This study attempts to analyze several drought features in South Korea from various perspectives using a three-month standard precipitation index. In particular, this study aims to evaluate changes in spatial distribution in terms of frequency and severity of droughts in the future due to climate change, using IPCC (intergovernmental panel on climate change) GCM (general circulation model) simulations. First, the Mann-Kendall method was adopted to identify drought trends at the five major watersheds. The simulated temporal evolution of SPI (standardized precipitation index) during the winter showed significant drying trends in most parts of the watersheds, while the simulated SPI during the spring showed a somewhat different feature in the GCMs. Second, this study explored the low-frequency patterns associated with drought by comparing global wavelet power, with significance test. Future spectra decreased in the fractional variance attributed to a reduction in the interannual band from 2 to 8 years. Finally, the changes in the frequency and the severity under climate change were evaluated through the drought spell analyses. Overall features of drought conditions in the future showed a tendency to increase (about 6%) in frequency and severity of droughts during the dry season (i.e., from October to May) under climate change.
Ministry of Land, Infrastructure and Transport15AWMP-B079625-021. Introduction
There exists a degree of climate variability on all time scales, and floods and droughts are extremes associated with variability in precipitation. Climate variability characterized by a slow-varying oscillation in the climate system can modify the likelihood of hydrologic extreme events. Together with climate variability, climate change is regarded as another potential driver for modifying the hydrological cycle [1–3]. Climate change refers to any long-term, significant change in the expected patterns of average weather in a specific region [4]. It has been widely acknowledged that the frequency and magnitude of extreme hydrologic events can be modulated by enhanced climate variability driven by climate change [1, 3, 5]. According to the precipitation outlook based on climate change scenarios [4], increasing concentrations of greenhouse gases are likely to trigger very different patterns of heavy rain, extreme drought, and heavy snow in some regions [6].
In recent decades, extreme drought events seem to be growing in frequency in many countries [7–10]. The frequency of a specific hydrologic variable, especially, should not be treated independently of the frequency of the generating mechanisms [1, 3, 11, 12]. There is evidence of a spatiotemporal organization for drought, which takes the form of band-limited and quasi-oscillatory variations, seen with the El Niño-Southern Oscillation. The rainfall data for South Korea exhibits long memory or regimes with quasi-oscillatory behavior that may derive from low-frequency Pacific and Indian Ocean climate modes [1]. The connection between these low-frequency climate modes and rainfall in South Korea has been noted by several researchers [1, 13, 14].
In terms of investigating drought variability and trends, Kwon and Moon [15] employed a wavelet transform (WT) analysis method and assessed its applicability to hydrologic time series. Kwon and Moon [16] investigated teleconnections between the El Niño/La Niña-Southern Oscillation (ENSO) index and the Palmer Drought Severity Index (PDSI) with respect to low-frequency modulation. They utilized cross wavelet transform and Multichannel Singular Spectrum Analysis (MSSA) as the main tool for the decomposition of time series. Kim [17] analyzed the variability of precipitation in California, USA, using the WT, and Yoon et al. [18] assessed major historical drought events in terms of duration based on the drought index for each duration in each district. Kim et al. [19] applied a nonparametric Mann-Kendall (MK) statistical trend test to SPI for the representative watersheds in South Korea.
South Korea has been already classified by the United Nations as a country suffering from a more than moderate water shortage. Indeed, South Korea has experienced much more frequent and extreme droughts and floods since the late 1990s [20], and drought risk is likely to increase over the course of the twenty-first century due to climate change [6, 21]. In addition, South Korea is very vulnerable to droughts because most of the cities in South Korea are densely populated with the extensive land use changes, so that meteorological disasters associated with the enhanced droughts are expected to become more severe. In the light of the above, a main objective of this study is first to understand the observed changes in drought and to further examine the relationship between drought and climate change. In this study, we analyzed the statistical features of past droughts that occurred in South Korea and future changes in drought patterns using the SPI as a representative meteorological drought index. The MK and WT were used as a main tool to characterize the trend and variability of drought. In the past, Fourier transforms (FT) have been used extensively to decompose and analyze climate time series data. This type of representation of the underlying signal assumes that climate processes are stationary, with linear, oscillatory dynamics and with fixed amplitudes and phases embedded in a short memory noise process. However, many hydroclimatological processes demonstrate strong nonstationary and nonlinear dynamics [22–24]. Therefore, the adoption of stationary and linear assumptions and the use of FT may not be appropriate in terms of understanding the underlying dynamics [25]. A WT analysis allows a frequency decomposition of the signal with time-varying amplitudes and phases and considers nonlinear oscillation dynamics, which is arguably more useful in understanding climate variability in space and time. Torrence and Compo [26] introduced various WT analysis methods using their application methods with ENSO time series. In addition, Grinsted et al. [27] applied cross wavelet transform and wavelet coherence analysis methods to better analyze underlying variability for various time series. Finally, this study investigated the drought variability, in terms of magnitude and occurrence frequency for five major watersheds in South Korea which were analyzed. The results of our study have the potential to improve water resource management in this region by highlighting management decisions that help to decrease vulnerability to droughts and other crises related to climate variability.
A brief summary of the main concept of this study was presented in this section. Section 2 describes the data set used to investigate the droughts. The relevant theoretical aspects of the MK test and WT analysis are introduced in Section 3. Changes in the trends, periodicities, and frequencies of drought under climate change are described in Section 4. Section 5 includes a discussion and the conclusions.
2. Data2.1. Watershed and Climate Data
The aim of this study was to analyze drought variability for five major watersheds in South Korea (i.e., watersheds of the Han River, Nakdong River, Geum River, Seomjin River, and Yeongsan River). For this research, the primary data is daily levels of precipitation for the Korean Peninsula, and the data is accumulated on a monthly basis for the SPI analysis. In this first respect, of the 77 weather stations operated by the Korea Meteorological Administration (KMA), we select 54 stations that are directly relevant for drought patterns and for which long-term reliable data are readily available (see Figure 1). The remaining 23 stations were excluded because the weather data on record covered periods of less than 30 years. Each site has a different period of record, and there are no missing values. The period of record of precipitation data analyzed here extends from 1976 to 2010, during which full records are available at each station. Both Thiessen and Inverse Distance Weight (IDW) are the simplest commonly used method for estimating areal rainfall. However, Thiessen often provides abrupt implausible change at polygon boundaries. Thus, these series were used for estimating the areal rainfall, using the IDW method. Second, the areal monthly rainfall was used to derive the three-month SPI for each watershed. The observed rainfall data, spanning from 1976 to 2010, were used in conjunction with precipitation simulations from 1976 to 2099 projected by four GCMs. Figure 1(a) shows the weather stations that are used for calculating the SPI. In Figure 1(b), the area in blue represents the 20 medium-size catchments in the Korean Peninsula and indicates the watersheds of the five major rivers analyzed in this study. Tables 1 and 2 show information for the weather stations and the representative watersheds. The watersheds of the Han River, Nakdong River, Geum River, Seomjin River, and Yeongsan River account for approximately 68% of the area of South Korea.
Weather stations of the KMA used in this study.
Code
Name
90
Sokcho
101
Chuncheon
105
Gangneung
108
Seoul
112
Incheon
114
Wonju
119
Suwon
127
Chungju
129
Seosan
130
Uljin
131
Cheongju
133
Daejeon
135
Chupungryeong
138
Pohang
143
Daegu
146
Jeonju
152
Ulsan
156
Gwangju
159
Busan
162
Tongyeong
165
Mokpo
168
Yeosu
170
Wan-do
201
Ganghwa
202
Yangpyeong
203
Icheon
211
Inje
212
Hongcheon
221
Jecheon
226
Boeun
232
Cheonan
235
Boryeong
236
Buyeo
238
Geumsan
243
Buan
244
Imsil
245
Jeongeup
247
Namwon
256
Suncheon
260
Jangheung
261
Haenam
262
Goheung
272
Yeongju
273
Mungyeong
277
Yeongdeok
278
Uiseong
279
Gumi
281
Yeongcheon
284
Geochang
285
Hapcheon
288
Miryang
289
Sancheong
294
Geoje
295
Namhae
Five major watersheds' ID and area (km2) for drought analysis.
Basin name
ID
Area (km2)
Han River
10
23,293
Anseong Stream
11
1,659
West of Han River
12
1,993
East of Han River
13
3,338
Nakdong River
20
23,702
Hyeongsan River
21
1,140
Taehwa River
22
661
Hoeya/Sooyeong
23
865
East of Nakdong River
24
2,895
South of Nakdong River
25
2,449
Geum River
30
9,914
Sapgyo Stream
31
1,668
West of Geum River
32
2,932
Mangyeong, Dongjin
33
3,023
Seomjin River
40
4,914
South of Seomjin River
41
3,385
Yeongsan River
50
3,470
Tamjin River
51
506
South of Yeongsan River
52
1,507
West of Yeongsan River
53
2,117
The locations of the 54 automated weather stations and the five major watersheds (Han River, Nakdong River, Geum River, Seomjin River, and Yeongsan River) of Korea.
54 weather stations in Korea
20 watersheds in Korea
2.2. GCMs and Downscaling
The four GCMs (i.e., CNRM-CM3, CSRIRO-MK3, CONS-ECHOG, and UKMO-HADCM) for the worst case climate change scenario from the IPCC GCM studies are described in Table 3.
Detailed information on the four GCMs used in this study.
Number
Model (agency-version)
Country
Spatial resolution
Atmospheric
Oceanic
1
CNRM-CM3
France
128×64
180×170
2
CSIRO-MK3
Australia
192×96
192×189
3
CONS-ECHOG
Germany/Korea
96×48
128×117
4
UKMO-HADCM
UK
96×73
288×144
GCMs have been used to reproduce historical climate models, understand climate mechanisms, and generate forecasts and projections of teleconnections and the interannual variability of sea surface temperature, among other things. GCMs have been claimed useful for long-term climate change projections [28, 29] as well as for short-term seasonal forecasts [2, 30–33], though these are often used with some type of dynamical or statistical downscaling technique. GCM-based analysis is constrained by the understanding of atmospheric dynamics at scales greater than 2 degrees of longitude and latitude, and thus using downscaling models to reproduce the underlying physics could elicit better analyses at finer spatial and temporal scales [34]. Specifically, the daily precipitation data have significant variability, are distinctively non-Gaussian, exhibit relatively complicated spatiotemporal dependence [35], and cannot be easily derived from atmospheric dynamic equations [34]. To solve these limitations, there are two primary approaches to downscale climate model outputs: statistical downscaling and dynamic downscaling using a regional climate model (RCM). It is not technically feasible to operate dynamic downscaling at the required spatial and temporal resolution, from multiple models due to computational load. In addition, it has been acknowledged that precipitation simulations from RCMs are still biased due to limited understanding of regional climate process. Therefore, statistical postprocesses associated with bias correction are generally needed before being used for climate impact assessment [36–42]. This inherent complexity has led to the development of statistical downscaling models to relate climate variables to synoptic atmospheric patterns (e.g., [32, 33, 35]). The downscaling of these GCM simulations to a regional scale is generally employed for hydrological climate impact studies and results in bias corrected information on local-scale climate change (e.g., [36, 43–46]). In this study, a hybrid spatiotemporal downscaling based on a transfer function and a weather generator was applied. One may expect a direct use of the bias corrected monthly precipitation without the temporal downscaling, but the projections of change to rainfall extremes may be still underestimated. Therefore, this study used the monthly precipitation data aggregated from the downscaled daily precipitation time series to better assess the changes in drought risk.
For the spatial bias correction of the GCMs to the 54 weather stations, the transfer function method based on the Cyclostationary Empirical Orthogonal Function (CSEOF) [47] and a multiple linear regression method were employed, and the statistical relationships were calculated between large-area and site-specific surface climates (e.g., precipitation and temperature). It has been acknowledged that the CSEOF analysis provides significant advantages over EOFs (empirical orthogonal functions) when dealing with signals such as modulated annual cycles and ENSO signals [48]. In other words, the CSEOF represents the complete spatiotemporal evolution of prominent climate signals (e.g., seasonal cycle, prominent intraseasonal oscillation, and ENSO-related evolution) over a cyclic period [48]. For the temporal downscaling, a weather generator (WXGEN) [49–51] was used to downscale monthly precipitation to daily precipitation. The WXGEN developed by Richardson [52] incorporates a first-order Markovian process for rainfall occurrences in the simulation process and utilized a skewed normal distribution for simulation of rainfall amounts. Among many stochastic weather generators, the WXGEN is a more comprehensive package which allows simultaneous generation of daily precipitation, maximum temperature, minimum temperature, relative humidity, and wind velocity, among other factors, based on the statistics of the observed climate variables [53]. The WXGEN embedded in SWAT [54] has been widely used in several studies to generate missing weather data [55–57] and climate change scenarios [58–60]. The WXGEN is based on a first-order Markov chain model to simulate daily precipitation occurrences, and the precipitation amount is then generated by a non-Gaussian distribution such as gamma distribution. The parameters in the WXGEN include monthly frequency of wet and dry day sequences, statistical moments (i.e., mean, standard deviation, and skewness) of monthly precipitation, daily air temperature, and daily solar radiation. The WXGEN uses a multivariate stochastic model to simulate maximum and minimum temperature and solar radiation. The time series is first normalized by monthly means and standard deviation. The anomaly series can be written as follows:(1)Xi,jk=αXi,j-1k+βωi,jk,where Xi,j(k) is a k×1 matrix for day j of year i whose elements are the anomalies of maximum temperature (k=1), minimum temperature (k=2), and solar radiation (k=3). ωi,j(k) is a k×1 matrix for normally distributed random variables with a mean of zero and a variance of unity, and α and β are k×k matrices whose elements are defined so that the observed cross-correlations are reproduced. Here, the daily values of the weather variables are simulated by multiplying the anomalies by the monthly standard deviation and then adding the monthly mean [61]. For details please refer to previous publications [49–51, 55–60]. Again, note that the subsequent analyses are based on monthly precipitation data aggregated from the downscaled daily precipitation time series.
2.3. Standardized Precipitation Index
In this study, we used an SPI to assess the spatial and temporal characteristics of future drought and specifically aimed to assess the potential meteorological drought risk rather than the hydrological drought risk in consideration of the ability to supply water and to better highlight needs specific to facilities for supplying water sources. McKee et al. [62, 63] developed the standardized precipitation index (SPI) for the purpose of defining and monitoring precipitation deficits on multiple timescales. The SPI is a simple index calculated from a long-term record (at least 30 years) of precipitation for individual weather stations. The data is first fitted to a two-parameter gamma distribution and normalized to a flexible multiple time scale. The shape and scale parameters of the gamma distribution are estimated for each station, for each timescale of interest (1,2,3,…months), and for each month of the year. The SPI is well suited for risk management and can provide early warnings of drought risk and severity because it is able to explicitly specify this information for each geophysical location.
To calculate the SPI, gamma distribution needs to be transformed to the standard normal random variable, with mean zero and variance one, which is the value of the SPI. Thom [64] found that the gamma distribution is well suited to fit monthly precipitation time series. The gamma probability density function using the shape-scale parametrization is(2)fx=1βαΓαxα-1e-x/β,for x>0,where α>0 is a shape factor, β>0 is a scale factor, and x>0 is the amount of precipitation. Γ(α)>0 is the gamma function, which is defined as(3)Γα=∫0∞xα-1e-xdx.Fitting the gamma distribution to the data requires estimating parameters and this study used a maximum likelihood method suggested by Thom [64]:(4)α^=14A1+1+4A3β^=x-α^A=lnx--∑lnxn,where n is number of precipitation observations.
The resulting parameters are then used to determine the cumulative probability of an observed precipitation event for the given month and time scale:(5)Fx=1β^α^Γα^∫0xxα^-1e-x/β^.Substituting t for x/β^, the equation becomes an incomplete gamma function. Since the gamma function is not defined for x=0 and a precipitation distribution may have many zeros, the cumulative probability density function can be written as follows:(6)Dx=p+1-pFx,where p is the probability of zero precipitation, and the probability p is simply estimated by a ratio of the number of zeros in the time series over the total number of data [65], and the cumulative probability D(x) is estimated by using the incomplete gamma. The cumulative probability, D(x), is then projected to the standard Gaussian distribution so as to transform the probability of the gamma distribution into normal random variable Z with mean zero and variance one, which is the value of the SPI. This can be regarded as an equiprobability mapping approach allowing us to retain the essential statistical properties of transforming a variate from the gamma distribution to a variate with the standard normal distribution [66], as illustrated in Figure 2. In other words, the precipitation is first transformed to uniformly distributed values (0,1) through the fitted gamma CDF, and these uniform values are then transformed to normally distributed data by using the inverse of the normal cumulative distribution function. The standardized anomaly is finally calculated with results having an average of zero and a standard deviation of one, and the transformation was implemented in Matlab. A dashed red line and solid blue line in the left side of Figure 2 indicate the cumulative probability of the fitted gamma distribution and the empirical cumulative density function of the accumulated three-month precipitation for Seoul station for the period 1976–2010, respectively. The dashed red line in the right hand side of Figure 2 denotes the cumulative probability of the standard normal random variable Z (or SPI value) using the same cumulative probability scale of the fitted gamma distribution on the left hand side of the figure. In this study, this transformation procedure was used to transform a given three-month precipitation to SPI value.
An example of (equiprobability) transformation of the three-month precipitation for Seoul from cumulative probability of fitted gamma cumulative distribution into normal random variable Z (SPI) with mean zero and variance one.
McKee et al. [62] proposed classifying the SPI into extreme, severe, and moderate states for both wet and dry condition as shown in Table 4. This classification has been adopted by KMA (Korea meteorological agency) that makes use of the SPI officially to define the severity and the frequency of the precipitation deficit. For this study, we used a three-month SPI, which is calculated on a monthly basis for a moving window of three months, where the rainfall is summed over the window for each month.
A classification of the SPI that classifies the SPI into extreme, severe, and moderate classes for both wet and dry moisture condition.
SPI value
Drought class
More than +2.00
Extremely wet
+1.50 to +1.99
Very wet
+1.00 to +1.49
Moderately wet
+0.99 to −0.99
Near normal
−1.00 to −1.49
Moderately dry
−1.50 to −1.99
Severely dry
Less than −2.00
Extremely dry
3. Methods
In this study, the WT and the MK test are used to determine possible changes in drought series and to further examine the relationship between drought and climate change. A brief description of the above-mentioned methodology is provided in the following section.
3.1. Mann-Kendall Trend Test
In this study, the MK test is used in place of a parametric linear regression model to analyze significant changes in drought patterns. The purpose of the Mann-Kendall (MK) test [67–69] is to statistically assess if there is a monotonic trend of the variable of interest over time. The monotonic trend indicates that the variable consistently increases (or decreases) over time, but the trend may be linear or nonlinear. The residuals from the linear regression model assume being normally distributed while the assumption is not required by the MK test. In other words, the MK test is a nonparametric (distribution-free) test. This rank-based test is ideal for the nonnormality of hydrological variables (e.g., precipitation and discharge). If the test statistic is significantly different from zero, the null hypothesis (H0) of no monotonic trend is rejected and accepts the alternative hypothesis (Ha) of monotonic trend and vice versa [70]. The MK test is conducted as follows. First, determine the sign of all (n-1)/2 possible differences xj-xi, where j>i. Second, compute MK statistic S as follows:(7)S=∑i=1n-1∑j=i+1nsignxj-xi,where xj are the sequential data values, n is the total number of data points in the set, and sign(x), an indicator function, is defined as(8)signx=1,if xj-xi>00,if xj-xi=0-1,if xj-xi<0.If S is a positive value, observations obtained later in time tend to be larger than observations made earlier and vice versa. When n is greater than 8, the statistic S is approximately normally distributed with mean E(S)=0. Third, compute the variance of MK statistic S as follows: (9)VarS=nn-12n+518.Fourth, standardized MK statistic ZMK is finally calculated as follows:(10)ZMK=S-1VarS,if S>00,if S=0S+1VarS,if S<0.If ZMK>Z1-α/2, null hypothesis (H0) is rejected and a statistically significant trend exists in the time series. The critical value of Z1-α/2 for a p value of 0.05 and 0.1 from the standard normal distribution is 1.96 and 1.645, respectively.
3.2. Wavelet Transform Analysis
A change in the variance of a distribution will have a larger effect on the frequency of extremes than a change in the mean [71, 72]. WT-based time series analysis is employed to investigate changes in the variability of a distribution and to identify both the temporal and spatial aspects of droughts. WT methods have been widely applied to geophysical time series analysis for the past ten years [73]. We summarize the WT analysis as presented by Torrence and Compo [26]. The term wavelets refers to sets of functions of the form φb,a(t)=a-0.5φ((t-b)/a), that is, sets of functions formed by the dilation and translation of a single function, φ(t), known as the mother wavelet. The continuous WT of a real time series x(t) is defined by [74](11)Xb,a=a-1/2∫-∞+∞xtφ∗t-badt,where X(b,a) is the wavelet spectrum, φ(t) is the wavelet function, (∗) denotes the complex conjugate, b is the translation (shift) parameter, and a≠0 is the scale parameter.
By localizing the wavelet function at t-b=0 and computing the coefficients X(b,a), it is possible to examine the behavior of x(t) near t=b. A variety of wavelet functions have been proposed [26, 75]. In this study, the Morlet wavelet was used, which is defined as φ(t)=π-1/4eiω0te-t2/2, where ω0 is the frequency. The Morlet wavelet is a good choice, since it provides a good balance between time and frequency localization [27]. In order to estimate the continuous wavelet transform, an N times convolution of the function shown in (11) is conducted for each scale, where N is the number of points in the time series [76]. Numerically, we were able to estimate wavelet power spectrum in Fourier space, at a given N points, using a discrete Fourier transform (xn) as [26]. In other words, by choosing N points, the convolution theorem allows us to do all N convolutions simultaneously in Fourier space so that it is much faster to do the estimations. The discrete Fourier transform of xn can be written as(12)x^j=1N∑n=0N-1xnexp-πijnN,where j=0,…,N-1 is the frequency index.
In a continuous limit, the Fourier transform of a function φ(t/a) is given by φ^(aω). According to the convolution theorem, the wavelet transform is the inverse Fourier transform of the product:(13)Xna=∑j=0N-1x^jφ^∗aωjexpiωjnδt.Information for the wavelet power spectrum can be interpreted at each time and scale. A time-integrated variance of the energy coefficients at every scale is introduced to determine the global wavelet power [26]: (14)Xn¯2a=1N∑n=0N-1Xna2.Another way to interpret information in the wavelet power spectrum at each time and scale is scale integrated variance of energy coefficients over time to compute the scale averaged wavelet power (SAWP) as(15)X-n2t=δjδtCδ∑j=j1j2Xnaj2aj.Cδ is reconstruction coefficient and is a constant for each wavelet function. j1 and j2 are scales over which the averaging takes place. δj and δt are the scale averaging coefficient and sampling period, respectively.
Wavelet transform can reconstruct the original time series using either deconvolution or the inverse filter because it is a bandpass filter with a known wavelet function. The reconstructed time series can be estimated by the sum of the real part of the wavelet transform over all scales:(16)xn=δjδt1/2Cδψ00∑j=0JRXnajaj1/2.The factor ψ0(0) removes the energy scaling, while aj1/2 converts the wavelet transform to an energy density. δj and δt are the scale averaging coefficient and sampling period. The factor Cδ is a constant (e.g., 0.776 for Morlet wavelet) and comes from the reconstruction of δ function from its wavelet transform using the wavelet function ψ0(η) (e.g., π-1/4 for Morlet wavelet).
4. Results4.1. Evaluation of the Downscaled Climate Change Scenario
The scientific concern about impact assessments on hydrologic studies under climate change is uncertainty associated with greenhouse gas concentration projection. Even selecting the relevant greenhouse gas emission scenario may be an issue for future projection, and this could generate various uncertainties [77]. There are four sources of uncertainties in the climate change study. The first issue is the uncertainty associated with the selection of climate change scenario. The second issue is the limited capability of the GCM in terms of reproducing a future climate model based on the selected emission scenario. The third is the results from biases from the statistical downscaling approach. In addition, the bias from the model output must be considered as a limitation of CGMs. Some errors are related to the projection of future hydroclimatic extremes using GCMs [46]. This study used multiple GCMs, which were less biased, to better characterize the uncertainties in investigating the variability of drought under climate change.
First, we try to assure ourselves that the simulated precipitation from the GCMs has similar statistical characteristics to the observed precipitation. In this respect, statistical properties of the simulated data were compared with that of the observed from the Seoul weather station during the historical period. The annual highest precipitation, the annual average precipitation, and the annual lowest precipitation are also compared. The performance of WXGEN was evaluated based on comparison with observed data. For example, statistical hypothesis tests (i.e., t-test and F-test) were used to determine if mean and variance of the observed and simulated data are significantly different from each other, respectively [78]. It can be seen that the simulated data are significantly close to the observed values, with a 0.05% significance level.
The results showed that the simulated annual average precipitation and annual lowest precipitation from the four GCMs are quite similar to the observed ones, while the annual highest precipitation is rather underestimated, suggesting that the simulated future precipitation could lead to a bias around 20~40 mm for analysis of drought variability. However, the bias is relatively small compared to the annual precipitation (about 1250 mm) such that the effects of bias are rather limited in this study. The underestimation may be due to the underestimation of typhoon-driven extreme rainfalls in the simulation process of the GCMs [79]. Some differences in the simulation of precipitation across the GCMs are identified and these may be because of different climate dynamics, grid resolutions, and physical and parameterization processes [44]. In addition, the seasonal cycle of the GCM is analyzed in terms of the behavior of the monthly periods for five major watersheds. The precipitation climatology is analyzed and compared to observed data during the baseline period (1976–2010) shown in Figure 3. Because of space limitations, we show only the results for Han River and Nakdong River watershed. As displayed in Figure 3, the estimated seasonal cycle is almost identical to the observed one, with small differences in the summer season. Student’s t-test and F-test were also employed to estimate the significant difference of mean and variance; the annual cycle was significantly close to the observed values, with a 0.05% significance level.
A comparison of the climatological annual cycle between the observed and the simulated data in watersheds of two major rivers for the baseline period (1976–2010).
Han River
Nakdong River
4.2. Spatial Distribution of Trend in Drought
The MK statistics were estimated to identify long-term drought trends at each station. The aforementioned drought index used in this study is the three-month SPI based on observed and GCM precipitation. The entire analysis period spans 1976–2099 with the first 37 years (historical: 1976–2010) and the remaining period (2011–2099) were forced by the representative concentration pathway scenarios (e.g., RCP 8.5). Four GCMs were downscaled over the South Korean Peninsula domain by a statistical downscaling model. The monthly SPI was rearranged to analyze seasonal drought trends, classified as spring (March–May), summer (June–August), autumn (September–November), and winter (December–February). Temporal trends of the SPI are tested at the α = 0.05 and α = 0.10 significance level and these trends are then spatially interpolated by using the Thiessen method to better represent spatial distributions of the trends. The spatial distributions of temporal trend in SPI are shown in Figure 4. Note that the positive trend of the SPI times series indicates the wetting (i.e., upward), meaning that occurrence of drought is likely to be less frequent while the negative trend indicates the drying (i.e., downward) trend.
Results of drought trend analysis for each season using the Mann-Kendall test (confidence level ≥ 95%).
Spring
Summer
Autumn
Winter
The observed historical SPI shows significant drying trends in all the watersheds during spring and most parts of the lower watershed during winter. In summer, there are no significant drying trends in the upper and lower watersheds (+0.010~0.027/year), except for a significant drying trend in a small part of the middle watersheds (≤−0.02/year). In fall, the SPI shows significant wetting trends in most parts of the watersheds, which indicates a predominant increase of precipitation over the South Korean Peninsula. These wetting trends may be related to changes in timing of monthly rainfall where the monthly peak times of most parts of Korea continuously moved backward from early July to early August in recent periods [13, 14]. In particular, the winter and spring droughts can lead to extreme dry conditions in spring that bring about serious problems during the agricultural planting in South Korea. With regard to this, it would be important to investigate changes in drought conditions in the dry season under climate change.
The simulated temporal evolution of SPI-3 over South Korea reveals a wide spread in the GCMs (Figure 4). In spring, CSIRO-MK3 and UKMO-HADCM show significant drying trends in all watersheds. These patterns are similar to that of the observed historical SPI. On the other hand, CNRM-CM3 and CONS-ECHOG indicate wetting trends in all watersheds at a 10% significance level. In winter, three GCMs showed significant drying trends in most parts of the watersheds, which will likely result in severe spring droughts. In summer, there are no significant drying trends in most parts of the watersheds, and only CONS:ECOHG showed a significant drying trend. Given the simulated results, the area affected by droughts is likely to increase through the 21st century during the dry season (e.g., spring and winter) which may exacerbate vulnerability to water resources management in South Korea.
4.3. Multiscale Analysis of Drought
A main question in this session is to understand how the low-frequency patterns associated with drought may change in the future under climate change. This question is explored by comparing the global wavelet power (GWP) for the time series. First, we applied the WT to the SPI derived from downscaled monthly precipitation that is spatially averaged for the four GCM data sets for the past period, 1976–2010 (labeled S0), and for three future periods, 2011 to 2040 (labeled S1), 2041 to 2070 (S2), and 2071 to 2100 (S3). Figures 5-6 show the GWP, in which the x-axis indicates the cycle (year) and the y-axis indicates the wavelet power spectrum. All of the analyses employed the Morlet wavelet and zero padding, and a 95% confidence limit for the wavelet amplitude corresponding to a null hypothesis of red noise is also illustrated in each of the figures [26]. One generally needs to choose an appropriate background spectrum in order to determine significance levels for wavelet spectra. It has been acknowledged that an appropriate background spectrum for geophysical phenomena is red noise characterized by increasing power with decreasing frequency. If a peak in the wavelet power spectrum is above this background spectrum, then it can be assumed to be a true frequency with a certain percent confidence [26]. Note that the GWP of the SPI for the S0 base scenario is a modeling output derived from the GCMs and not from the observed data. Here, the S0 period in the figure is represented by a red line comprised of circles, the S1 period by a green line, the S2 period by a cyan line, and the S3 period by a pink line of triangles.
A comparison of global wavelet spectra for the Han River watershed (S0: 1976~2010, S1: 2011–2040, S2: 2041–2070, and S3: 2071–2099). The dashed blue line is the significance for the global wavelet spectrum, assuming the same significance level and background spectrum as in wavelet power spectra. All analyses employed the Morlet wavelet.
A comparison of global wavelet spectra for the Geum River watershed (S0: 1976~2010, S1: 2011–2040, S2: 2041–2070, and S3: 2071–2099). The dashed blue line is the significance for the global wavelet spectrum, assuming the same significance level and background spectrum as in wavelet power spectra. All analyses employed the Morlet wavelet.
In the case of the Han River watershed, the spectra during S1, S2, and S3 decrease in fractional variance attributed to a reduction in the interannual band from 2 years to 8 years in the CSIRO-MK3, UKMO-HADCM, and CNRM-CM3. The only plausible frequency from 30-year data is about 10 years, given the length of record that is one-third of the time series, so it is not clear that one should directly attach significance to these differences and model them. A strong spectrum is identified around 20 years in CNRM-CM3, CSIRO-MK3, and UKMO-HADCM, which may be related to trends in the SPI series. Given the results of spectrum analysis, interannual variability associated with precipitation will likely decrease. The reduction in the interannual variation can lead to reduction in the long memory and increase in the randomness of the climate system, and this may reduce the usefulness of teleconnection based forecasting systems.
Note that we did not include the results for the Nakdong River watershed because the spectrum structure is almost identical to that of the Han River watershed (not shown in this study). Likewise, the results for the Seomjin River watershed and the Yeongsan River watershed are not included. Instead, the results for the Geum River watershed are only shown as a representative watershed. In the case of the Geum River watershed, significant peaks with a period of 4–8 years are evident in the global power spectrum for the S0 period, indicating the presence of an interannual variation throughout the last several years. As similarly noted in the Han River watershed, the spectra during S1, S2, and S3 decrease in variance in the interannual band from 2 to 8 years in CNRM-CM3, UKMO-HADCM, and CONS-ECHOG. Again, a strong spectrum is identified around 20 years in most of the GCMs, except for CONS-ECHOG, which may be related to trends. It seems that interannual variability associated with the droughts will likely decrease as indicated in the Han River watershed.
4.4. Frequencies and Severity of Drought
We examined the spatial distribution of the severity and frequency in the dry stages (with −1.5 ≤ SPI) in the major river basins. These analyses are conducted through a dry spell analysis that aims to analyze the changes in the frequencies of occurrence and the severity of drought. The dry spell analysis assists in understanding the likelihood of intraseasonal droughts [80]. The analysis period was comprised of two parts: the first, from 1976 to 2010, representing past droughts; the second from 2011 to 2099, speculating on future droughts. Figure 7 shows the spatial distribution of the frequency in severe dry stages with three-month SPI less than −1.5. Note that the SPI series used here is calculated from a downscaled monthly precipitation that is derived from the hybrid spatiotemporal downscaling model using the four GCMs as inputs. The drought spell analysis using the observed data revealed that the frequency of severe drought was high in the Nakdong River watershed (7.30%), Seomjin River watershed (7.65%), and Yeongsan River watershed (7.43%), which are located in the southern part of the Korean Peninsula. Overall, the severe drought frequency for the future shows a tendency to decrease with time under climate change. In other words, future projection, which averaged the four GCM models, showed that the frequency of severe drought was less than that observed in the past, with 10.68% (Han River), 26.66% (Nakdong River), 28.81% (Geum River), 38.12% (Seomjin River), and 40.97% (Yeongsan River), respectively.
The spatial distribution of the frequency in severe dry stages with three-month SPI less than or equal to −1.5 for past and future climate change projections. (a) Observed frequency of severe drought for the period 1976–2010 and (b–f) projected frequency of severe drought by each GCM and MME average for the period 2011–2099 for the climate change scenario. Note that the SPI series is calculated from a downscaled monthly precipitation using the four GCMs as inputs.
Observed
CNRM:CM3
CSIRO:MK3
CONS:ECHOG
UKMO:HADCM
MME average
Changes in the frequency of severe drought with the four GCMs compared to historical drought data are summarized in Table 5. Among the four GCMs, the CNRM:CM3 showed the lowest frequency of severe drought, while the frequency of the CONS:ECHOG was the highest. In particular, the drought frequency in the Han River basin with the CONS:ECHOG showed 7.26% for future projections, which is higher than past estimates. The overall frequency of severe drought in the Nakdong River basin was observed to decrease with the four GCMs; however, an increase in the frequency of severe drought in some parts of the Nakdong River basin was identified.
Changes in the frequency in severe dry stages with three-month SPI less than −1.5 for past and future climate change projections. Observed frequency of severe drought for the period 1976–2010 and projected change in frequency of severe drought by each GCM and MME average for the period 2011–2099 for the climate change scenario. Difference is a percentage change in drought frequency between past and future periods, and positive value indicates increasing trend and vice versa. Note that the SPI series is calculated from a downscaled monthly precipitation using the four GCMs as inputs.
Name
ID
Observed
CNRM
CSIRO
ECHOG
HADCM
MME
Diff (%)
Han River
10
6.00
4.13
4.93
7.26
5.38
5.42
−10.68
Anseong Stream
11
6.10
3.99
4.90
7.35
5.54
5.44
−12.14
West of Han River
12
6.04
4.00
4.60
7.68
5.67
5.48
−10.18
East of Han River
13
6.17
4.71
5.52
6.00
5.71
5.48
−12.49
Nakdong River
20
7.30
4.56
6.02
6.36
6.12
5.76
−26.66
East of Nakdong River
24
6.10
5.18
6.15
6.13
5.82
5.82
−4.85
South of Nakdong River
25
6.34
4.67
6.99
6.66
6.68
6.25
−1.39
Hyeongsan River
21
6.82
5.20
6.50
6.50
5.99
6.05
−12.75
Taehwa River
22
6.69
5.51
7.38
6.89
6.23
6.50
−2.97
Hoeya, Sooyeong
23
6.52
5.46
7.24
6.94
6.32
6.49
−0.52
Geum River
30
7.19
4.35
5.45
6.81
5.72
5.58
−28.81
Sapgyo Stream
31
6.41
4.33
4.95
6.89
5.59
5.44
−17.87
West of Geum River
32
6.18
4.38
4.79
6.81
5.47
5.36
−15.19
Mangyeong, Dongjin
33
7.33
4.37
5.42
6.44
5.99
5.55
−31.98
Seomjin River
40
7.65
4.16
5.38
6.27
6.35
5.54
−38.12
South of Seomjin River
41
6.86
4.01
5.65
6.21
6.58
5.61
−22.21
Yeongsan River
50
7.43
3.92
4.83
6.03
6.31
5.27
−40.97
Tamjin River
51
6.02
3.75
4.88
5.99
6.40
5.26
−14.59
South of Yeongsan River
52
6.78
3.93
4.96
5.91
6.19
5.25
−29.16
West of Yeongsan River
53
7.04
3.97
5.04
6.09
6.32
5.36
−31.51
This study evaluated the impact of climate change on drought severity in the region of South Korea. First, the average drought severity analysis, based on the observed SPI, showed that the severity was relatively higher in the Nakdong River watershed, Seomjin River watershed, and Yeongsan River watershed, in which the frequency of severe drought was higher than for other watersheds. Moreover, it was found that the average severity less than −2.0 was shown in the river basin located in the eastern part of Nakdong River (e.g., Hyeongsan River −2.01, Taehwa River −2.03, and Hoeya/Sooyeong −2.01) and in the southern part of Yeongsan River (−2.01), as summarized in Table 6.
Changes in the severity of drought in severe dry stages with three-month SPI less than −1.5 for past and future climate change projections. Observed severity of drought for the period 1976–2010 and projected change in severity of drought by each GCM and MME average for the period 2011–2099 for the climate change scenario. Difference is a percentage change in severity of drought between past and future periods, and positive value indicates increasing trend and vice versa. Note that the SPI series is calculated from a downscaled monthly precipitation using the four GCMs as inputs.
Name
ID
Observed
CNRM
CSIRO
ECHOG
HADCM
MME
Diff (%)
Han River
10
−1.91
−2.08
−2.00
−2.19
−1.98
−2.06
8.09
Anseong Stream
11
−1.92
−2.09
−2.01
−2.21
−1.95
−2.07
7.75
West of Han River
12
−1.89
−2.11
−2.02
−2.20
−1.98
−2.08
9.84
East of Han River
13
−1.87
−2.11
−1.99
−2.14
−2.03
−2.07
10.63
Nakdong River
20
−1.98
−2.04
−1.98
−2.22
−2.09
−2.08
5.27
East of Nakdong River
24
−1.96
−2.09
−1.95
−2.15
−2.15
−2.09
6.40
South of Nakdong River
25
−1.98
−2.06
−1.99
−2.19
−2.09
−2.08
5.07
Hyeongsan River
21
−2.01
−2.08
−1.96
−2.18
−2.16
−2.10
4.30
Taehwa River
22
−2.03
−2.08
−1.95
−2.16
−2.18
−2.09
3.22
Hoeya/Sooyeong
23
−2.01
−2.08
−1.97
−2.18
−2.17
−2.10
4.38
Geum River
30
−1.90
−1.98
−1.97
−2.24
−2.00
−2.05
7.85
Sapgyo Stream
31
−1.90
−2.05
−2.02
−2.22
−1.95
−2.06
8.56
West of Geum River
32
−1.90
−2.05
−2.03
−2.23
−1.96
−2.07
9.06
Mangyeong, Dongjin
33
−1.93
−1.96
−1.95
−2.28
−1.99
−2.04
6.14
Seomjin River
40
−1.95
−1.93
−1.98
−2.22
−2.03
−2.04
4.91
South of Seomjin River
41
−1.95
−2.00
−2.00
−2.16
−2.06
−2.05
5.11
Yeongsan River
50
−1.97
−1.92
−1.98
−2.20
−2.00
−2.03
3.01
Tamjin River
51
−1.99
−1.98
−2.01
−2.15
−2.05
−2.05
3.07
South of Yeongsan River
52
−2.01
−1.98
−2.00
−2.15
−2.04
−2.04
1.79
West of Yeongsan River
53
−1.99
−1.95
−1.97
−2.21
−1.99
−2.03
2.13
Second, this study investigated the spatial pattern of the average severity in the severe dry stages estimated from three-month SPI less than or equal to −1.5, as shown in Figure 8. The average future drought severity less than −2.0 will likely happen in most of the basins under climate change scenarios informed by GCMs, and overall features of the severe drought for the future show a tendency to increase with time under climate change, leading to higher risk in terms of intensified droughts in the Han River basin (8.09%), Nakdong River basin (5.27%), Geum River basin (7.85%), Seomjin River basin (4.91%), and Yeongsan River basin (3.01%). The aforementioned Nakdong River basin was an area vulnerable to drought in the past in terms of the frequency and severity of droughts, and these features are likely to be affected by future droughts.
The spatial distribution of the severity of drought with three-month SPI less than or equal to −1.5 for past and future climate change projections. (a) Observed severity of drought for the period 1976–2010 and (b–f) projected severity of drought by each GCM and MME average for the period 2011–2099 for the climate change scenario. Note that the SPI series is calculated from a downscaled monthly precipitation using the four GCMs as inputs.
Observed
CNRM:CM3
CSIRO:MK3
CONS:ECHOG
UKMO:HADCM
MME average
5. Conclusions
Climate change is expected to change the hydrological pattern, frequency, and intensity of droughts, leading to a higher number of drought-related disasters, hence the importance of developing a strategy for better assessing the impact of climate change on extremes associated with drought. This effort will allow us to respond proactively by providing policy analysis and advice to policymakers. In this regard, the main objectives of this study were to evaluate the changes in spatial distribution of droughts in terms of frequency and severity under climate change, using IPCC GCM simulations in the five major watersheds, Korea. Here, we utilized a Mann-Kendall (MK) trend test and a wavelet transform analysis for the evaluation of the possible changes in drought projections. This study’s major contribution is the proposal of a drought pattern analysis to coupling low-frequency issue. An application to the five major watersheds in Korea was illustrated to show how climate change can lead to change in droughts. The following main conclusions are drawn.
The simulated annual average precipitation and annual lowest precipitation from four GCMs of 1976–2010, equivalent to a baseline period, are quite similar to observed ones. The generated monthly mean and variance of precipitation were significantly close to the observed values, through Student’s t-test and F-test with a 0.05% significance level. However, some discrepancies in the precipitation during the summer season were identified and these may be due to the exclusion of typhoon-driven extreme events in the simulation process of the GCMs. The temperature was consistently projected to increase under future climate change scenario according four GCMs over South Korea. It was shown that dry season rainfall (e.g., spring and winter) will decline while rainy season rainfall (e.g., summer and fall) will incline over next century. This indicates that change in the seasonality is likely to be enhanced in South Korea under warming climate.
The Mann-Kendall method was adopted to identify drought trends at the five major watersheds. The observed historical SPI showed significant drying trends (i.e., negative trends) in all the watersheds during spring and most parts of the lower watershed during winter. In fall, the SPI showed significant wetting trends (i.e., positive trends) in most parts of the watersheds, and these wetting trends may be related to changes in timing of monthly rainfall, with monthly peak times of most parts of Korea continuously moved backward from early July to early August in recent periods. The simulated temporal evolution of SPI during the winter showed significant drying trends in most parts of the watersheds, while the simulated SPI during the spring showed a somewhat different feature in the GCMs. Given the simulated results, overall, a spring drought is likely to be intensified under climate change, and the area affected by the spring drought is likely to increase through the 21st century which may lead to extreme dry conditions during the agricultural planting in South Korea.
This study explored the low-frequency patterns associated with drought by comparing global wavelet power for the time series, with significance test. Significant peaks with a period of 2–8 years are evident in the global power spectrum in most of the watersheds, indicating the presence of the interannual variation throughout the last several years. Future spectra decreased in the fractional variance attributed to a reduction in the interannual band from 2 to 8 years. The reduction in the interannual variation can lead to reduction in the long memory and increase in the randomness of the climate system, and this may reduce the usefulness of teleconnection based forecasting systems. The results are consistent with others indicating that the randomness in the climate system will increase under a warmer climate [81–83].
Finally, the changes in the frequency and the severity under climate change were evaluated through the drought spell analyses. The results showed that the projected SPI was found to decrease in frequency for mild and moderate drought cases over time. However, in cases of severe droughts less than −2.0, the frequency was found to increase slightly over time in most of the watersheds under climate change. Overall features of drought conditions in the future showed a tendency to decrease in frequency and increase in severity with time under climate change, leading to higher risk in terms of intensified damage of drought.
This study investigated potential changes in the characteristics of drought using multimodel simulations. Readers should be aware of some issues regarding the uncertainty and assumptions of models. Indeed, the uncertainty of scenarios used herein is an essential influence on the projected changes in drought. Despite using cutting-edge climate simulations of IPCC climate model, it is still unable to reproduce historical extremes (droughts and floods) associated with natural climate variability. The importance of climate model resolution to improving reproduction of climate dynamics over a large area in East Asia has been reported (e.g., [84, 85]). Hence, dynamical downscaling system using regional climate models (RCMs) would be useful for reliable climate change studies in South Korea. However, a high resolution regional climate model ensemble system for South Korea is not available. If RCM ensemble simulation is utilized, the uncertainties in extreme climate projection are expected to be reduced. Our ongoing research focuses on using the RCM to better understand future drought for water resources management.
Competing Interests
The authors declare that they have no competing interests.
Acknowledgments
This research was supported by a Grant (15AWMP-B079625-02) from Water Management Research Program funded by Ministry of Land, Infrastructure and Transport of Korean government.
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