ecosistemas potenciales de Colombia a escala 1:100.000. 2015.
55.
NordenNGonzálezMRAvellaMA, et al.Building a socio-ecological monitoring platform for the comprehensive management of tropical dry forests. Plants People Planet2021; 3: 238–248.
56.
NadaletiWCde SouzaEGLourençoVA. Green hydrogen-based pathways and alternatives: towards the renewable energy transition in South America’s regions–part B. Int J Hydrogen Energy2022; 47: 1–15.
57.
WangRMirzaNVasbievaDG, et al.The nexus of carbon emissions, financial development, renewable energy consumption, and technological innovation: what should be the priorities in light of COP 21 agreements?J Environ Manage2020; 271: 111027.
58.
CalzadaLMeaveJABonfilC, et al.Lands at risk: land use/land cover change in two contrasting tropical dry regions of Mexico. Applied Geography2018; 99: 22–30.
59.
NunezSVerboomJAlkemadeR. Assessing land-based mitigation implications for biodiversity. Environ Sci Policy2020; 106: 68–76.
60.
LiuJYanQZhangM.Ecosystem carbon storage considering combined environmental and land-use changes in the future and pathways to carbon neutrality in developed regions. Sci Total Environ2023; 903: 1–16. DOI: https://doi.org/10.1016/j.scitotenv.2023.166204
61.
ZhangFXuNWangC, et al.Effects of land use and land cover change on carbon sequestration and adaptive management in Shanghai, China. Phys Chem Earth2020; 120: 1–8. DOI: https://doi.org/10.1016/j.pce.2020.102948
62.
XuXJiaoFLiuH, et al.Persistence of increasing vegetation gross primary production under the interactions of climate change and land use changes in Northwest China. Sci Total Environ; 834. Epub ahead of print. 2022; 834. DOI: https://doi.org/10.1016/j.scitotenv.2022.155086
63.
YanYWuCWenY.Determining the impacts of climate change and urban expansion on net primary productivity using the spatio-temporal fusion of remote sensing data. Ecol Indic2021; 127: 1–12. DOI: https://doi.org/10.1016/j.ecolind.2021.107737
64.
JohnsonJAKennedyCMOakleafJR, et al.Energy matters: Mitigating the impacts of future land expansion will require managing energy and extractive footprints. Ecol Econ2021; 187. Epub ahead of print. DOI: https://doi.org/10.1016/j.ecolecon.2021.107106.
65.
ClericiNCote-NavarroFEscobedoFJ, et al.Spatio-temporal and cumulative effects of land use-land cover and climate change on two ecosystem services in the Colombian Andes. Sci Total Environ2019; 685: 1181–1192.
66.
Martínez-MartínezYDewulfJAguayoM, et al.Sustainable wind energy planning through ecosystem service impact valuation and exergy: A study case in south-central Chile. Renewable Sustainable Energy Rev; 178. Epub ahead of print 1 May 2023. DOI: https://doi.org/10.1016/j.rser.2023.113252.
67.
HuangFZuoLGaoJ, et al.Exploring the driving factors of trade-offs and synergies among ecological functional zones based on ecosystem service bundles. Ecol Indic2023; 146: 109827.
68.
BernardinoJBevangerKBarrientosR, et al.Bird collisions with power lines: state of the art and priority areas for research. Biol Conserv2018; 222: 1–13.
69.
FthenakisVKimHC. Life-cycle uses of water in U.S. Electricity generation. Renewable Sustainable Energy Rev2010; 14: 2039–2048.
70.
RadeloffVCWilliamsJWBatemanBL, et al.The rise of novelty in ecosystems. Ecol Appl2018; 28: 1547–1567.
71.
DiffendorferJEComptonRWKramerLA, et al.Potential effects of large-scale solar energy development on small mammals and the American pika. Biol Conserv2013; 158: 389–401.
72.
DavisSJCaldeiraKMatthewsHD. Future CO2 emissions and climate change from existing energy infrastructure. Science (1979)2015; 329: 1330–1333.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
