Safe Groundwater Level Estimation in Pingtung Plain, Taiwan
1
Department of Civil Engineering, National Pingtung University of Science and Technology, Pingtung 91201, Taiwan
2
Disaster Prevention and Mitigation Technology Research Center, National Pingtung University of Science and Technology, Pingtung 91201, Taiwan
*
Author to whom correspondence should be addressed.
Water 2023, 15(16), 2947; https://doi.org/10.3390/w15162947
Submission received: 25 July 2023
/
Revised: 12 August 2023
/
Accepted: 14 August 2023
/
Published: 15 August 2023
(This article belongs to the Special Issue Research on Soil Moisture and Irrigation)
Abstract
:The groundwater resources in the Pingtung Plain are crucial water sources in southern Taiwan. However, they have been significantly impacted by climate change, resulting in changes in groundwater quality and quantity in the region. To effectively manage groundwater extraction, this study utilized runs theory to analyze the safe groundwater levels at six groundwater level observation stations located in the proximal fan, mid fan, and distal fan areas of the Pingtung Plain. The methodology involved dividing the range between the maximum and minimum groundwater levels at each station into 20 equal intervals. The groundwater levels were then sorted in ascending order, and the cumulative frequency percentiles of groundwater levels in each interval were calculated to determine the truncation levels for runs theory. Subsequently, the groundwater over-extraction duration and severity were computed. By comparing the results with the groundwater management levels set by the Water Resources Agency of the Ministry of Economic Affairs, it was found that the safe groundwater levels in the proximal fan and distal fan areas were the average of observation data plus 0.5 times the standard deviation. The over-withdrawn duration for these areas was approximately 8 to 10 months and 8 months, respectively. In the mid fan area, the safe groundwater level was based on the average of observation data, and the over-withdrawn duration ranged from 6 to 9 months.
1. Introduction
The balance between the development, utilization, and conservation of groundwater resources is a crucial issue for the sustainable use of groundwater. However, due to the high uncertainty associated with groundwater extraction and recharge rates, it is essential to establish standards for the allowable groundwater withdrawal to prevent groundwater overexploitation and its associated hazards. These standards serve as the basis for groundwater management in different regions. Various factors influence the allowable groundwater withdrawal in different areas, such as groundwater recharge capacity, water rights, water quality, economic considerations, and social factors. Therefore, the establishment of these standards needs to take into account the specific characteristics and conditions of each region. By considering these factors, a more balanced and sustainable management approach can be adopted to ensure the long-term availability and viability of groundwater resources.
There are several methods for establishing groundwater management standards, such as safe yield, optimal yield, sustainable yield, and standardized groundwater index assessment. Safe yield refers to the amount of groundwater that can be extracted from an aquifer without causing adverse effects on the aquifer itself [1,2,3,4,5,6,7]. It has been widely used by hydrogeologists as a management method to regulate groundwater extraction [4,8,9]. Despite its widespread use in groundwater resource assessment, the concept of safe yield remains controversial. To address this, the concept of optimal yield has been proposed from an optimization perspective [10]. The optimal yield is determined by selecting the best groundwater management option from a set of possible alternatives, considering social, economic, and water resource use evaluations. Zhou [11] clarified the dispute over safe yield and explored the concepts of safe yield and sustainable yield using water balance equations. Chen et al. [12] used Darcy’s law and established optimization linear models with limited data to assess the optimal safe yield of groundwater, integrating grey theory to evaluate parameter uncertainty. Seward et al. [13] focus on the concept of “capture” rather than “recharge” as a measure of sustainable groundwater use. Capture refers to the total of the increase in recharge introduced by pumping and the decrease in recharge caused by pumping. Sustainable groundwater use depends on the additional pumping volume and is compensated through capture, which can be acceptable to stakeholders. However, uncertainty exists in factors such as pumping time, pumping volume, pumping locations, aquifer heterogeneity, and recharge, making it challenging to precisely determine groundwater balance. Consequently, using pumping volume as a basis for groundwater management can be difficult. Groundwater levels, on the other hand, can be directly and accurately measured. Therefore, groundwater level variations can be utilized as a method for groundwater resource management, such as standardized groundwater index assessment, groundwater level exceedance probabilities, and runs theory.
Runs theory has been applied in several studies to analyze droughts. Yevjevich [14] proposed three attractive parameters to define droughts, including the duration of a drought, the severity of a drought, and the area run as the deficit of water over a specific time duration and area of drought. Saldariaga and Yevjevich [15] used run theory and time series to predict drought occurrences. Sen [16,17] introduced methods to calculate run lengths and run sum for annual hydrological data. Moye et al. [18] developed a relevant probability distribution based on difference equations. This distribution enables hydrologists to estimate the expected number of droughts of a specified duration and the average drought length over a desired time period. Moye and Kapadia [19] used run theory to predict events based on order statistics. Sen [20] presented a general method to determine the exact probability distribution function of the longest drought duration in a finite sample of any process based on runs theory and enumeration techniques. Saghafian et al. [21] determined the severity, magnitude, and duration of drought periods on a monthly and longer time basis using a dimensionless Z-score and run theory. Karamouz et al. [22] developed an algorithm to study drought characteristics, such as duration and severity, for a region. They generated a large sequence of synthetic data to develop the probability density function of drought characteristics for planning and water allocation purposes. Peters et al. [23] indicated that hydrologic droughts include both streamflow and groundwater drought characteristics. Severity–duration–frequency (SDF) curves are very useful in the analysis of drought phenomena. Station-level information obtained from SDF curves can be interpolated to obtain severity maps for fixed return periods, enabling the joint analysis of the spatial variability of drought characteristics (e.g., severity, duration, and frequency) [24,25].
The Pingtung Plain is an important aquifer in southern Taiwan and a key region for agricultural development. Surface water supply in the Pingtung area accounts for only 20% of the total water demand, with groundwater being the primary water source for various water users [26]. Due to the lack of effective management of groundwater extraction and the fact that groundwater pumping areas are often not recharge areas, excessive pumping during the dry season can easily lead to groundwater over-withdrawal, resulting in land subsidence and seawater intrusion in coastal areas of the Pingtung Plain [27,28,29,30,31]. Despite monitoring and management efforts by the government, the actual total volume of groundwater extraction remains unknown. Therefore, sustainable utilization of surface water and groundwater resources has become a critical mission in agricultural water use in the past decade [31]. In recent years, extreme climate events have significantly impacted the groundwater quality and quantity in the Pingtung Plain. Consequently, innovative scientific analyses are needed for groundwater management to develop better water management strategies. Chang et al. [32], based on long-term groundwater level data from the Pingtung Plain, used Principal Component Analysis (PCA) and Self-Organizing Map (SOM) regression analysis to assess the fundamental characteristics of the groundwater system. The analysis results suggested that groundwater management plans should take into account the zonal differences of the groundwater system to achieve groundwater protection goals.
This study is based on groundwater level observation data and utilizes the runs theory, a drought analysis method, to analyze the safe groundwater levels in the proximal fan area, mid fan area, and distal fan area of the Pingtung Plain. Additionally, the study aims to analyze the occurrence cycles of groundwater over-extraction in these areas.
2. Overview of the Study Area
2.1. Topography and Hydrology
The Pingtung Plain is one of Taiwan’s important groundwater resource areas, located in the southwestern part of Taiwan (as shown in Figure 1). It stretches approximately 60 km from north to south and 20 km from east to west, with an elevation below 100 m. The northern boundary abuts the Alishan Mountain Range, while its western border connects with the Liukuo and Fengshan Hills. To the south lies the Taiwan Strait, and its eastern boundary is demarcated by the Chaozhou Fault, meeting the southern end of the Central Mountain Range’s Dawu Mountain Range. The terrain gently slopes from the northeast to the southwest. The total area encompasses roughly 1130 square kilometers. The main rivers in the plain are the Gaoping Creek, Donggang Creek, and Linbian Creek. The Gaoping Creek flows from north to south, traversing the plain and flowing into the Taiwan Strait. Its tributaries, Qishan Creek and Laonong Creek, are characterized by abundant rainfall and serve as important recharge areas for the groundwater in the Pingtung Plain.
The climate in the Pingtung Plain is subtropical, with abundant rainfall but uneven distribution. It experiences distinct wet and dry seasons, with the period from May to October being the wet season when rainfall accounts for over 90% of the total annual precipitation and streamflow accounts for over 91% of the annual total. Rainfall decreases towards the coastal area, with the minimum precipitation near the mouth of the rivers, and increases with higher elevation. Due to its lower latitude, the Pingtung Plain experiences high temperatures, strong sunlight, and high evaporation rates. The annual evaporation ranges from 1000 to 2000 mm. In winter, the monthly evaporation exceeds the precipitation, while in summer, the opposite occurs. Figure 2 shows the distribution of monthly average rainfall and evaporation measured at the Pingtung station from 1990 to 2022. The temperature in the region is influenced by elevation and latitude, with the annual average temperature ranging from 20 to 25 degrees Celsius, and little variation in the monthly average temperature.
2.2. Geological and Hydrogeological Setting
The geological structure of the Pingtung Plain groundwater region is illustrated in Figure 3. The predominant rock formation in this area is the Miocene–Pliocene shale formation, which is distributed in four river basins: the Laonong Creek, the Ailaion Creek, the Linbian Creek, and the Lili Creek, situated on the eastern side. The bedrock of the Pingtung Plain consists of Miocene and Pliocene rock formations, progressively deepening from the northeast to the southwest. The overlying formations include the Pleistocene gravel and the modern alluvium layers. The northeastern part mainly consists of continental gravel, transitioning to predominantly marine siltstone and sandstone toward the southwest. The Gaoping River basin covers an area of 3273 km2. The upper reaches of the Qishan Creek originate from the Yushan Mountain Range and traverse mainly Miocene to Pliocene sandstone, shale, and mudstone. The Laonong Creek originates from the Central Mountain Range. Its upper reaches flow through Eocene to Oligocene shale, tuff, and metamorphosed sandstone. The middle reaches pass through Miocene hard shale, shale, tuff, and metamorphosed sandstone. The Ailaion Creek originates from the Central Mountain Range as well, flowing through Eocene to Oligocene shale, tuff, and metamorphosed sandstone. In the upper reaches of the Wanan Creek and Taiwu Creek, tributaries of the Donggang Creek originate from the hard shale, tuff, and metamorphosed sandstone zone on the eastern side of the Chaozhou Fault in the Central Mountain Range. Similarly, in the upper reaches of the Laichi Creek and Lili Creek, tributaries of the Linbian Creek originate from the same zone on the eastern side of the Chaozhou Fault in the Central Mountain Range [33].
The deposition of eroded materials from the upland areas is transported by rivers and then accumulates through specific mechanisms at the foot of the mountains and in the plain regions. This process can be easily identified based on the existing terrain, water systems, and surface rock distribution. As river water flows out of narrow mountain outlets into flat terrain, its velocity suddenly decreases, causing the deposition of coarse particles like gravel and coarse sand at the fan heads and riverbeds. Due to the possibility of river channel shifting, gravel and sand are distributed extensively, constituting the most important aquifers. Figure 4 shows a geological cross-section from the upper region to the lower southwest direction of the Pingtung Plain. From this figure, it is evident that the main rock types in the upstream area of the Gaoping Creek are sandstone and shale on the western side of the Laonong Creek and Qishan Creek. The sediments eroded from the upland areas mainly consist of sand and silt, with fewer pebbles. Because pebbles and coarse sand particles are larger, they tend to accumulate in the alluvial fan heads and braided river channels, forming highly permeable aquifers [33].
3. Methodology
3.1. Data Characteristics Analysis
The Pingtung Plain has 61 self-recording and stratified groundwater level observation stations [34], which were installed between 1995 and 1998. Over the past 30 years, Taiwan has undergone social development, leading to changes in land use patterns. The area of rice paddies has gradually decreased, while dry fields and aquaculture areas have increased. Consequently, the patterns of groundwater usage have also changed accordingly.
The present study collected monthly average groundwater level data from six shallow monitoring wells located in the Pingtung Plain, including the Xinwei, Gaoshu, Ligang, Jiuru, Wandan, and Donggang stations. The locations of each station and the historical groundwater level profiles are shown in Figure 1 and Figure 5, respectively. Among them, the Xinwei, Gaoshu, and Ligang stations are located in the proximal fan area, while the Jiuru and Wandan stations are in the mid fan area, and the Donggang station is in the distal fan area.
The Xinwei station is situated upstream of the Laolong Creek, with a wellhead elevation of 152.023 m, making it the highest-located observation station. The Gao-Shu station is positioned between the Laolong Creek and the Ailiao Creek, mainly dedicated to rice and fruit tree cultivation. The Ligang station is adjacent to the Laolong Creek and serves as an important aquaculture area in Pingtung County, with groundwater being the main water source for aquaculture. The Jiuru and Wandan stations are located upstream and midstream of the Gaoping Creek, respectively. The area is primarily involved in paddy rice, upland crop, and fruit tree cultivation, with groundwater being the primary irrigation source. The Donggang station is situated downstream of the Donggang Creek and falls within an area of seawater intrusion and land subsidence, resulting in its groundwater use being regulated.
Based on the collected groundwater level data, various historical water level characteristics of each observation station were statistically analyzed, as shown in Table 1. The data include the wellhead elevation, groundwater level observation time, average water level, highest and lowest water levels, and the standard deviation of the water level. Additionally, the groundwater management levels set by the Water Resources Agency for each station are provided in Table 1 [35].
3.2. Safe Groundwater Level Analysis
This study defines the groundwater level as the safe level when it is at a certain water level reference and relative time duration reference. When the groundwater level exceeds this water level reference, it is considered to be in a state of groundwater over-withdrawal. If the time duration of groundwater over-withdrawal exceeds the time duration reference, the groundwater system is considered to be in a potentially hazardous stage. Therefore, the determination of the safe groundwater level depends on the groundwater level and its relative time duration. In this study, the runs theory is used to establish the safe groundwater level in the Pingtung Plain. The runs theory is an objective tool for analyzing droughts [15], and it uses the truncation level to divide the selected variables into two states (as shown in Figure 6). In this study, the truncation level is defined as the reference for the safe groundwater level. In the figure, the symbol “Qi” represents the cumulative sum of groundwater overdrafts that occurred at each overdraft duration “Li”. Thus, for the study of the safe groundwater level, the range below the truncation level is considered as negative runs, representing the time duration of groundwater over-withdrawal. The area enclosed by the truncation level and the variable curve in the negative runs region represents the cumulative total of groundwater over-withdrawal. In determining the safe groundwater level, five factors are considered: the truncation level, over-withdrawal time duration, cumulative total of over-withdrawal, severity, and over-withdrawal period. These factors are used to assess the risk of hydrogeological disasters relative to groundwater levels falling below the safe level.
The determination of the truncation level varies depending on the geological conditions and the characteristics of groundwater extraction and recharge at different observation sites. In this study, the observed groundwater levels between the maximum and minimum values are divided into 20 equal intervals. The observed groundwater levels are sorted from the smallest to the largest, and the frequency of occurrence and percentage frequency are calculated for each interval. Then, the cumulative frequency percentiles for each interval are calculated. The groundwater levels corresponding to the 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, and 90% cumulative frequency percentiles are taken as the truncation levels.
The determination of the over-withdrawn duration is obtained from the groundwater level hydrograph in relation to the truncation level, which provides the time duration of each over-drawdown event. The over-withdrawn duration criterion is defined based on the ease of groundwater recharge and the time period for recharge. In this study, the period of high water availability, such as the wet season, is used as the over-withdrawn duration criterion. The over-withdrawn volume is defined as the area enclosed by the groundwater level hydrograph and the truncation level. Severity (M) is calculated by dividing the over-withdrawn volume (S) by the super-drawdown duration (D), i.e., M = S/D. The over-withdrawn period represents the average time interval between occurrences of groundwater over-withdrawn events, as determined by the safe withdrawal intervals.
The determination of safe groundwater levels depends on the geological conditions and the conditions of groundwater extraction and recharge at each observation station. In the proximal fan area and distal fan area, the safe groundwater levels are set as the mean of the observation data plus 0.5 times the standard deviation. In the mid fan area, the safe groundwater level is set as the mean of the observation data.
4. Analysis Results and Discussion
Based on the statistical data from Table 1, it can be observed that among the six observation stations, the groundwater level variability is highest at the Gaoshu station and lowest at the Donggang station. Additionally, the groundwater management levels set by the Water Resources Agency (WRA) are higher than the average groundwater levels at all stations. Analyzing the long-term groundwater level trends from Figure 5, in this figure, the blue line represents the linear regression trend of groundwater level observation data. Trend analysis indicates that among the six observation stations, only the groundwater level at Gaoshu station shows a decreasing trend, while the other five stations exhibit an upward trend over the long term. This information indicates that the groundwater conditions in the study area vary significantly among the observation stations. The Gaoshu station experiences the highest fluctuation in groundwater levels, while the Donggang station remains relatively stable. The WRA’s management strategy of maintaining groundwater levels above average levels could be a proactive measure to prevent excessive groundwater overdraft and potential adverse effects on the aquifer system.
Based on the data collected from various groundwater observation stations, the cumulative frequency percentile corresponding to groundwater levels was used as a truncation level for the analysis of groundwater overdraft using the runs theory, as shown in Figure 7. From this figure, it can be observed that the average frequency of groundwater overdraft is highest at the Xinwei station in the proximal fan area and at the Donggang station in the distal fan area. Additionally, the Donggang station exhibits the highest standard deviation in groundwater overdraft frequency, indicating that groundwater level variations in the distal fan area are influenced significantly by both extraction and recharge processes. On the other hand, the soil texture in the proximal fan area is characterized by good permeability, making it an easily rechargeable zone. As a result, the groundwater levels in this area exhibit lower variability. Furthermore, the analysis of groundwater overdraft frequency based on different cumulative frequency percentiles reveals that the 50% percentile has the highest frequency of groundwater overdraft events, while the 10% percentile has the fewest occurrences.
The analysis of the runs theory provides the cumulative total of groundwater over-withdrawn and the corresponding over-withdrawn duration at various percentiles for each observation well. By calculating the severity of groundwater over-withdrawal at different cumulative percentiles, as shown in Figure 8, it is evident that the highest severity of groundwater over-withdrawal occurs at the Gaoshu observation well, especially at the 80th percentile. This indicates that the groundwater over-withdrawal at Gaoshu station is most severe and occurs frequently, posing potential risks to the aquifer in that area. On the other hand, the Donggang station shows the lowest severity of groundwater over-withdrawal. This is expected, since this station is located in a groundwater extraction regulated area, where measures are implemented to control groundwater extraction and prevent excessive over-withdrawal. Moreover, across all the cumulative percentiles, the 80th percentile demonstrates the highest severity of groundwater over-withdrawal, while the 10th percentile exhibits the lowest severity. This suggests that the more extreme and intense over-withdrawal events are more likely to occur at higher cumulative percentiles, which underscores the importance of sustainable groundwater management practices to mitigate the adverse impacts of groundwater over-extraction. Overall, the analysis using the runs theory provides valuable insights into the severity and frequency of groundwater over-withdrawal at different observation wells, guiding better management strategies to ensure the sustainable use of groundwater resources in the Pingtung Plain.
From the data collected at each groundwater observation well, the over-withdrawn duration, cumulative over-withdrawn sum, and severity of over-withdrawal at various cumulative percentiles can be determined based on the corresponding groundwater levels at each percentile. The distribution of over-withdrawn duration at different percentiles can be obtained, and the average over-withdrawn duration and its standard deviation are calculated as shown in Table 2. According to Table 2, it can be observed that as the groundwater levels at the percentile-based segmentation decrease, the management of groundwater becomes more relaxed, but it also increases the risk of groundwater over-withdrawal. Smaller average over-withdrawn durations are associated with smaller standard deviations in over-withdrawn duration. Conversely, as the groundwater levels at the percentile-based segmentation increase, the average over-withdrawn duration also increases, indicating more stringent management of groundwater extraction and potentially higher management costs. At the Jiuru station, the average over-withdrawn duration is the highest at the 70th percentile, as shown in Figure 7, which indicates that this station experiences the least frequent groundwater over-withdrawal events. However, it also exhibits the highest variation in over-withdrawn duration, suggesting a more unpredictable pattern of groundwater extraction in this area.
Based on the regression analysis using the groundwater levels at different percentiles and the average over-withdrawn duration from Table 2, the coefficient of determination was used to determine the best-fitting equation for each observation well. The regression equations for each observation well are presented in Table 3. It is evident that the regression equations for Xinwei, Wandan, and Donggang stations follow a quadratic polynomial form, while the equations for Gaoshu and Ligang stations exhibit a power function. On the other hand, the regression equation for Jiuru station takes the form of an exponential function.
These diverse regression equations indicate that the relationship between groundwater levels and average over-withdrawn duration varies across different observation wells. Understanding these relationships can assist in formulating specific groundwater management strategies tailored to each site’s characteristics, ensuring sustainable groundwater use in the Pingtung Plain. Based on the determination of the safe groundwater levels using the average and standard deviation data from Table 1, the approach of adding 0.5 times the standard deviation to the average groundwater level was applied for the proximal and distal fan areas, while the average groundwater level was used for the mid fan area. By substituting the safe groundwater levels and the management groundwater levels into the regression equations from Table 3, the calculated over-withdrawn duration periods are presented in Table 4. From Table 4, it can be observed that the safe groundwater levels for Xinwei, Gaoshu, and Ligang stations in the proximal fan area are 140.0, 64.0, and 31.0 m, respectively. For the mid fan area, Jiuru and Wandan stations have safe groundwater levels of 24 and 10 m, respectively. In the distal fan area, the safe groundwater level for Donggang station is 0.4 m. The over-withdrawn duration periods for the proximal fan area, mid fan area, and distal fan area are 8 to 10 months, 6 to 9 months, and 8 months, respectively. These results provide valuable information for groundwater management and sustainable use in different areas of the Pingtung Plain.
5. Conclusions
This study utilized runs theory to analyze the safe groundwater levels and overdraft duration periods of six groundwater observation stations in the Pingtung Plain. The analysis revealed that, in the long term, only the groundwater level at Gaoshu station showed a declining trend, while the other five stations exhibited rising trends. Additionally, Gaoshu station had the highest variability in groundwater levels. The occurrence of groundwater overdraft varied, with the highest frequency at the 50% cumulative frequency percentile and the lowest at the 10% percentile. The determined safe groundwater levels for the proximal fan area were 140.0, 64.0, and 31.0 m for Xinwei, Gaoshu, and Ligang stations, respectively. In the mid fan area, the safe groundwater levels were 24 and 10 m for Jiuru and Wandan stations, respectively. For the distal fan area, the safe groundwater level at Donggang station was 0.4 m. The over-withdrawn duration periods for the proximal fan area, mid fan area, and distal fan area were 8 to 10 months, 6 to 9 months, and 8 months, respectively. These findings provide valuable insights into the groundwater management and sustainable use in different regions of the Pingtung Plain.
In future groundwater management in the Pingtung Plain, apart from analyzing the changes in observed groundwater levels, it is important to consider the potential impact of excessive pumping duration when groundwater levels fall below the safe threshold. Therefore, establishing a reasonable groundwater overdraft duration is crucial for the sustainable utilization and management of groundwater resources. It is suggested that in the future, discussions could be focused on how the changing rainfall distribution due to climate change might influence the safe groundwater levels and the management of overdraft duration in the Pingtung Plain.
Author Contributions
Conceptualization, Y.-L.Y. and Z.-M.C.; methodology, Y.-L.Y.; software, T.-P.C.; validation, Y.-L.Y. and Z.-M.C.; formal analysis, C.-Y.W.; data curation, C.-Y.W.; writing—original draft preparation, C.-Y.W.; writing—review and editing, Y.-L.Y. All authors have read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Data Availability Statement
The data presented in this study are available on request from the corresponding author.
Acknowledgments
We appreciate the editors and the reviewers for their constructive suggestions and insightful comments, which helped greatly to improve this manuscript.
Conflicts of Interest
The authors declare no conflict of interest.
References
- Lee, C.H. The determination of safe yield of underground reservoirs of the closed basin type. Trans. Am. Soc. Civ. Eng. 1915, 78, 148–218. [Google Scholar] [CrossRef]
- Meinzer, O.E. The Occurrence of Groundwater in the United States, with a Discussion of Principles; Water Supply Paper 489; US Geological Survey: Reston, VA, USA, 1923.
- Todd, D.K. Groundwater Hydrology; John Wiley & Sons: New York, NY, USA, 1959. [Google Scholar]
- Dottridge, J.; Jaber, N.A. Groundwater resources and quality in northeastern Jordan: Safe yield and sustainability. Appl. Geogr. 1999, 19, 313–323. [Google Scholar] [CrossRef]
- Heath, R.C.; Spruill, R.K. Cretaceous aquifers in North Carolina: Analysis of safe yield based on historical data. Hydrogeol. J. 2003, 11, 249–258. [Google Scholar] [CrossRef]
- Voudouris, K.S. Groundwater balance and safe yield of the coastal aquifer system in NEastern Korinthia, Greece. Appl. Geogr. 2006, 26, 291–311. [Google Scholar] [CrossRef]
- Kalf, F.R.P.; Donald, R.; Woolley, D.R. Applicability and methodology of determining sustainable yield in groundwater systems. Hydrogeol. J. 2005, 13, 295–312. [Google Scholar] [CrossRef]
- Sakiyan, J.; Yazicigil, H. Sustainable development and management of an aquifer system in western Turkey. Hydrogeol. J. 2004, 12, 66–80. [Google Scholar] [CrossRef]
- Rezaei, A.; Mohammadi, Z. Annual safe groundwater yield in a semiarid basin using combination of water balance equation and water table fluctuation. J. Afr. Earth Sci. 2017, 134, 241–248. [Google Scholar] [CrossRef]
- Domenico, P.A. Concepts and Models in Groundwater Hydrology; McGraw-Hill: New York, NY, USA, 1972. [Google Scholar]
- Zhou, Y. A critical review of groundwater budget myth, safe yield and sustainability. J. Hydrol. 2009, 370, 207–213. [Google Scholar] [CrossRef]
- Chen, H.W.; Ning, S.K.; Yu, R.F.; Chen, J.C. Optimal safe groundwater yield for land conservation in a seashore area under uncertainty. Resour. Conserv. Recycl. 2010, 54, 481–488. [Google Scholar] [CrossRef]
- Seward, P.; Xu, Y.; Brendonck, L. Sustainable groundwater use, the capture principle, and adaptive management. Water SA 2006, 32, 473–482. [Google Scholar] [CrossRef] [Green Version]
- Yevjevich, V. An Objective Approach to Definitions and Investigations of Continental Hydrologic Droughts; Hydrology Paper No. 23; Colorado State University: Fort Collins, CO, USA, 1967. [Google Scholar]
- Saldarriaga, J.; Yevjevich, V. Application of Run-Lengths to Hydrologic Series; Hydrology Paper No. 40; Colorado State University: Fort Collins, CO, USA, 1970. [Google Scholar]
- Sen, Z. Wet and dry periods of annual flow series. J. Hydrol. Div. ASCE 1976, 106, 99–115. [Google Scholar] [CrossRef]
- Sen, Z. Run-sums of annual flow series. J. Hydrol. 1977, 35, 311–324. [Google Scholar] [CrossRef]
- Moye, L.A.; Kapadia, A.S.; Cech, I.M.; Hardy, R.J. The theory of runs with applications to drought prediction. J. Hydrol. 1988, 103, 127–137. [Google Scholar] [CrossRef]
- Moye, L.A.; Kapadia, A.S. Predictions of drought length extreme order statistics using run theory. J. Hydrol. 1995, 169, 95–110. [Google Scholar] [CrossRef]
- Sen, Z. Critical drought analysis of periodic—Stochastic processes. J. Hydrol. 1980, 46, 251–263. [Google Scholar] [CrossRef]
- Saghafian, B.; Shokoohi, A.; Raziei, T. Drought spatial analysis and development of severity-duration-frequency curves for an arid region. In Proceedings of the International Conference on Hydrology of the Mediterranean and Semiarid Regions, Montpellier, France, 1–4 April 2003; IAHS Publication: Wallingford, UK, 2003; p. 278. [Google Scholar]
- Karamouz, M.; Torabi, S.; Araghinejad, S. Analysis of hydrologic and agricultural droughts in central part of Iran. J. Hydrol. Eng. 2004, 9, 402–414. [Google Scholar] [CrossRef]
- Peters, E.; Torfs, P.J.J.F.; van Lanen, H.A.J.; Bier, G. Propagation of drought through groundwater- a new approach using linear reservoir theory. Hydrol. Process. 2003, 17, 3023–3040. [Google Scholar] [CrossRef]
- Todisco, F.; Mannocchi, F.; Vergni, L. Severity-duration-frequency curves in the mitigation of drought impact: An agricultural case study. Nat. Hazards 2013, 65, 1863–1881. [Google Scholar] [CrossRef]
- Razmkhah, H. Preparing stream flow drought severity-duration-frequency curves using threshold level method. Arab. J. Geosci. 2016, 9, 513. [Google Scholar] [CrossRef]
- Hsu, K.C.; Wang, C.H.; Chen, K.C.; Chen, C.T.; Ma, K.W. Climate-induced hydrological impacts on the groundwater system of the Pingtung Plain. Taiwan. Hydrogeol. J. 2007, 15, 903–913. [Google Scholar] [CrossRef]
- Ting, C.S.; Zhou, Y.; de Vries, J.J.; Simmers, I. Development of a preliminary ground water flow model for water resources management in the Pingtung Plain, Taiwan. Ground Water 1998, 36, 20–36. [Google Scholar] [CrossRef]
- Shih, D.S.; Chen, C.J.; Li, M.H.; Jang, C.S.; Chang, C.M.; Liao, Y.Y. Statistical and numerical assessments of groundwater resource subject to excessive pumping: Case study in Southwest Taiwan. Water 2019, 11, 360. [Google Scholar] [CrossRef] [Green Version]
- Tran, D.H.; Wang, S.J. Land subsidence due to groundwater extraction and tectonic activity in Pingtung Plain, Taiwan. Proc. Int. Assoc. Hydrol. Sci. 2020, 382, 361–365. [Google Scholar] [CrossRef] [Green Version]
- Vu, T.D.; Ni, C.F.; Li, W.C.; Truong, M.H.; Hsu, S.H.M. Predictions of groundwater vulnerability and sustainability by an integrated index-overlay method and physical-based numerical model. J. Hydrol. 2021, 596, 126082. [Google Scholar] [CrossRef]
- Lin, K.P.; Chou, P.C.; Shih, D.S. To study hydrological variabilities by using surface and groundwater coupled model—A case study of PingTung Plain, Taiwan. Procedia Eng. 2016, 154, 1034–1042. [Google Scholar] [CrossRef] [Green Version]
- Chang, F.J.; Huang, C.W.; Cheng, S.T.; Chang, L.C. Conservation of groundwater from over-exploitation—Scientific analyses for groundwater resources management. Sci. Total Environ. 2017, 598, 828–838. [Google Scholar] [CrossRef]
- Ministry of Economic Affairs. Identification Plan of Geologically Sensitive Areas for Groundwater Recharge—G0002 Pingtung Plain; Ministry of Economic Affairs: Taipei, Taiwan, 2014. (In Chinese)
- Water Resources Agency, Ministry of Economic Affairs. Hydrological Year Book of Taiwan; Ministry of Economic Affairs: Taipei, Taiwan, 2022. (In Chinese)
- Water Resources Agency, Ministry of Economic Affairs. Establishment of an Evaluation System for Groundwater Resources as Supportive Water Supply Sources during the Drought Period in Taiwan; Ministry of Economic Affairs: Taipei, Taiwan, 2016. (In Chinese)
Figure 1.
Location of the Pingtung Plain and the groundwater observation wells.
Figure 2.
Average monthly rainfall and evaporation during 1990~2022 in Pingtung station.
Figure 3.
Regional geological map of groundwater area in Pingtung Plain [33].
Figure 3.
Regional geological map of groundwater area in Pingtung Plain [33].
Figure 4.
Geological profile from northeast to southwest in the upper reaches of the Pingtung Plain [33].
Figure 4.
Geological profile from northeast to southwest in the upper reaches of the Pingtung Plain [33].
Figure 5.
The groundwater level with time in the investigation sites.
Figure 6.
The sketch diagram of safe groundwater level using runs theory. (a) Truncation of given series ht at h0 level; (b) groundwater over-withdrawn duration sequence; (c) groundwater over-withdrawn sums sequence.
Figure 6.
The sketch diagram of safe groundwater level using runs theory. (a) Truncation of given series ht at h0 level; (b) groundwater over-withdrawn duration sequence; (c) groundwater over-withdrawn sums sequence.
Figure 7.
The number of groundwater over-withdrawn occurrences at various cumulative frequency percentiles of the truncation level.
Figure 7.
The number of groundwater over-withdrawn occurrences at various cumulative frequency percentiles of the truncation level.
Figure 8.
The severity of groundwater over-withdrawal at various cumulative frequency percentiles of the truncation level.
Figure 8.
The severity of groundwater over-withdrawal at various cumulative frequency percentiles of the truncation level.
Table 1.
Statistical analysis of groundwater level data at observation wells.
| Observation Station | Wellhead Elevation (m) | Mean (m) | Standard Deviation (m) | Maximum (m) | Minimum (m) | Observation Duration (month) | Management Groundwater Level (m) |
|---|---|---|---|---|---|---|---|
| Xinwei | 152.023 | 139.71 | 1.00 | 144.53 | 138.57 | 01/1999~12/2022 | 140.19 |
| Gaoshu | 86.733 | 59.82 | 7.06 | 74.20 | 44.82 | 01/1997~12/2022 | 65.03 |
| Ligang | 38.250 | 30.64 | 1.44 | 34.04 | 28.24 | 01/1996~12/2022 | 31.76 |
| Jiuru | 34.592 | 24.73 | 1.88 | 28.76 | 21.22 | 01/1997~12/2022 | 24.78 |
| Wandan | 16.884 | 10.00 | 1.08 | 12.92 | 7.44 | 01/1997~12/2022 | 10.37 |
| Donggang | 2.883 | 0.29 | 0.26 | 0.81 | −0.90 | 01/1997~12/2022 | 0.41 |
Table 2.
Truncation levels and average over-withdrawn duration corresponding to various cumulative frequency percentiles of groundwater levels.
Table 2.
Truncation levels and average over-withdrawn duration corresponding to various cumulative frequency percentiles of groundwater levels.
| Cumulative Frequency Percentile | Truncation Level (m) | Average Over-Withdrawn Duration (month) | Standard Deviation (month) | Truncation Level (m) | Average Over-Withdrawn Duration (month) | Standard Deviation (month) |
|---|---|---|---|---|---|---|
| Xinwei station | Jiuru station | |||||
| 10% | 138.93 | 2.28 | 2.16 | 22.02 | 3.32 | 1.58 |
| 20% | 139.02 | 2.31 | 2.48 | 22.81 | 6.74 | 1.47 |
| 30% | 139.10 | 3.50 | 2.88 | 23.57 | 7.06 | 5.77 |
| 40% | 139.19 | 4.71 | 3.07 | 24.20 | 8.26 | 8.00 |
| 50% | 139.46 | 5.79 | 3.53 | 24.63 | 10.44 | 10.39 |
| 60% | 139.65 | 8.30 | 5.26 | 25.35 | 18.79 | 29.14 |
| 70% | 139.81 | 7.73 | 6.97 | 26.24 | 72.36 | 122.96 |
| 80% | 140.13 | 9.04 | 6.59 | 26.71 | 27.67 | 70.21 |
| 90% | 140.91 | 12.95 | 11.19 | 27.10 | 35.09 | 76.03 |
| Gaoshu station | Wandan station | |||||
| 10% | 50.84 | 2.11 | 1.56 | 8.54 | 4.31 | 3.00 |
| 20% | 53.09 | 3.27 | 1.68 | 9.07 | 5.24 | 4.42 |
| 30% | 55.19 | 4.44 | 2.27 | 9.40 | 5.65 | 9.03 |
| 40% | 57.40 | 5.23 | 2.29 | 9.74 | 6.01 | 8.17 |
| 50% | 59.09 | 5.93 | 2.19 | 10.03 | 6.55 | 7.76 |
| 60% | 61.77 | 7.54 | 3.27 | 10.34 | 7.52 | 7.44 |
| 70% | 64.52 | 9.58 | 4.82 | 10.56 | 10.36 | 8.25 |
| 80% | 67.06 | 11.84 | 6.83 | 10.89 | 13.84 | 9.29 |
| 90% | 69.80 | 20.20 | 14.54 | 11.44 | 23.62 | 16.49 |
| Ligang station | Donggang station | |||||
| 10% | 28.68 | 2.91 | 1.45 | −0.07 | 2.91 | 1.63 |
| 20% | 29.08 | 5.47 | 1.92 | 0.11 | 3.79 | 2.72 |
| 30% | 29.64 | 7.29 | 3.19 | 0.22 | 4.57 | 3.71 |
| 40% | 30.24 | 10.16 | 8.82 | 0.29 | 5.30 | 4.32 |
| 50% | 30.61 | 11.45 | 15.05 | 0.34 | 6.09 | 5.15 |
| 60% | 31.07 | 17.76 | 31.98 | 0.37 | 6.20 | 5.02 |
| 70% | 31.55 | 15.00 | 27.78 | 0.42 | 8.32 | 5.29 |
| 80% | 32.05 | 16.15 | 29.73 | 0.49 | 11.05 | 12.50 |
| 90% | 32.54 | 29.24 | 44.57 | 0.57 | 16.62 | 13.68 |
Table 3.
Regression equation of segmentation level and average over-withdrawn duration of each observation station.
Table 3.
Regression equation of segmentation level and average over-withdrawn duration of each observation station.
| Observation Station | Regression Equation * | Safe Groundwater Level (m) | Over-Withdrawn Duration Period (month) |
|---|---|---|---|
| Xinwei | y = −1.1967x2 + 340.19x − 24,162 | 140.20 | 10.27 |
| Gaoshu | y = 4 × 10−11x6.2969 | 63.35 | 8.86 |
| Ligang | y = 2 × 10−22x15.327 | 31.36 | 17.24 |
| Jiuru | y = 5 × 10−5e0.5067x | 24.73 | 13.85 |
| Wandan | y = 3.6008x2 − 66.128x + 307.74 | 10.00 | 6.55 |
| Donggang | y = 51.589x2 − 7.0613x + 2.8402 | 0.42 | 8.92 |
Note: * x indicates the groundwater level of the truncation level, and y represents the duration period of over-withdrawal.
Table 4.
Comparison of over-withdrawn duration period between safe groundwater level and management groundwater level.
Table 4.
Comparison of over-withdrawn duration period between safe groundwater level and management groundwater level.
| Observation Station | Safe Groundwater Level (m) | Over-Withdrawn Duration Period (month) | Management Groundwater Level (m) | Over-Withdrawn Duration Period (month) | Relative Error of Groundwater Level (%) |
|---|---|---|---|---|---|
| Xinwei | 140.20 | 10.27 | 140.19 | 10.21 | 0.01 |
| Gaoshu | 63.35 | 8.86 | 65.03 | 10.45 | 2.58 |
| Ligang | 31.36 | 17.24 | 31.76 | 20.91 | 1.25 |
| Jiuru | 24.73 | 13.85 | 24.78 | 14.19 | 0.19 |
| Wandan | 10.00 | 6.55 | 10.37 | 9.21 | 3.55 |
| Donggang | 0.42 | 8.92 | 0.41 | 8.62 | 2.09 |
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content. |
© 2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Yeh, Y.-L.; Wu, C.-Y.; Chen, Z.-M.; Chiu, T.-P. Safe Groundwater Level Estimation in Pingtung Plain, Taiwan. Water 2023, 15, 2947. https://doi.org/10.3390/w15162947
AMA Style
Yeh Y-L, Wu C-Y, Chen Z-M, Chiu T-P. Safe Groundwater Level Estimation in Pingtung Plain, Taiwan. Water. 2023; 15(16):2947. https://doi.org/10.3390/w15162947
Chicago/Turabian StyleYeh, Yi-Lung, Ching-Yi Wu, Zhi-Mou Chen, and Teng-Pao Chiu. 2023. "Safe Groundwater Level Estimation in Pingtung Plain, Taiwan" Water 15, no. 16: 2947. https://doi.org/10.3390/w15162947
Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.
