1. Introduction
The Earth’s hydrological cycle involves the continuous movement of water between the Earth’s surface, the atmosphere, and back, driving various natural processes. Water is important not only for humans but for all living beings on Earth. Observations of changes in the Earth’s natural water cycle, the consequence of which is a reduction in groundwater levels, indicate a worrying decrease in the area of land with retention characteristics [
1]. One of the main reasons for this situation is the increase in urbanisation, industrial development, and agriculture, which result in greater water consumption than the possibility of replenishment through natural processes. Any destabilisation of the water cycle in the environment results in a disequilibrium of the water cycle, which may increase its scarcity or cause its excess [
2]. Therefore, it is particularly important to carry out rational water management, which would allow for the efficient use of rainwater while at the same time allowing for the renewal of water resources. In rivers, water renews itself in 18–20 days, in the atmosphere in 12 days, and in a lake in 10 years, while groundwater requires a much longer time of more than 5000 years, and a long period of about 8000 years is required for water contained in glaciers [
1]. The problem also lies in the quality of water, as the availability of fresh water for human use is limited. Both natural processes, including weathering of rocks and biological processes, as well as anthropogenic influences like agriculture, industrial effluents, and mining, affect the water quality by altering mineral content, pH, alkalinity, and introducing pollutants like heavy metals, mercury, coliforms, and nutrients [
3].
It may seem that our planet’s water resources are limitless, as seventy percent of the Earth’s surface is covered by water. However, only a negligible percentage of water exists in the form of fresh water ready for consumption. The majority of the Earth’s water resources are salt water—98%—and only 2% are fresh water. Given this 2%, most of the approximately 1.5% of water is accumulated in the ice caps at the North and South Poles, which have been declining in recent years. This amount of available freshwater in the form of groundwater or surface water that can be used for consumption or food production represents only about 0.5% of total water resources [
1].
On Earth, around 35 million km
2 of the land area is characterised by water scarcity. These are areas where evaporation exceeds precipitation. Across the globe, evaporation and precipitation are of equal magnitude, averaging 1000 mm per year. Precipitation on the land surface is about 710 mm, while evaporation averages about 470 mm per year; runoff (surface, ground, and subsurface), on the other hand, is about 240 mm per year. Evaporation is higher as more solar energy reaches the area [
1].
As a result, a permanent scarcity or lack of freshwater is present in about 60% of the land area, where about 700 million people live, or about 10% of the world’s human population. At the same time, there are areas in the world that, with a small population, have very large freshwater resources (amount of rainfall), e.g., the Amazon [
1].
Poland, as a country, has modest water resources and ranks 24th in Europe in terms of the volume of renewable freshwater resources per capita—1600 m
3, while per capita in Europe, there are 4011 m
3 [
1,
4]. According to the United Nations (UN), water resources in Poland are below the water security level [
4]. In addition, the area of Poland is characterised by high variability of water resources in time and space. The most scarce natural areas fed by precipitation are those located in the central belt of Poland [
5]. The situation is different in submontane regions, where there is more precipitation. In these regions, excessive precipitation may contribute to flooding and waterlogging. In addition to spatial variability, there is high variability in precipitation, both annually and over many years. Under the climatic conditions of central Europe, the highest flows in watercourses usually occur in spring, while the lowest flows occur in summer and autumn. In recent years, variability in river outflows has been noticeable. Surface and groundwater levels have decreased significantly, causing droughts in many regions, while other areas often experience inundation, flooding, and floods [
1].
The reason for this situation is most often economic activity, which in many cases has reduced the natural retention capacity of the catchment area. The rapid discharge of water in spring floods and after precipitation has worsened the structure of the water balance of Poland’s natural resources. Water scarcity is particularly acute during the growing season, especially when a dry summer is preceded by a snowless winter [
1].
The second reason for the deterioration of the water balance structure is caused by increased water abstraction for municipal, industrial, and agricultural purposes. At present, agricultural production in Poland is based mainly on precipitation; only a negligible percentage of crops are irrigated [
2], but in the near future, due to climate change, an increase in irrigation needs in field agricultural production, especially horticultural and orchard production, will be necessary. Under conditions of low freshwater resources in the near future, this may lead to an increasing dependence of food production on non-renewable water consumption. All the above-mentioned factors will worsen the water balance, which is why it is necessary to take a number of both preventive and intervention measures to ensure that water resources are used rationally [
2]. There is, therefore, a natural need to make increasingly efficient use of existing water resources.
A worrying trend for agriculture is the observed changes in the distribution of rainfall over the year. Larger but less frequent precipitation events may cause many environmental changes, e.g., increase the risk of flooding, increase soil erosion, change the volume of surface runoff, alter water infiltration, and even increase the risk of agricultural drought. This is indicated by climate scenarios, according to which an increase in the variance of precipitation, up to 20%, is to be expected. According to Kundzewicz and Kozyra [
6], climate models unanimously show that precipitation in some mid-latitude areas will decrease in the summer. However, projections of precipitation changes are characterised by high uncertainty. The geographical location of Poland means that wet air masses and snowfall have usually arrived in the winter. However, in recent years, snow cover in Poland has been decreasing. Its absence increases the frequency and duration of drought episodes, especially during the growing season, when we need water the most. Therefore, water resources may be less available in the 21st century.
To prepare for upcoming changes, including those affecting the Vistula River basin, it is essential to understand the impact of climate change on the environment, such as the occurrence of extreme weather events, droughts, and violent storms. Such knowledge is indispensable for developing solutions that mitigate the adverse effects of climate change [
7,
8].
There is growing interest in understanding the interactions between climate change and agricultural production, and this is motivating a significant amount of research [
9].
A wide variety of studies are being conducted in Poland using the SWAT model, both for small catchments [
10,
11,
12,
13,
14,
15,
16,
17] and large catchments [
18,
19,
20,
21]. A paper on two small catchments, the Gąsawka and Rega, and one large catchment, the Warta, analysed the effect of catchment size on the calibration process and simulation results [
18]. The peculiarities of hydrological phenomena occurring in Central Europe and the lack of sufficiently long measurement series for small catchments have a significant impact on the results obtained from the SWAT model for catchments in Poland [
18].
Applying the SWAT hydrological model, the study examined the impact of climate change on water resources in the Central and Eastern European regions [
21]. The research utilised a set of nine climate simulations from EURO-CORDEX, corrected for systematic errors, for the time horizons of 2024–2050 and 2074–2100 under two representative concentration pathways (RCPs), to forecast future water balance and streamflow conditions in the Vistula and Oder river basins. This comprehensive dataset can be valuable for scientists, water managers, and decision-makers in the water sector. However, the authors emphasise that the forecasts are subject to considerable uncertainty, as detailed in the documentation [
21]. For the Vistula and Oder catchments, another study was conducted using the SWAT model [
19,
20].
In 2015, a publication on a high-resolution SWAT model addressing hydrology and water quality at a continental scale for Europe was released [
22]. The study covered various large river basins in Europe, including Aare, Angermaelven, Danube, Dnieper, Duero, Ebro, Elbe, Garonne, Guadalquivir, Inn, Luleaelven, Loire, Maros, Northern Dvina, Oder, Olt, Pechora, Po, Rhine, Rhone, Sava, Siret, Szamos, Tiber, Thames, Tisza, Trent, Vistula, and Volga.
The research was motivated by the increasing impact of various factors on local, national, and regional water sources crucial for irrigation, energy production, industrial purposes, domestic use, and environmental conservation. Consequently, in many European regions, groundwater resources are diminishing and their quality is deteriorating. Climate change adds an additional challenge, introducing a new level of uncertainty regarding the availability of freshwater. The utilisation of large and precise water resource models facilitated a comprehensive investigation of integrated system behaviour through simulations based on physical data. The calibrated model and its outcomes can provide valuable information and support for water managers, particularly in Eastern European countries where rapid economic development may pose challenges related to freshwater availability [
22].
The developed approach and methods in the study are general and can be applied to any large region worldwide [
22].
The aim of this study is to analyse the hydrology of the Vistula River basin in climate projections for the years 2020–2050 under the climate change scenarios of RCP 4.5 and RCP 8.5 and to assess it in relation to the current state of knowledge related to research covering the European continent as well as small regional watersheds.
5. Results of the Application of RCP 4.5 and RCP 8.5 for 2020–2050
After calibration and validation of the SWAT model, flow simulations were carried out for the Vistula catchment for two climate scenarios and three models for the period 2020–2050.
To compare climate change scenarios for individual forecasts, a single iteration was conducted in SWAT-CUP using the best calibration parameters. In addition, for the RCP 4.5 and RCP 8.5 scenarios, changes in CO
2 concentrations were assumed for each decade: from 2021 to 2030, from 2031 to 2040, and from 2041 to 2050, as developed by the Potsdam Institute for Climate Impact Research [
58,
59].
Average annual precipitation totals for most projections (except the RCP 4.5.C) will show an increasing trend in the following decades (
Figure 5).
In the upcoming decades, the average annual temperature is expected to rise in all three projections for both the RCP 4.5 and RCP 8.5 scenarios.
The annual average number of days without precipitation shows a clear downward trend in RCP 8.5.A. On the other hand, a clear upward trend is visible in RCP 4.5.B. In the other projections, the trend changes minimally over the next few years (
Figure 6 and
Figure 7).
The annual average number of days with a mean temperature above 5 °C in the coming decades will increase significantly for most forecasts, with the exception of RCP 4.5.A, where the trend will be downward.
The mean seasonal precipitation totals for the Vistula catchment in the 2013–2018 simulation years change compared to the individual climate change projections in 2021–2030, 2031–2040, and 2041–2050 (
Table 4). These changes are particularly evident in the JJA (June, July, and August) season, where an increase in precipitation is observed in all projections. For most projections, an increase in seasonal average precipitation is also seen in DJF (December, January, and February) and MAM (March, April, and May). The exception is the SON (September, October, November) season, where reductions in rainfall occur most frequently, up to 20%. For the RCP 4.5.C, RCP 8.5.B, and RCP 8.5.C projections, the seasonal mean precipitation is higher in most seasons than in the 2013–2018 simulation years.
The average annual precipitation for all projections in 2021–2030, 2031–2040, and 2041–2050 will be up to 22% higher (projection RCP 8.5.C—2041–2050) compared to the simulation years 2013–2018.
The average seasonal temperature patterns within the Vistula catchment during the 2013–2018 simulation years also exhibit changes when compared to the individual climate change projections for 2021–2030, 2031–2040, and 2041–2050 (
Table 5). These changes are particularly pronounced in 2031–2040 and 2041–2050, where, for most seasons in all projections, the seasonal mean temperature will be higher than in the SWAT 2013–2018 simulation period. The highest increases (up to 1.4 °C) in temperature are recorded for the MAM season for all decades. The highest increases in annual mean temperature (up to 1.2 °C) are recorded for RCP 8.5.B and RCP 8.5.C projections for 2031–2040 and 2041–2050 compared to the simulation period (2013–2018).
The average annual temperature for most climate projections for 2021–2030 will fall to as low as 8.7 °C (RCP 4.5.B) compared to the 2013–2018 simulation period (9.2 °C). In contrast, for all projections in 2031–2040 and 2041–2050, the average annual temperature will increase to as much as 10.3 °C (RCP 8.5.C).
In all projections for the RCP 8.5 scenario, the average annual total runoff will trend upwards (
Figure 8). The trend in annual total runoff will be similar.
The seasonal average total runoff for the Vistula catchment is expected to be higher for the majority of climate change projections in 2021–2030, 2031–2040, and 2041–2050 when compared to the simulation years of 2013–2018 (
Table 6). The exception is the DJF season in 2041–2050, where, for most projections, the total runoff will be lower. In contrast, for the JJA season for all decades, the total runoff will be higher by up to 93% compared to the SWAT 2013–2018 simulation.
The average annual total runoff for most projections in the following decades (2021–2030, 2031–2040, 2041–2050) will increase up to 159 mm (RCP 4.5.B—2021–2030) compared to the 2013–2018 simulation period—116 mm.
The trend line for the annual average of potential evapotranspiration in the climate change scenarios RCP 4.5.A, RCP 8.5.A, and RCP 8.5.B is expected to show a slight decrease in the upcoming decades (
Figure 9). Conversely, in the climate change scenarios RCP 4.5.C, RCP 8.5.C, and RCP 4.5.B, the annual average of potential evapotranspiration is projected to increase in the future decades.
The trend in the annual average sum of actual evapotranspiration from 2020 to 2050 changes marginally across all projections.
Seasonal mean current evapotranspiration increases for most projections in all seasons compared to the 2013–2018 simulation period, with the highest increases occurring in the DJF and SON seasons (
Table 7).
The average annual actual evapotranspiration for all projections in 2021–2030, 2031–2040, and 2041–2050 will increase up to 467 mm (RCP 4.5.A—2021–2030) compared to the 2013–2018 simulation period of 401 mm.
For potential evapotranspiration as well, the seasonal mean totals are anticipated to increase in most projections across all seasons when compared to the 2013–2018 simulation period, with the most significant increases occurring in the DJF and SON seasons. (
Table 8).
The average annual potential evapotranspiration for all projections in 2021–2030, 2031–2040, and 2041–2050 will increase up to 755 mm (RCP 8.5.C—2031–2040) compared to the 2013–2018 simulation period—616 mm.
When analysing the spatial distribution of changes in mean annual precipitation across the 23 sub-catchments from the 2013–2018 simulation period to the 2041–2050 period (
Figure 10) in the individual climate projections of RCP 4.5 and RCP 8.5 in the Northwest, South, and East regions, precipitation is expected to increase by several tens of percent. Increased average annual precipitation in most sub-basins between 2041 and 2050 will occur in the climate projections and RCP 8.5.B for the RCP 8.5 scenario. On the other hand, for all projections in the RCP 4.5.B scenario between 2041 and 2050, precipitation in the central region of the Vistula basin will be reduced by up to 16 percent.
Annual mean total runoff totals over the 2013–2018 SWAT simulation period will be lower in most regions in the coming decades for most climate projections, with the exception of projection RCP 8.5.C (
Figure 11). Larger annual mean total runoff totals can be found in the Northwest and South regions.
6. Discussion
The objective of this paper is to examine the hydrology of the Vistula catchment within the climate projections for 2020–2050, considering the climate change scenarios RCP 4.5 and RCP 8.5, and to evaluate it in light of the existing body of knowledge concerning research spanning both the European continent and smaller regional catchments.
The climate projection for Poland shows increased monthly precipitation values in winter and summer for the RCP 4.5 scenario for 2021–2030 compared to 2011–2020 [
57]. In contrast, in spring, average monthly precipitation is lower than in 2011–2020. In the RCP 8.5 scenario for 2021–2030, average monthly precipitation changes slightly in most months compared to 2011–2020, while in autumn months, average monthly precipitation is higher in 2021–2030 [
57]. In the article, all climate projections for 2021–2030 for the RCP 4.5 and RCP 8.5 scenarios are characterised by higher precipitation in winter (DJF) and summer (JJA) compared to 2013–2018. In autumn (SON), precipitation will be lower for most projections for 2021–2030. The same will be true for spring (MAM). For RCP 8.5.C projections for 2021–2030, most projections predict higher precipitation in winter, spring, summer, and autumn (
Table 4).
The climate projection for the RCP 4.5 scenario for 2041–2050 shows increased monthly precipitation values in winter, summer, and autumn. In contrast, the spring months show lower average monthly precipitation compared to 2011–2020. For the RCP 8.5 scenario for 2041–2050, all months show increased average monthly precipitation compared to 2011–2020 [
57]. In the paper, all climate projections for 2041–2050 for the RCP 4.5 scenario are characterised by higher average seasonal precipitation in summer (JJA) compared to 2013–2018. In autumn (SON), precipitation will be lower for RCP 4.5.A and RCP 4.5.B projections. In winter (DJA) and spring (MAM), precipitation will be higher for most projections. For RCP 8.5.A, RCP 8.5.B, RCP 8.5.C projections between 2041 and 2050, most projections predict higher precipitation in winter, spring, summer, and autumn (
Table 4).
Changes in mean annual precipitation and total runoff were also considered in a publication on runoff in the Oder and Vistula catchments [
20]. The publication shows that when comparing the 1971–2000 simulation period with the 2021–2050 period for RCP 4.5 and RCP 8.5 scenarios, there is an increase in mean annual precipitation and mean annual total runoff. In this paper, mean annual total runoff and mean annual precipitation tend to increase for most projections compared to the 2013–2018 simulation years.
The occurrence of drought in Poland has been an increasingly frequent and intense phenomenon in recent years, especially since 2006 [
7]. It is a serious economic problem for the whole country. Drought causes large crop losses, reducing farmers’ income and thus increasing the price of food products [
8]. The drought in 2015 had a very negative impact on agricultural crops. It occurred among all monitored crops [
60]. The very hot and dry summer resulted in a hydrological drought in addition to heavy agricultural losses [
61]. A partial water shortage also occurred in 2016 [
62]. On the other hand, in 2017, no agricultural drought occurred in Poland in most reporting periods (9 out of 14 reports) [
63]. Analysing 2018 from January to September, it can be concluded that it was a year characterised by high air temperatures (April, May, June, July, and August). In April and May, large differences were found in terms of precipitation. June was characterised by very low precipitation (except in the southern part of Poland). July, on the other hand, was characterised by high rainfall (except in the southern part of Poland). August was exceptionally warm this year, with varied precipitation [
64]. The persistent precipitation deficiency from mid-April onwards, combined with high air temperatures and considerable sunshine, resulting in increased evaporation, caused droughts from April to September over large areas of Poland [
37].
As per the National Oceanic and Atmospheric Administration (NOAA), 2017 ranked as the second-hottest year globally in recorded meteorological history (since 1880) [
65]. Climate change will also affect Poland in the future. Analysis of climate scenarios for 2021–2050 shows that the growing season in Poland, defined by the number of days with an average daily air temperature higher than 5 °C in the 2021–2050 perspective, will be longer than in 1971–2000 by 16 days. The predicted higher temperature during the growing season would significantly accelerate the development of plants [
57]. The trend in the annual average number of days with a mean temperature above 5 °C between 2020 and 2050 for most climate projections will increase, with the exception of the projection for scenario RCP 4.5.A (
Figure 8).
Changes in the sum of mean annual precipitation in Poland between the control period 1971–2000 and the period 2021–2050 were compared for the RCP 4.5 scenario [
66]. The publication shows that the sum of mean annual precipitation between the control period 1971–2000 and the period 2021–2050 will increase by 6.4%. For the Vistula basin, the sum of mean annual precipitation will increase between 2021 and 2050 for all climate projections compared to the simulation years 2013–2018.
In a publication on the Oder and Vistula catchments [
19], the application of the SWAT model to simulate the water balance and natural flow of watercourses in the Vistula and Oder catchments from 1984 to 2013 is presented, followed by the results in the form of the concepts blue water flow, green water flow, and green water storage [
67,
68]. Blue water flow is the sum of ‘water yield’ and ‘deep aquifer recharge.’ Green water flow is the actual evapotranspiration, while green water storage is the soil water content [
19]. Average results for the Vistula basin from 1984 to 2013 show blue water flow at 188 mm, green water flow at 521 mm, and green water retention at 211 mm. Results obtained for this article (2013–2018): blue water flow 234 mm, green water flow 402 mm, green water storage 171 mm. The values obtained [
19] were compared with the results of publications on the SWAT hydrological model for Europe [
22] from 1973 to 2006. Blue water flow for Poland ranges from 50 to 200 mm, green water flow from 390 to 430 mm, and green water storage from 100 to 190 mm. The discrepancies in the results are probably due to the lower resolution of the HWSD 1: 1,000,000 and IUNG-PIB 1: 500,000 soil maps, which were introduced into the SWAT model in the article on the Vistula and Odra regions [
19]. In this publication, the soil map IUNG-PIB 1: 100,000 was mainly used. While preparing the soil data, we took into account that the available water-holding capacity values are applicable to the soils in the Vistula River basin. These values were derived from a study conducted in 2013 by researchers from the Department of Soil Science, Erosion, and Soil Protection at IUNG-PIB in Puławy [
69].
An examination of publications regarding the influence of climate change on the water resources of three Ukrainian catchments was conducted utilising the SWIM model [
70]. One of the catchments studied is the Bug River. The study area of the Bug catchment included its part located in Ukraine, which is also included in the area of the present study [
71]. Studies have shown an increase in precipitation, especially in spring and winter, and an increase in temperature under most climate change scenarios, which is also confirmed in this article.
Consistent findings regarding increased precipitation and temperature for climate change scenarios between 2071 and 2100 were achieved in studies of three Estonian catchments employing the SWAT model [
72] and two catchments in Poland [
10].
The study for the Neajlov River (southeastern part of Romania) with a catchment area of 3720 km
2 used output data from three GCMs (CNRM, MPR, and ICHEC) under two future climate projections (RCP 4.5 and RCP 8.5) in SWAT, which cover the periods 2021–2050 and 2071–2100 [
73]. The projected changes in temperature and precipitation will be most noticeable during the growing season, leading to increased water stress. Different climate change scenarios, such as RCP 4.5 and RCP 8.5, exhibit diverse impacts on the hydrological cycle. In both short- and long-term perspectives, projected changes in temperature and precipitation will affect soil water content and streamflow, particularly in the lower watershed areas. For RCP 4.5, a moderate increase in SW is anticipated in the short term, but in the long term, a decline is expected, while RCP 8.5 indicates more significant reductions in both short- and long-term periods. This finding underscores the need to consider this diverse response to climate change when planning adaptive strategies related to water resources, with particular attention to lower watershed areas that appear more sensitive to these changes [
73].
In a study conducted for the Manning River catchment in eastern Australia, hydrological responses to climate change were examined using the Xinanjiang (XAJ) model and downscaled climate data from 28 global climate models (GCMs) under RCP 8.5 scenarios [
74].
The results show a slight decrease in annual precipitation and runoff between 2021 and 2060, followed by an increase between 2061 and 2100. While annual actual evapotranspiration is projected to increase slightly, soil moisture content is expected to decrease in the future. Changes in rainfall mainly affect future changes in seasonal and annual runoff, actual evapotranspiration, and soil moisture, with temperature changes playing a lesser role. The 28 GCM team predicts increased monthly and seasonal variability in water resources, characterised by higher values of high runoff and lower values of low runoff [
74].
In a study conducted in the Gediz watershed in Turkey, downscaled general circulation model (GCM) data for monthly precipitation were utilised, employing representative concentration pathways (RCP). Projections were based on output data from 12 GCMs for the period 2015–2050. The findings indicate a significant decreasing trend in precipitation for the RCP 8.5 scenario, while it is less pronounced for the RCP 4.5 and RCP 6.0 scenarios [
75]. This is an example of the impact of different climate change projection scenarios on the hydrological cycle.
The climate analysis for 1970–2004 reveals a statistically significant rise in total evapotranspiration throughout the growing season. Additionally, the years 2021–2030 and 2041–2050 exhibit an increase in potential evapotranspiration during the growing season (
Table 7) [
76].
The actual evapotranspiration, potential evapotranspiration, mean annual precipitation, and mean annual total runoff were also compared with the results of a publication on actual evapotranspiration in Europe [
77]. Mean annual evapotranspiration, mean annual precipitation, and mean annual total outflow cover the years 2002–2014. For the Vistula basin, the mean annual actual evapotranspiration is in the range of 300–500 mm, the mean annual precipitation in the aforementioned publication is in the range of 500–700 mm, and the mean annual total outflow is in the range of 100–200 mm. The mean annual potential evapotranspiration covers the period 2002–2012 and is in the range of 650–750 mm. Similar results for potential evapotranspiration are included in a publication on the impact of climate change on Europe [
78].
In conclusion, there are some differences in the results, but explaining these would require an extensive analysis of other potential factors influencing the spatial variability of the runoff response, such as land cover, soil, and hydrogeology. Such an analysis could be carried out in future studies.
7. Summary
Most climate change projections for the RCP 4.5 and RCP 8.5 scenarios show a trend of increasing temperature and precipitation in the coming decades. For most of the projections, the number of days with an average temperature above 5 °C will be higher, indicating that the growing season will become longer in the future. However, there are no clear results on how precipitation-free periods will develop in the future, as the number of days without precipitation varies from forecast to forecast.
For most of the projections analysed, the distribution of seasonal mean temperature in 2021–2030, 2031–2040, and 2041–2050, relative to the 2013–2018 period, indicates higher temperatures in the MAM season.
The average annual temperature for most climate projections for 2021–2030 will fall to as low as 8.7 °C (RCP 4.5.B) compared to the 2013–2018 simulation period (9.2 °C). In contrast, for all projections in 2031–2040 and 2041–2050, the average annual temperature will increase to as much as 10.3 °C (RCP 8.5.C).
A change in the seasonal distribution of rainfall is also to be expected. For most of the projections for 2021–2030, 2031–2040, and 2041–2050, precipitation is expected to increase in the JJA season compared to the 2013–2018 period. On an annual basis, precipitation is expected to be higher in the Northwest, South, and East regions by up to several tens of percent. In contrast, the amount of precipitation will decrease in the Central Vistula region by up to 17 percent for all projections in the RCP 4.5 scenario and for RCP 8.5.A and RCP 8.5.B projections in the RCP 4.5 scenario from 2041 to 2050. For most sub-catchments, increased annual precipitation is projected from 2041 to 2050 for climate projections RCP 8.5.C and RCP 8.5.C.
The average annual precipitation for all projections in 2021–2030, 2031–2040, and 2041–2050 will be higher by up to 22% (763 mm) (RCP 8.5.C for 2041–2050) compared to the 2013–2018 simulation years (624 mm). The trend of current evapotranspiration and potential evapotranspiration will differ between the 2020 and 2050 projections. The trend line of the average annual sum of potential evapotranspiration in projections RCP 8.5.A and RCP 8.5.B will decrease slightly in the coming decades. On the other hand, for the RCP 4.5.C and RCP 8.5.C projections and the RCP 4.5.B scenarios, the average annual sum of potential evapotranspiration increases in the coming decades.
The average annual actual evapotranspiration for all projections in 2021–2030, 2031–2040, and 2041–2050 will increase up to 467 mm (RCP 4.5.A—2021–2030) compared to the 2013–2018 simulation period of 401 mm.
The average annual potential evapotranspiration for all projections in 2021–2030, 2031–2040, and 2041–2050 will increase up to 755 mm (RCP 8.5.C—2031–2040) compared to the 2013–2018 simulation period—616 mm.
The trend of average annual evapotranspiration totals between 2020 and 2050 in all projections changes slightly.
In most climate projections, seasonal average evapotranspiration and potential evapotranspiration totals will be higher compared to the 2013–2018 model simulation period.
The average annual total runoff in all projections for the RCP 4.5 scenario will decrease between 2020 and 2050. On the other hand, in all projections for the RCP 8.5 scenario, the average annual total runoff will trend upward.
The average annual total runoff for most projections in the following decades (2021–2030, 2031–2040, and 2041–2050) will increase up to 159 mm (RCP 4.5.B—2021–2030) compared to the 2013–2018 simulation period—116 mm.
The average annual total runoff over the 2013–2018 simulation period will be lower in most regions in the coming decades for most climate projections, with the exception of RCP 8.5.A. A larger average annual total runoff can be found in the Northwest and South regions. All of the above changes in the individual components of the water balance may adversely affect crop vegetation in 2020–2050. The trend of increased temperatures and reduced precipitation may lead to long-term climate change as well as increased extreme events. Increased seasonal mean evapotranspiration and changes in soil water content may disrupt the vegetation of crops grown in Poland at every stage of growth, from sowing to harvest. The trend of an increase in average annual total runoff for the RCP 8.5 scenario and changes in the periods of the year when runoff will be higher may exacerbate erosion phenomena. Changes in the water balance between 2020 and 2050 will also depend on the particular Vistula catchment region.
This study contributes to a better understanding of the impact of climate change on hydrological processes at the watershed scale. Furthermore, the methodology applied in this research can be applied in other regions and consider additional factors such as land use and land cover changes to assess the influence of climate change on hydrological processes. It can provide support in formulating and implementing effective water resource management plans to minimise the impact of future climate changes on watershed-scale water resources.