Climate change effects on crop yields in Serbia and related shifts of Köppen climate zones under the <scp>SRES‐A1B</scp> and <scp>SRES‐A2</scp>

Mihailoviĉ, Dragutin T.; Lalić, Branislava; Drešković, Nusret; Mimić, Gordan; Djurdjević, Vladimir; Jančić, M.

doi:10.1002/joc.4209

Cited by 47 publications

(33 citation statements)

References 50 publications

(66 reference statements)

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“…The higher temperatures, more days with extreme high temperatures, and lack of precipitation lead to the simulated lower yields for maize and soybean when irrigation is not included (Jancic, 2016b;Jancic et al, 2015), and to stable and higher yields when the crop is under irrigated conditions (Jancic et al, 2015). Simulations with the CO 2 effect also gave higher yields, as in previous studies, for soybean (CECILIA, 2006;Jancic et al, 2015;Mihailović et al, 2014;Southworth et al, 2002;Wittwer, 1995) and maize (Jancic, 2016a;Mihailović et al, 2014;Wang et al, 2011). The expected increase in temperature and lack of precipitation caused higher net irrigation and lower IWUE values in the simulated maize and soybean crop productions under optimum available water conditions.…”

Section: Climate Change Impact On Yield Net Irrigation and Iwue Forsupporting

confidence: 74%

“…Experimental fields were in Rimski Sancevi, located in the southern part of the Pannonian lowland (latitude 45° 20' N, longitude 19° 51' E, altitude 84 m). The experimental field location was characterized by a moderate continental climate (Mihailović et al, 2014) with an annual maximum temperature of 16.3 °C, minimum temperature of 5.9 °C, relative humidity of 74.8%, and precipitation of 576.8 mm (Rimski Sancevi station records for . The fields are the property of the Institute for Field and Vegetable Crops.…”

Section: Location and Experimental Datamentioning

confidence: 99%

“…This study is important for assessing the risk of climate change impact on maize and soybean yield and irrigation water use efficiency (IWUE) to maintain economically high production under optimum irrigation and for estimating potential limitations under future conditions. Both crops have a growing season from April to September (AS period), during which less precipitation, higher temperature, and more days with extreme high temperatures were predicted (Jancic, 2017;Jancic et al, 2015;Mihailović et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

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Modeling the impact of climate change on yield, water requirements, and water use efficiency of maize and soybean grown under moderate continental climate in the Pannonian lowland

Tovjanin¹,

Djurdjević²,

Pejić³

et al. 2019

Időjárás

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⎯ In Central and Eastern Europe, climate changes have been predicted (Trnka et al., 2009). These changes are expected to have a great impact on field crops during the spring-summer growing season. The aim of this paper is to estimate the impact of climate change on the main field crops (maize and soybean) in the Republic of Serbia. The AquaCrop model was used as a tool to quantify climate change impact on yield and net irrigation using results from the ECHAM climate model (SRES A2 scenario for the 2041-2070 and 2071-2100 periods) and data from two experimental fields located in the southern part of the Pannonian lowland. The analyzed results for the 2041-2070 and 2071-2100 periods showed an increase in maize (1 and 1.3 t/ha) and soybean (1.9 and 2.8 t/ha) yields and a very significant increase in the net irrigation of 151.4 and 183.1 mm in maize production and 179.3 and 227.3 mm in soybean production under climate change conditions compared to the 1961-1990 period. Additionally, irrigation water use efficiency was calculated to estimate the importance of irrigation, because crop production is usually conducted under rainfed conditions. It was concluded that maize and soybean production should benefit from climate changes but with higher water quantities.

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Section: Climate Change Impact On Yield Net Irrigation and Iwue Forsupporting

confidence: 74%

Section: Location and Experimental Datamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Modeling the impact of climate change on yield, water requirements, and water use efficiency of maize and soybean grown under moderate continental climate in the Pannonian lowland

Tovjanin¹,

Djurdjević²,

Pejić³

et al. 2019

Időjárás

View full text Add to dashboard Cite

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“…Lalić et al (2013) have indicated that there is an increasing trend in the observed extreme winter and summer temperatures in the Pannonian lowland. Mihailović et al (2015a) showed that it is possible to expect the shifts of Köppen climate zones in the near future; and accordingly, changes there would appear in crop yields. Besides them, other authors were using various statistical methods to analyze the spatial and temporal variability of the precipitations in Serbia in the second half of twentieth century.…”

Section: Introductionmentioning

confidence: 99%

“…The climate of Serbia can be described as mild-temperate-continental, with significant precipitation during all seasons, dry winters, and second precipitation maximum in autumn. However, the climate of Serbia is influenced by the Alps, the Mediterranean Sea, the Genoa Gulf, the Pannonian basin, the Moravian valley, the Carpathian and Rhodope mountains, the hillymountainous part with ravines and the highland plains, as well as the deep southward penetration of polar air masses, which leads to a high spatial variability (Radinović 1979;Mihailović et al 2015a). …”

Section: Introductionmentioning

confidence: 99%

Complexity analysis of the air temperature and the precipitation time series in Serbia

Mimić

Mihailoviĉ

Kapor

2015

Theor Appl Climatol

Self Cite

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In this paper, we have analyzed the time series of daily values for three meteorological elements, two continuous and a discontinuous one, i.e., the maximum and minimum air temperature and the precipitation. The analysis was done based on the observations from seven stations in Serbia from the period 1951-2010. The main aim of this paper was to quantify the complexity of the annual values for the mentioned time series and to calculate the rate of its change. For that purpose, we have used the sample entropy and the Kolmogorov complexity as the measures which can indicate the variability and irregularity of a given time series. Results obtained show that the maximum temperature has increasing trends in the given period which points out a warming, ranged in the interval 1-2°C. The increasing temperature indicates the higher internal energy of the atmosphere, changing the weather patterns, manifested in the time series. The Kolmogorov complexity of the maximum temperature time series has statistically significant increasing trends, while the sample entropy has increasing but statistically insignificant trend. The trends of complexity measures for the minimum temperature depend on the location. Both complexity measures for the precipitation time series have decreasing trends.

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Response of shallow soil temperature to climate change on the Qinghai–Tibetan Plateau

Wang

Chen

Han

et al. 2020

Intl Journal of Climatology

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Under climate change, soil temperature change remarkably influences regional landscapes, ecosystems, hydrological processes, and other parameters. Based on daily soil temperature data from 56 stations from 1965 to 2014, the spatiotemporal variations in shallow soil temperature (0, 5, 10, 15, and 20 cm) on the Qinghai-Tibetan Plateau (QTP) were investigated. The mean shallow soil temperature decreased obviously with altitude both annually and seasonally, except in winter. Primarily dependent on station latitude, the spatial distribution of winter soil temperature was significantly affected by the snow cover conditions. As the soil depth increased, the soil temperature showed a cooling trend in spring and summer but a warming trend in autumn and winter. In the past 50 years, the shallow soil temperature increased considerably on the QTP both annually and seasonally. The warming rate of soil temperature was greatly dependent on station altitude in winter and dependent on latitude in summer and longitude in autumn. Unlike the increasing air temperature that was contributed mainly by winter, the warming rate of soil temperature in winter at depths of 5, 10, 15, and 20 cm was obviously lower than that in other seasons and air temperature in winter. This occurrence may be caused by relatively less snow cover in winter, which produces a weak insulation effect and further makes the soils more vulnerable to cooling from cold air. For the entire region, the soil temperature variability was strongly correlated with the change in air temperature but weakly correlated with precipitation. Although the warming rate in shallow soil tended to be low (high) at stations with a high amount of precipitation (snow cover), the influence of precipitation (including snow) on shallow soil temperature was limited on the QTP in the past few decades.

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Climate change effects on crop yields in Serbia and related shifts of Köppen climate zones under the SRES‐A1B and SRES‐A2

Cited by 47 publications

References 50 publications

Modeling the impact of climate change on yield, water requirements, and water use efficiency of maize and soybean grown under moderate continental climate in the Pannonian lowland

Modeling the impact of climate change on yield, water requirements, and water use efficiency of maize and soybean grown under moderate continental climate in the Pannonian lowland

Complexity analysis of the air temperature and the precipitation time series in Serbia

Response of shallow soil temperature to climate change on the Qinghai–Tibetan Plateau

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