Adamopoulos I, Frantzana A, Syrou N (2024) Climate crises associated with epidemiological, environmental, and ecosystem effects of a storm: flooding, landslides, and damage to urban and rural areas (extreme weather events of storm Daniel in thessaly, Greece). Med Sci Forum 25. https://doi.org/10.3390/msf2024025007

AdelekeAA. Technological advancements in cotton agronomy: a review and prospects. Technol Agron, 2024, 4e008.

AlluvioneF, MorettiB, SaccoD, GrignaniC. EUE (energy use efficiency) of cropping systems for a sustainable agriculture. Energy, 2011, 36: 4468-4481.

ArunratN, SereenonchaiS, WangC. Carbon footprint and predicting the impact of climate change on carbon sequestration ecosystem services of organic rice farming and conventional rice farming: A case study in Phichit province, Thailand. J Environ Manage, 2021, 289112458.

AvramidouG, PlatisDP, MenexesGC, AnagnostopoulosCD, TsaboulaAD, KalburtjiKL, MamolosAP. Evaluation and selection of aromatic plants based on agri-environmental indicators. Environ Dev Sustain, 2024.

BaiY, ZhangT, ZhaiY, ShenX, MaX, ZhangR, JiC, HongJ. Water footprint coupled economic impact assessment for maize production in China. Sci Total Environ, 2021, 752141963.

BaranMF, PolatR, GokdoganO. Comparison of energy use efficiency of different tillage methods on the secondary crop sunflower production. Fresen Environ Bull, 2016, 25: 4937-4943

BenzécriJPCorrespondence analysis handbook, 1992, Boca Raton FL. CRC. .

Bouwman AF, Boumans LJM, Batjes NH (2002) Modeling global annual N₂O and NO emissions from fertilized fields. Global Biogeochem Cy 16. https://doi.org/10.1029/2001gb001812

CetinO, BilgelL. Effects of different irrigation methods on shedding and yield of cotton. Agric Water Manag, 2002, 54: 1-15.

ChenR, ZhangR, HanH. Where has carbon footprint research gone?. Ecol Indic, 2021, 120106882.

CohenJStatistical power analysis for the behavioral sciences, 1988, New Jersey. Lawrence Erlbaum Associates, Inc.

Environment ECD-G (2014) for Mapping and assessment of ecosystems and their services– Indicators for ecosystem assessments under action 5 of the EU biodiversity strategy to 2020, 2nd report. Publications Office. https://op.europa.eu/en/publication-detail/-/publication/ab4b4d54-787b-4241-96a9-8fe64f1ab593. Accessed 6 Mar 2025

Espadas-AldanaG, VialleC, BelaudJP, Vaca-GarciaC, SablayrollesC. Analysis and trends for life cycle assessment of Olive oil production. Sustain Prod Consum, 2019, 19: 216-230.

European Commission (2025) Sustainable agricultural practices and methods. In: European Commission. https://agriculture.ec.europa.eu/cap-my-country/sustainability/environmental-sustainability/sustainable-agricultural-practices-and-methods_en. Accessed 4 May 2025

European Commission (2021) Common agricultural policy funds. https://agriculture.ec.europa.eu/common-agricultural-policy/financing-cap/cap-funds_en. Accessed 6 May 2025

European Commission (2020) Stepping up Europe’s 2030 climate ambition: Investing in a climate-neutral future for the benefit of our people. Brussels. https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=celex:52020DC0562. Accessed 4 May 2025

European Commission (2023) CAP Specific Objectives, Agriculture and Climate Mitigation. https://agriculture.ec.europa.eu/common-agricultural-policy/cap-overview/cap-2023-27/key-policy-objectives-cap-2023-27_en. Accessed 4 May 2025

Eurostat (2023) Eurostat statistics explained. Energy statistics– an overview. https://ec.europa.eu/eurostat/statistics-explained/index.php?title=Energy_statistics_-_an_overview. Accessed 6 May 2025

FAO (2022) Greenhouse gas emissions from agrifood systems Global, regional and country trends, 2000–2020 FAOSTAT Analytical Brief Series No. Rome, FAO. https://openknowledge.fao.org/server/api/core/bitstreams/121cc613-3d0f-431c-b083-cc2031dd8826/content. Accessed 6 May 2025

FengX, SunT, GuoJ, CaiH, QianC, HaoY, YuY, DengA, SongZ, ZhangW. Climate-smart agriculture practice promotes sustainable maize production in Northeastern china: higher grain yield while less carbon footprint. Field Crops Res, 2023, 302109108.

Field A (2013) Discovering statistics using IBM SPSS statistics, 4th edn. Sage Publications Ltd.

FinnvedenG, HauschildMZ, EkvallT, GuinéeJ, HeijungsR, HellwegS, KoehlerA, PenningtonD, SuhS. Recent developments in life cycle assessment. J Environ Manage, 2009, 91: 1-21.

FluckRC. Energy sequestered in repairs and maintenance of agricultural machinery. Trans ASAE, 1985, 28: 738-744.

FluckRCFluckRC. Energy analysis for agricultural systems. Energy in farm production, 1992, Amsterdam. Elsevier Science. 4552.

Forster P, Storelvmo T, Armour K, Collins W, Dufresne JL, Frame D, Lunt DJ, Mauritsen T, Palmer MD, Watanabe M, Wild M, Zhang H (2023) The Earth’s energy budget, climate feedbacks and climate sensitivity. In: Masson-Delmotte V, Zhai P, Pirani A, Connors SL, Péan C, Berger S, Caud N, Chen Y, Goldfarb L, Gomis MI, Huang M, Leitzell K, Lonnoy E, Matthews JBR, Maycock TK, Waterfield T, Yelekçi O, Yu R, Zhou B (eds) Climate Change 2021 - The physical science basis. Cambridge University Press, United Kingdom and New York, NY, USA, pp 923–1054. https://doi.org/10.1017/9781009157896.009

GkisakisVD, VolakakisN, KosmasE, KabourakisEM. Developing a decision support tool for evaluating the environmental performance of Olive production in terms of energy use and greenhouse gas emissions. Sustain Prod Consum, 2020, 24: 156-168.

GregoryPJ, IngramJSI, BrklacichM. Climate change and food security. Philos Trans R Soc Lond B Biol Sc, 2005, 360: 2139-2148.

HeK, YangQ, ShenX, DimitriouE, MentzafouA, PapadakiC, StoumboudiM, AnagnostouEN. Brief communication: storm Daniel flood impact in Greece in 2023: mapping crop and livestock exposure from synthetic-aperture radar (SAR). Nat Hazards Earth Syst Sci, 2024, 24: 2375-2382.

Hellenic Statistical Authority of Greece (2024) Land Area and Production 2022. https://www.statistics.gr/el/statistics/-/publication/SPG06/-. Accessed 6 May2025

HillierJ, WalterC, MalinD, Garcia-SuarezT, Mila-i-CanalsL, SmithP. A farm-focused calculator for emissions from crop and livestock production. Environ Model Softw, 2011, 26: 1070-1078.

HossardL, ArcherDW, BertrandM, Colnenne-DavidC, DebaekeP, ErnforsM, JeuffroyM-H, Munier-JolainN, NilssonC, SanfordGR, SnappSS, JensenES, MakowskiD. A meta-analysis of maize and wheat yields in low-input vs. conventional and organic systems. Agron J, 2016, 108: 1155-1167.

HuangW, WuF, HanW, LiQ, HanY, WangG, FengL, LiX, YangB, LeiY, FanZ, XiongS, XinM, LiY, WangZ. Carbon footprint of cotton production in china: composition, Spatiotemporal changes and driving factors. Sci Total Environ, 2022, 821153407.

Iatrou M, Tziouvalekas M, Tsitouras A, Evangelou E, Noulas C, Vlachostergios D, Aschonitis V, Arampatzis G, Metaxa I, Karydas C, Tziachris P (2024) Analyzing the impact of storm ‘daniel’ and subsequent flooding on thessaly’s soil chemistry through causal inference. Agriculture 14. https://doi.org/10.3390/agriculture14040549

ImranM, OzcatalbasO. Optimization of energy consumption and its effect on the energy use efficiency and greenhouse gas emissions of wheat production in Turkey. Discov Sustain, 2021, 228.

ISOEnvironmental Management-life cycle Assessment-requirements and guidelines ISO-Norm 14044:2006, 2006, Brussels, Belgium. International Organization for Standardization, European Committee for Standardization.

ISOEnvironmental Management-life cycle Assessment-principles and framework. ISO-Norm 14040:2006, 2006, Brussels, Belgium. International Organization for Standardization, European Committee for Standardization.

ISOCarbon footprint of products requirements and guidelines for quantification and communication. ISO-norm 14067:2013. International organization for standardization, 2013, Brussels, Belgium. European Committee for Standardization.

KashyapD, AgarwalT. Carbon footprint and water footprint of rice and wheat production in punjab, India. Agric Syst, 2021, 186102959.

KourgialasNN. A critical review of water resources in greece: the key role of agricultural adaptation to climate-water effects. Sci Total Environ, 2021, 775145857.

Lang Y, Chao H, Xiao J (2024) The relationship between carbon emissions and ecosystem services in Guangdong province, china: the perspective of ecological function zones. Land 13. https://doi.org/10.3390/land13122227

LebartL, MorineauA, FenelonJPMethoden und programme, 1984, Berlin, Boston. De Gruyter.

LeddaA, Di CesareE A, SattaG, CoccoG, De MontisA. Integrating adaptation to climate change in regional plans and programmes: The role of strategic environmental assessment. Environ Impact Asses, 2021.

LitskasV, ChrysargyrisA, StavrinidesM, TzortzakisN. Water-energy-food nexus: A case study on medicinal and aromatic plants. J Clean Prod, 2019, 233: 1334-1343.

LiuA, LiZ, ZhangD, CuiZ, ZhanL, XuS, ZhangY, DaiJ, LiW, NieJ, YangG, LiC, DongH. One-off basal application of nitrogen fertilizer increases the biological yield but not the economic yield of cotton in moderate fertility soil. Field Crops Res, 2022, 288108702.

MaesJ, LiqueteC, TellerA, ErhardM, ParacchiniML, BarredoJI, GrizzettiB, CardosoA, SommaF, PetersenJE, MeinerA, GelabertER, ZalN, KristensenP, Bastrup-BirkA, BialaK, PiroddiC, EgohB, DegeorgesP, FiorinaC, Santos-MartínF, NaruševičiusV, VerbovenJ, PereiraHM, BengtssonJ, GochevaK, Marta-PedrosoC, SnällT, EstreguilC, San-Miguel-AyanzJ, Pérez-SobaM, Grêt-RegameyA, LillebøAI, MalakDA, CondéS, MoenJ, CzúczB, DrakouEG, ZulianG, LavalleC. An indicator framework for assessing ecosystem services in support of the EU biodiversity strategy to 2020. Ecosyst Serv, 2016, 17: 14-23.

MazisA, LitskasVD, PlatisDP, MenexesGC, AnagnostopoulosCD, TsaboulaAD, MamolosAP, KalburtjiKL. Could energy equilibrium and greenhouse gas emissions in agroecosystems play a key role in crop replacement? A case study in orange and Kiwi orchards. Environ Sci Pollut Res Int, 2021, 28: 29421-29431.

MehmetiA, AbdelhafezAAM, EllsselP, TodorovicM, CalabreseG. Performance and sustainability of organic and conventional cotton farming systems in egypt: an environmental and energy assessment. Sustainability, 2024, 1656637.

MehtaC, PatelRSPSS exact tests 7.0 for windows, 1996, Chicago. SPSS Inc.

MekonnenMM, HoekstraAY. The green, blue and grey water footprint of crops and derived crop products. Hydrol Earth Syst Sci, 2011, 15: 1577-1600.

MichosMC, MenexesGC, KalburtjiKL, TsatsarelisCA, AnagnostopoulosCD, MamolosAP. Could energy flow in agro-ecosystems be used as a tool for crop and farming system replacement?. Ecol Indic, 2017, 73: 247-253.

MichosMC, MenexesGC, MamolosAP, TsatsarelisCA, AnagnostopoulosCD, TsaboulaAD, KalburtjiKL. Energy flow, carbon and water footprints in vineyards and orchards to determine environmentally favourable sites in accordance with natura 2000 perspective. J Clean Prod, 2018, 187: 400-408.

PacettiT, CastelliG, SchröderB, BresciE, CaporaliE. Water ecosystem services footprint of agricultural production in central Italy. Sci Total Environ, 2021, 797149095.

PandaRK, BeheraSK, KashyapPS. Effective management of irrigation water for wheat under stressed conditions. Agric Water Manag, 2003, 63: 37-56.

PapanastasiouDK, KeppasS, MelasD, KatsoulasN. Estimation of crops future irrigation water needs in a mediterranean plain. Sustainability, 2023, 152115548.

ParameshV, ArunachalamV, NathAJ. Enhancing ecosystem services and energy use efficiency under organic and conventional nutrient management system to a sustainable Arecanut based cropping system. Energy, 2019, 187115902.

PierratÉ, LaurentA, DorberM, RygaardM, VeronesF, HauschildM. Advancing water footprint assessments: combining the impacts of water pollution and scarcity. Sci Total Environ, 2023, 870161910.

PimentelD, HurdLE, BellottiAC, ForsterMJ, OkaIN, SholesOD, WhitmanRJ. Food production and the energy crisis. Science, 1973, 182: 443-449.

PlatisDP, MamolosAP, KalburtjiKL, MenexesGC, AnagnostopoulosCD, TsaboulaAD. Analysis of energy and carbon and blue water footprints in agriculture: a case study of tomato cultivation systems. EuroMediterr J Environ Integr, 2021, 612.

PlatisDP, MenexesGC, KalburtjiKL, MamolosAP. Energy budget, carbon and water footprint in perennial agro and natural ecosystems inside a natura 2000 site as provisioning and regulating ecosystem services. Environ Sci Pollut Res Int, 2023, 30: 1288-1305.

RiedeselL, LaidigF, HadaschS, RentelD, HackaufB, PiephoHP, FeikeT. Breeding progress reduces carbon footprints of wheat and Rye. J Clean Prod, 2022, 377134326.

ShaoG, ZhouJ, LiuB, AlharbiSA, LiuE, KuzyakovY. Carbon footprint of maize-wheat cropping system after 40-year fertilization. Sci Total Environ, 2024, 926172082.

SharmaM, ThakurR, SharmaM, Kumar SharmaA, Kumar SharmaA. Changing scenario of medical plants diversity in relation to climate change: a review. Plant Arch, 2020, 20: 4389-4400

SreeshnaTR, AthiraP, SoundharajanB. Impact of climate change on regional water availability and demand for agricultural production: aplication of water footprint concept. Water Resour Manage, 2024, 38: 3785-3817.

Swarts K, Gutaker RM, Benz B, Blake M, Bukowski R, Holland J, Kruse-Peeples M, Lepak N, Prim L, Romay MC, Ross-Ibarra J, Sanchez-Gonzalez J, de Schmidt J, Schuenemann C, Krause VJ, Matson J, Weigel RG, Buckler D, Burbano ES (2017) HA Genomic estimation of complex traits reveals ancient maize adaptation to temperate North America. Science (1979) 357:512–515. https://doi.org/10.1126/science.aam9425

TaxidisET, MenexesGC, MamolosAP, TsatsarelisCA, AnagnostopoulosCD, KalburtjiKL. Comparing organic and conventional Olive groves relative to energy use and greenhouse gas emissions associated with the cultivation of two varieties. Appl Energy, 2015, 149: 117-124.

Tomczak M, Tomczak E The need to report effect size estimates revisited. An overview of some recommended measures of effect size. Trends Sport Sci 1(21):19–25. https://tss.awf.poznan.pl/pdf-188960-110189?filename=The%20need%20to%20report%20effect.pdf

WangX, MüllerC, ElliotJ, MuellerND, CiaisP, JägermeyrJ, GerberJ, DumasP, WangC, YangH, LiL, DeryngD, FolberthC, LiuW, MakowskiD, OlinS, PughTAM, ReddyA, SchmidE, JeongS, ZhouF, PiaoS. Global irrigation contribution to wheat and maize yield. Nat Commun, 2021, 121235.

WangX, JiaR, ZhaoJ, YangY, ZangH, ZengZ, OlesenJE. Quantifying water footprint of winter wheat– summer maize cropping system under manure application and limited irrigation: an integrated approach. Resour Conserv Recycl, 2022, 183106375.

WangH, RenH, HanK, LiG, ZhangL, ZhaoY, LiuY, HeQ, ZhangJ, ZhaoB, RenB, LiuP. Improving the net energy and energy utilization efficiency of maize production systems in the North China plain. Energy, 2023, 274127340.

WardJJr. Hierarchical grouping to optimize an objective function. J Am Stat Assoc, 1963, 58: 236-244.

WassonAP, RichardsRA, ChatrathR, MisraSC, PrasadSVS, RebetzkeGJ, KirkegaardJA, ChristopherJ, WattM. Traits and selection strategies to improve root systems and water uptake in water-limited wheat crops. J Exp Bot, 2012, 63: 3485-3498.

WuQ, HeY, MadramootooCA, QiZ, XueL, BukovskyM, JiangQ. Optimizing strategies to reduce the future carbon footprint of maize under changing climate. Resour Conserv Recycl, 2023, 188106714.

YahyaF, LeeCC. The asymmetric effect of agriculturalization toward climate neutrality targets. J Environ Manage, 2023, 328116995.

YilmazI, AkcaozH, OzkanB. An analysis of energy use and input costs for cotton production in Turkey. Renew Energy, 2005, 30: 145-155.

YinD, YuH, ShiY, ZhaoM, ZhangJ, LiX. Matching supply and demand for ecosystem services in the yellow river basin, china: A perspective of the water-energy-food nexus. J Clean Prod, 2023, 384135469.

ZhangW, RickettsTH, KremenC, CarneyK, SwintonSM. Ecosystem services and dis-services to agriculture. Ecol Econ, 2007, 64: 253-260.

ZhangXQ, PuC, ZhaoX, XueJF, ZhangR, NieZJ, ChenF, LalR, ZhangHL. Tillage effects on carbon footprint and ecosystem services of climate regulation in a winter wheat–summer maize cropping system of the North China plain. Ecol Indic, 2016, 67: 821-829.

Zhang J, Zhao G, Dang Y, Fan T, Wang L, Li S, Zhou G, Fudjoe SK, Wang L, Palta JA (2023a) Enhancing maize yield and resource efficiency through controlled-release nitrogen fertilization on the semiarid loess plateau. Agronomy 13. https://doi.org/10.3390/agronomy13092320

ZhangZ, HuangJ, YaoY, PetersG, MacdonaldB, La RosaAD, WangZ, SchererL. Environmental impacts of cotton and opportunities for improvement. Nat Rev Earth Environ, 2023, 4: 703-715.

ZiaeiSM, MazloumzadehSM, JabbaryM. A comparison of energy use and productivity of wheat and barley (case study). J Saudi Soc Agric Sci, 2015, 14: 19-25.