Copulas modelling of maize yield losses-drought compound events using the multiple remote sensing indices over the Danube River Basin

0571057 - ÚVGZ 2024 RIV NL eng J - Článek v odborném periodiku
Potopová, Vera - Trifan, T. - Trnka, Miroslav - De Michele, C. - Semerádová, Daniela - Fischer, Milan - Meitner, Jan - Musiolková, M. - Muntean, N. - Clothier, B.
Copulas modelling of maize yield losses-drought compound events using the multiple remote sensing indices over the Danube River Basin.
Agricultural Water Management. Roč. 280, APR (2023), č. článku 108217. ISSN 0378-3774. E-ISSN 1873-2283
Grant CEP: GA MŠMT(CZ) EF16_019/0000797; GA TA ČR(CZ) SS02030027
Výzkumná infrastruktura: CzeCOS IV - 90248
Institucionální podpora: RVO:86652079
Klíčová slova: Evaporative Stress Index * Enhanced Vegetation Index * Relative Soil Water Availability * Peak correlation timing * Coupling droughtmaize yield losses * mechanism * Four-variate C-vine copula * Food security
Obor OECD: Agriculture
Impakt faktor: 6.7, rok: 2022
Způsob publikování: Open access
https://www.sciencedirect.com/science/article/pii/S0378377423000823?via%3Dihub

Danube countries have witnessed numerous waves of drought events, causing significant agro-economic loss, but three consecutive dry years amplified the debate on how to deal with future drought risk. The European drought of 2022 has shown how important it is to look at food security from an environmental droughts risk assessment approach. The coupling droughtyield losses framework derives from the understanding that all land systems are connected through coupled human and natural systems, and these social, ecological, and agro-economic impacts are the result. Maize is considered a commodity and a staple food in Europe with the largest market share in global maize exports. Droughtheat stress, war and subsequent limitations on Ukrainian trade have created a shortage of maize supply in 2022 over Europe. This study focused on eighteen countries where maize production becomes highly susceptible to drought in the Danube River Basin (DRB, Austria, Bosnia and Herzegovina, Bulgaria, Croatia, the Czech Republic, Hungary, Montenegro, Romania, Serbia, Slovakia, and Slovenia). To understand the coupling droughtyield losses mechanism, time series of maize yield datasets and multiple remote sensing indices were used on arable lands for 278 districts at a high spatial resolution. The main objective of this study was to determine which regions respond to the changes in the rate of evapotranspiration and soil moisture and in which period and how much maize production is affected. The time series of the two-band enhanced vegetation index (EVI2), the evaporative stress index (ESI), and the relative water availability (AWR) were calculated. The spatial evolution of the ESI for 4-week and 12-week time windows, EVI2, and relative soil saturation at the topsoil and rootzone layers demonstrate the progress of agricultural drought under varying agroclimatic conditions and its impacts on maize yields. Our study adopted a novel mechanism-based risk assessment approach using a four-variate C-vine copula in the perspective of modelling yield losses. To assess how much maize production can be limited by drought stress, the weekly dynamics of the strength of bivariate linkage of eight compound modes were provided. The return periods of droughtyield losses signatures in the study region were less than 4 years. The highest chances (once every 2.50-2.86 years) of the occurrence of droughtyield losses signature occurred in Romania, Bulgaria, Slovakia, Bosnia and Herzegovina. The avail-ability of soil water is one of the crucial indicators (AWR40) that explain the high degree of yield variability. This is an alarming finding given the expected or increasing year-to-year variability in soil moisture in these regions. The joint cumulative distribution function (Fcaop, ESI, AWR40, AWR100) suggests that shorter-term ESI will be most beneficial for maize yield estimation in agricultural districts where crop productivity is primarily impaired by warmer and drier events. This combination of effects can cause short-term compound hot and dry extremes characterized by rapid onset, severe intensity, and devastating impacts on crop production. Droughts between 2015 and 2022 challenged governments across the Danube basin and highlighted the need for intergovernmental interactions and coordination. For the DRB area, user-oriented drought monitoring portals are already providing real-time information about drought occurrences and intensity to practitioners, but drought-yield loss assess-ments for such predictions for most of the region have been lacking.
Trvalý link: https://hdl.handle.net/11104/0342366