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Article

Temporal Assessment of Phosphorus Speciation in a Model Ramsar Lake System in Asia

by
Anjali Venukumar
1,
Abdugani M. Azimov
2,
Gani M. Iztleuov
3,
Vishnu S. Moorchilot
1,
Usha K. Aravind
4,
Marat I. Sataev
2,
Valsamma J. Koshy
5 and
Charuvila T. Aravindakumar
1,5,*
1
School of Environmental Sciences, Mahatma Gandhi University (MGU), Kottayam 686560, Kerala, India
2
Research Laboratory Innovative Water Treatment Systems, M. Auezov South Kazakhstan University, Taukehan Street 5, 16000 Shymkent, Kazakhstan
3
Department of Ecology, M. Auezov South Kazakhstan University, Taukehan Street 5, 16000 Shymkent, Kazakhstan
4
School of Environmental Studies, Cochin University of Science & Technology (CUSAT), Kochi 682022, Kerala, India
5
Inter University Instrumentation Centre (IUIC), Mahatma Gandhi University (MGU), Kottayam 686560, Kerala, India
*
Author to whom correspondence should be addressed.
Hydrology 2024, 11(5), 70; https://doi.org/10.3390/hydrology11050070
Submission received: 17 March 2024 / Revised: 11 May 2024 / Accepted: 15 May 2024 / Published: 17 May 2024
(This article belongs to the Section Surface Waters and Groundwaters)

Abstract

:
This study focused on monitoring phosphorus (P) concentrations in the water of the Ramsar site, Lake Vembanad, with a special focus on the mouths of the river bodies draining into the lake, a known hotspot for eutrophication. Four phosphorus fractions—total reactive phosphorus (TRP), total acid hydrolysable phosphorus (TAHP), total organic phosphorus (TOP), and total phosphorus (TP)—were monitored during the pre-monsoon and post-monsoon seasons. The results revealed high levels of all monitored phosphorus fractions, with an average concentration exceeding 300 ppb P across both seasons, indicating a highly eutrophic state. Notably, TRP, TOP, and TP showed high concentrations in both the pre-monsoon and post-monsoon periods. These data suggest significant phosphorus input into the lake’s surface water, potentially triggering excessive algal growth and threatening the biodiversity of this rich wetland ecosystem.

1. Introduction

Wetlands represent vital ecosystems, where land and water converge to provide invaluable benefits to both humanity and wildlife [1,2]. Serving as natural filters, they enhance water quality by absorbing excess nutrients and pollutants, while also regulating water levels to mitigate floods and protect coastal areas from erosive forces [3]. Despite their critical role, wetlands face a mounting threat from human activities, leading to widespread degradation and loss [4].
One of the most pressing challenges to wetland health is eutrophication, a process driven by the accumulation of nutrients like phosphate and nitrate [5]. This nutrient overload disrupts the delicate balance of aquatic ecosystems, triggering harmful algal blooms, oxygen depletion, and biodiversity loss [6]. The root causes of eutrophication are manifold, including agricultural runoff, urban development, and untreated waste discharge, which have led to a surge in nutrient levels in rivers and lakes worldwide [7].
Of particular concern is the role of phosphorus, a key nutrient in freshwater environments, in fuelling eutrophication [8]. Even slight increases in phosphorus concentrations can have profound consequences, stimulating rapid plant and algae growth, reducing oxygen levels, and disrupting aquatic ecosystems. Phosphorus enters water bodies through various pathways, including fertilizers, manure, and industrial waste, exacerbating eutrophication in vulnerable ecosystems [9].
Understanding the complex dynamics of phosphorus cycling within aquatic systems is essential for assessing and managing eutrophication [10]. Phosphorus exists in multiple forms, including orthophosphate, inorganic phosphates, and organic phosphates, each with distinct transformations and interactions with water and sediment [11]. These processes, influenced by physicochemical and biological factors, govern the distribution and availability of phosphorus in aquatic environments [12,13].
Against this backdrop, the Lake Vembanad emerges as a critical case study, representing one of India’s largest and most ecologically significant wetland ecosystems [14]. Designated as a Ramsar Site for its rich biodiversity [15,16], the lake faces mounting pressures from human activities, including agricultural runoff and industrial pollution [17]. Numerous studies on the health of Vembanad Lake have been carried out over the years because of its ecological significance as a Ramsar site. The majority of the studies were limited to the northern Vembanad, where pollution is mostly caused by urbanization and industrialization [18,19]. The fractionation of phosphorus in the sediments of the northern Vembanad Lake has been the subject of several research projects [15,16]. A study in this region demonstrated that in the Cochin estuary (northern Vembanad Lake), surface sediments can serve as an internal supply of phosphorus [19]. However, there have not been many discussions on the phosphorus speciation in the water of the southern Vembanad Lake, which receives the majority of its runoff from agricultural lands.
In the southern area, agriculture practices, especially in low-lying fields, heavily rely on fertilizers, pesticides, and herbicides, contributing significantly to phosphorus loading [20,21]. This southern region has become a focal point for nutrient accumulation and the proliferation of invasive species. Additionally, the construction of the Thanneermukkom Bund (which divides the lake, with the southern portion dominated by freshwater and the northern portion by saltwater), designed to regulate the water exchange between the Arabian Sea and the freshwater habitats, exacerbates these issues by accumulating agricultural residues and promoting the rapid spread of harmful aquatic vegetation [22]. Such degradation poses significant threats to public health and environmental sustainability, underscoring the urgent need for comprehensive monitoring and management strategies.
Given this context, our focus was on specifically examining the influence of phosphorous loading from the four rivers that drain into the southern part of Vembanad Lake, which pass through vast agricultural fields. The confluence points of these rivers within the lake system serve as hotspots for phosphorous loading. This study has been carried out to understand the influx of phosphorus species into the lake system.
In summary, the health of Vembanad Lake can serve as a model for the broader challenges facing wetland ecosystems worldwide. This study aims to provide essential insights for the preservation and sustainable management of this natural resource by elucidating the intricate temporal dynamics of phosphorus species and its implications for eutrophication.

2. Materials and Methods

2.1. Study Area

The study area is situated in Kerala, located in the southwestern part of India, which is characterized by a network of 44 rivers, with 41 flowing westward and the remaining 3 flowing eastward. These westward-flowing rivers terminate either in a lake or merge with the sea on the western coast. Our research specifically delved into the phosphorous speciation in Vembanad Lake, a designated Ramsar site and the largest estuarine system in Kerala, covering approximately 256 km2 spanning latitudes 9°30′–10°20′ N and longitudes 76°13′–76°50′ E (Figure 1). The lake is renowned for its elongated axes running parallel to the sea coast and features two permanent openings, Azhikod and Cochin, facilitating direct connections to the Arabian Sea and contributing to its status as a highly productive estuary system [23].
Vembanad Lake receives nourishment from seven major rivers, five of which—Muvattupuzha, Meenachil, Manimala, Pamba, and Achankovil—originate from the south, while the remaining two—Periyar and Chalakudi—originate from the north of the Thanneermukkom Bund. Notably, Manimala, Achankovil, and Pamba flow into the lake’s southernmost part at Alappuzha, while Meenachil joins the eastern portion of the lake after passing through the Thannermukkom Bund. Collectively, these rivers contribute an estimated 297,010 m3 of fresh water annually [24], along with an annual sediment flow from catchments totaling around 329,106 tons [25]. Influenced predominantly by the monsoon, these rivers contribute approximately 71% of yearly precipitation [26].
Our research specifically focuses on the effects observed at the mouths of four rivers: Meenachil, Manimala, Pamba, and Achankovil. These rivers traverse through the agricultural lands of Kuttanad, resulting in extensive agricultural runoff that may be enriched with phosphorus content.

2.2. Sample Collection and Preservation

Water samples were collected from 16 distinct sampling points in the southern arm of Vembanad Lake over the period from March to December 2019, encompassing both the pre-monsoon and post-monsoon seasons. These samples were obtained from different rivers before their convergence with the lake system, with additional samples gathered from locations where rivers merge with the lake. Additionally, a representative sample of the entire lake was collected from the middle of the lake (Figure 1). Samples from the lake points were collected by reaching the sites by boat. At some points in the river, we used a boat to reach the sampling location, while at other points samples were obtained directly.
In order to ensure the accuracy of the analysis, surface water samples were collected using polypropylene containers that were thoroughly rinsed with river water prior to each sampling. The samples were then stored in PTFE bottles pre-cleaned with phosphate-free detergent and rinsed with double-distilled water [27]. Subsequently, the samples were transported to the laboratory in an ice box and preserved at 4 °C prior to analysis.

2.3. Sample Analysis

The collected water samples underwent comprehensive analysis for various physicochemical parameters, including temperature, pH, conductivity, total dissolved solids (TDS), total hardness (TH), salinity, dissolved oxygen (DO), and both anions and cations. Real-time measurements of temperature, pH, conductivity, TDS, salinity, and DO were conducted using the Aquaprobe AP 5000 plus. Total hardness was determined using the titration technique, while ion chromatography (Dionex ICS 1100 plus) was employed to analyze major ionic composition such as chloride (Cl), nitrate (NO3), sulphate (SO4), sodium (Na), potassium (K), magnesium (Mg), calcium (Ca), and ammonium (NH4). The identification of anions was performed using an AS12A/AG12A column with an ASRS suppressor, while major cations were analyzed using a CS12A/CG12A column and CSRS suppressor.
The phosphomolybdate blue colorimetric method, in combination with a UV–visible spectrophotometer, was utilized to quantify different phosphorus species [28]. Total reactive phosphorus (TRP) (unfiltered sample) was obtained from the non-digested water sample and total acid hydrolysable phosphorus (TAHP) (unfiltered) was obtained from the digested water sample. The difference between TRP and TAHP provided the TAHP concentration. Additionally, total phosphorus (TP) and total organic phosphorus (TOP) samples were digested for 2 h using potassium persulfate on a hotplate. TOP was calculated as the difference between TP and the sum of TAHP and TRP [29].

2.4. Data Analysis

In the data analysis phase, two main software tools were utilized: Microsoft Excel 2016 and IBM SPSS Statistics 22. These tools provided the necessary functionalities for conducting a comprehensive examination of the collected data.
Various statistical tests were employed to assess different aspects of the data. The Shapiro–Wilk test and Kolmogorov–Smirnov test were utilized to assess the normality of data distributions. These tests help to determine whether the data follow a normal distribution, which is essential for certain statistical analyses.
The Spearman correlation test was conducted to evaluate the relationships between different variables in the dataset. This non-parametric test assesses the strength and direction of monotonic relationships between variables, providing insights into potential associations among water quality metrics [30].
Additionally, a one-way ANOVA (Analysis of Variance) test was performed to compare the means across multiple groups. This test allowed for the examination of potential differences in water quality metrics among different sampling sites or seasons.
Principal component analysis (PCA) was employed to identify underlying patterns and extract relevant information from the dataset. PCA is a multivariate statistical technique used to reduce the dimensionality of data by transforming correlated variables into a smaller set of uncorrelated variables called principal components. By doing so, PCA helps uncover hidden elements influencing surface water quality and facilitates the interpretation of complex datasets [31].
Furthermore, hierarchical cluster analysis (HCA) was utilized to identify groups of similarity among sampling sites and/or water quality metrics. HCA is a technique used to classify objects or variables into homogeneous groups based on their similarities or dissimilarities. By clustering similar sampling sites or water quality metrics together, HCA provides valuable insights into the overall structure of the dataset and helps identify distinct patterns or trends [32].

3. Results and Discussions

3.1. pH, Water Temperature, Conductivity, TDS, Salinity, and Total Hardness

The physicochemical parameters of the surface water samples collected from Vembanad Lake and its adjoining rivers in the pre-monsoon (PRM) and post-monsoon (POM) seasons are presented in Figure 2 and Table 1. The pH values of the samples ranged between 5.1 to 7.8 and 5.3 to 7.2 in the PRM and POM seasons, respectively. However, there was no significant variation (p > 0.05) in the pH between the seasons. A significant difference in the water temperature (p < 0.05) between the seasons was noticed, with temperatures ranging between 28.5 to 32.2 °C and 26.8 to 30.8 °C in the PRM and POM seasons, respectively. Higher conductivity was recorded in the samples in the PRM (mean: 2128.75 μS/cm) than in the POM (mean: 669.45 μS/cm) season, with a significant variation (p < 0.05) in conductivity during these seasons. Furthermore, there was a significant deviation (p < 0.05) in the total dissolved solids (TDS) of samples between the seasons, whereas salinity did not vary significantly. The TDS in the water samples ranged from 41 to 3003 ppm and 32.2 to 1970 ppm in the PRM and POM seasons, respectively. The salinity varied from 20 to 2460 ppm and from 28.2 to 1420 ppm during the PRM and POM seasons, respectively, with a higher salinity in the samples recorded during the PRM season. The total hardness in the samples varied between 18.0 to 526.0 ppm in the PRM season and 16.0 to 252.0 ppm in the POM season. The hardness was higher in the PRM season (mean: 220.56 ppm) than in the POM season. Furthermore, a significant deviation in hardness levels was also noted between the seasons (p < 0.05).

3.2. Dissolved Oxygen (DO)

The mean dissolved oxygen (DO) concentration was recorded to be greater in the PRM season (6.45 ppm) than in the POM season (5.26 ppm) (Figure 2). Upon comparing both the PRM and POM seasons, it was noticed that the distributaries (S1–S5) of the Meenachil river had a relatively lower DO content, indicative of organic pollution in these locations [33]. The minimum DO concentration was recorded at S1 during both seasons (1.6 and 3.3 ppm in the PRM and POM seasons, respectively). S1 is a site in the river–lake interface point, where the excessive salinity load as a consequence of sea water mixing [34], along with domestic waste effluents, might have led to the reduction in DO content. Interestingly, very low DO levels were recorded at S11 (a site at the interface point of River Pamba and Lake Vembanad) during the POM season, which can be attributed to high organic waste disposal during the pilgrimage season (December to January) at Sabarimala. Previous reports have also correlated the high degree of contamination in the River Pampa with the pilgrimage season [35]. Similar drops in DO concentration were noted at S3, S5, and S7, including S1 and S11, during the POM season. These observations were mostly caused by the growth of aquatic weeds in the surface water at the time of sampling. During the sampling, aquatic plants like Eicchornia blocked the lake, which may have reduced the water’s ability to dissolve oxygen [23]. In the case of DO levels, ANOVA analysis revealed no significant (p < 0.05) seasonal variation among the sampling locations.
In general, higher pH, water temperature, conductivity, TDS, salinity, DO, and hardness levels were recorded in the PRM season. During the PRM season, the site S7 at the mouth of River Meenachil had the highest conductivity, TDS, salinity, and hardness values in the PRM season; this is where the primary channels of the River Meenachil drain into the lake. Meanwhile, Puthankayal (S12), another interface of the River Pamba with the Lake, exhibited the highest conductivity, TDS, salinity, and hardness levels in the POM season. Thus, these results clearly highlight the role of the river mouth points in controlling the water chemistry of the lake. Strong positive correlations were observed between the conductivity, total dissolved solids, salinity, total hardness, chloride, sulphate, sodium, magnesium, potassium, and calcium values. Additionally, a strong positive correlation was observed between the pH and DO. The temperature displayed a moderate positive correlation among chloride, sulphate, sodium, potassium, magnesium, and DO (Table 2).

3.3. Ionic Levels

In the pre-monsoon (PRM) season, notably high concentrations of sulphate and chloride were found in water samples collected from Vembanad Lake and its adjoining rivers (Figure 3). Specifically, sampling points S7 (located at the mouth of River Meenachil) and S8 (Manimala) exhibited the highest levels of both ions during the PRM season. Conversely, during the post-monsoon (POM) season, S12 (Puthankayal), S15 (chloride), and S6 (sulphate) recorded the highest values. The elevated chloride levels in the lower reaches of River Meenachil during the PRM season could be attributed to saline water intrusion, with [36] chloride contamination serving as an indicator of chloride-rich sewage effluent discharge. The decrease in ion concentration during the POM season could be due to dilution during the monsoon season. In contrast to other parameters, an elevated nitrate concentration in surface water was observed during the POM season, followed by the PRM season. Despite being low in both seasons, nitrate concentrations ranged between 0.24–2.11 ppm in the PRM season and 0.38–4.2 ppm in the POM season (Table 1). The presence of nitrate, although typically not detrimental to health, can lead to eutrophication and pose harm to aquatic systems [37]. The chloride, nitrate, and sulphate levels exhibited significant variation between the PRM and POM seasons. Additionally, a strong positive association between chloride and sulphate suggested a common source of origin (Table 2). However, there was no association between sulphate and chloride with nitrate levels, indicating a potentially different source for nitrate contribution.
In terms of cation analysis, concentrations of Na, Mg, K, and Ca peaked during the PRM season compared to the POM season (Figure 3). Although no significant difference was observed between ammonium and calcium levels, the maximum concentration of Na, Mg, Ca, and K during the PRM season was recorded at S1. These ions, particularly Na, showed higher concentrations near the lake–river interface, primarily due to saline water intrusion. Moreover, strong positive associations were observed between Na and various parameters, indicating a common source (Table 2). Notably, a significant seasonal variation (p < 0.05) in Na concentrations was noted.
Before reaching the Vembanad Lake, the neighboring rivers traverse around the Kuttanadu Padashekaram, where paddy cultivation occurs below sea level, a characteristic feature of this study area. Potassium (K), a key component of many artificial fertilizers, exhibited concentrations varying from 9.49 to 76.2 ppm during the PRM season and 0.81 to 27.71 ppm during the POM season. The annual fertilizer input of K into River Pamba is approximately 6207 tons/year [35]. K displayed significant positive correlations with various parameters, indicating a common source. Additionally, significant seasonal differences were observed for K (p < 0.05).
Significant variations were also observed for the Mg and Ca levels between the two seasons, with higher concentrations recorded during the PRM season. Mg ions exhibited a seasonal average value greater than Ca ions during the PRM season, while the opposite trend was observed during the POM season. In both seasons, the maximum concentrations for both ions were recorded at S1. The presence of a lime industry near a certain sampling station (S1) may contribute to the significant loading of Ca ions in both seasons. Strong positive correlations were observed for Mg and Ca with various parameters, indicating potential common sources.
Ammonium ions, recognized as good indicators of eutrophication, exhibited a concentration variation from 3.52 to 12.55 ppm during the PRM season and 0.04 to 12.52 ppm during the POM season (Figure 3). The maximum NH4 concentration in the PRM season was observed at S10, while S14 recorded the highest NH4 concentration in the POM season. River Pamba contributes dissolved inorganic nitrogen to Lake Vembanad, with chemical fertilizers and animal waste effluents potentially contributing to the nitric acid pollution of the water [35,38]. Negative correlations were observed between NH4 and conductivity, TDS, and salinity, with no significant variation in the NH4 concentration between seasons (Table 2).

3.4. Phosphorus Speciation in Surface Water

The concentration of total reactive phosphorus (TRP) ranged from 76.66 to 676.66 ppb during the Pre-Rainy Monsoon (PRM) and 110.0–476.66 ppb during the Post-Rainy Monsoon (POM). However, no significant temporal variation was observed across different seasons (Figure 4, Table 3). Elevated phosphorus levels in lakes typically occur in areas where there is a significant influx of sediments carrying human and animal waste fertilizers into water bodies [39]. Higher concentrations were recorded at S7 (Meenachil river mouth), where all the distributaries of River Meenachil drain into Lake Vembanad. The PO4 concentrations were high during the PRM season concerning the POM season. One factor that might have been involved in raising the phosphate levels is the reduced water level in the aquatic matrices leading to a concentration of ions. Other factors may involve the surge in microbial activity and the rise in phosphorus release from sediment at elevated temperatures [40]. Similar trends were observed in the phosphate content in the Cochin estuary, draining into Vembanad Lake [16], and River Sitalakhya (Bangladesh) [41]. Agriculture runoff carrying fertilizers containing phosphate that had been applied to the nearby paddy fields was mostly responsible for the phosphate content in the southern part of Vembanad Lake [23]. The yearly fertilizer use in the Kuttanad agrarian zone was 8409 tons of nitrogen, 5044 tons of phosphorus, and 6786 tons of potassium. Additionally, approximately 500 tons of pesticides/fungicides/weedicides were used annually [42]. The direct release of phosphate and nutrients from a variety of sources, including fertilizers containing the phosphorus used in the agriculture fields of Vembanad Lake and domestic sewage, was reported by Asha et al. [43]. A soluble reactive phosphate concentration of over 0.025 ppm is usually considered showing eutrophic conditions [44]. In this context, the level of PO4 in Vembanad Lake and its tributaries is high enough to support eutrophication. There was also a significant positive correlation observed between reactive phosphorus, Cl (r = 0.399), SO4 (r = 0.359), Na (r = 0.424), K (r = 0.375), Mg (r = 0.469), and hardness (r = 0.404) (Table 2).
The total acid hydrolysable phosphorus (TAHP) ranged from 100.0 to 1033.33 ppb and 243.33 to 1276.67 ppb in the PRM and POM seasons, respectively (Figure 4, Table 3). TAHP concentrations were maximum at S8 (River Manimala) and S6 (River Meenachil) during the PRM and POM seasons, respectively. TAHP levels did not show significant variation (p > 0.05) among the seasons. In general, TAHP concentrations were noticed to be higher in the POM season. During the POM season, millions of devotees perform rituals as a part of their belief in River Pampa. Bathing and laundry activities by the devotees could very well lead to the substantial influx of polyphosphate into the aquatic matrix. Phosphates are added to detergents as sodium tripolyphosphate (STPP), and in India, their composition levels in products vary from 8 to 35% [45]. STPP is an acid hydrolysable phosphorus that can quickly hydrolyse to orthophosphate in water. The River Manimala basin also receives significant amounts of inorganic phosphate and other ions through effluents’ discharge from commercial centers and restaurants [46].
The concentration of the total organic phosphorus (TOP) ranged from 33.33 to 1243.34 ppb in the PRM season and 23.33 to 890.0 ppb in the POM season (Figure 4, Table 3). TOP recorded the maximum concentration at S3 in the PRM season and S5 in the POM season. Both are river mouths of River Meenachil. These stations are at the downstream portion of the river, which carries significant quantities of organic/inorganic wastes. Previous records have also highlighted the effects of anthropogenic influences on the River Meenachil [47,48,49]. Only a few reports are focused on organic phosphorus in rivers/lakes, as it was previously believed that organic phosphorus contributes insignificantly to the phosphate levels in the water. However, recent studies have revealed that orthophosphate in agricultural watersheds can be released from particulate organic phosphorus [50]. Bioavailable P, besides orthophosphate, is present in the phosphorus-containing fertilizers used in agricultural watersheds. Particulate organic phosphorus in the river has a significant chance of supplying PO43− into the river water [51,52]. This can trigger eutrophication in water bodies. After flowing across the extensive agricultural region, the tributaries enter Vembanad Lake, which may carry tons of organic phosphorus into the lake system. In Kerala, organic fertilizers like animal manure, and bone meal along with chemical fertilizers are widely applied before the onset of the south-west and north-east monsoon [35]. In our study, the TOP concentration was greater when the water level was low during the PRM season. TOP showed a significant (p < 0.05) seasonal difference, and it is positively correlated with DO (r = 0.354). A significant negative correlation was observed between TOP and TAHP (Table 4).
The total phosphorus (TP) ranged between 1020–2286.66 ppb in the PRM season and 743.33–1876.66 ppb in the POM season. We could not notice any significant (p > 0.05) variation among the seasons (Figure 4, Table 3). The maximum value of the TP was recorded at S14 (Manimala and Pamba) in the PRM season. With the POM season, the highest values were recorded at S6 (Meenachil) and S15 (Achankovil). Overall, the sampling stations in River Meenachil showed unusually higher values for most of the phosphorus fractions. The concentration gradations of the four phosphorus species observed are TRP > TAHP > TOP > TP in PRM and TRP > TOP > TAHP > TP in POM. The mean TRP, TOP, and TP concentrations were high at the PRM season when compared to the POM season. The absorption of TRP and TP by phytoplankton might be one reason responsible for this phenomenon [53]. Apart from this, the quantity of diffuse-source phosphorus entering the adjoining rivers is mostly determined by rainfall, hydrological conditions, and the land use in their watersheds [54]. The excessive fertilization of the soil with chemical fertilizers or the growth of algae that are capable to bind directly to PO43− from the air are both responsible for the high amounts of phosphorus [55]. The contaminants accumulated in the estuaries because of anthropogenic activities, and the dynamics of rivers and lakes may also have increased the quantities of nitrogen and phosphorus [56]. The landscape surrounding the Vembanad Lake is mainly agrarian, particularly enriched with paddy cultivation. It can contribute a large quantity of fertilizers into the aquatic system. The phosphorus loading in the Vembanad Lake was increased by the excessive and unscientific use of phosphatic fertilizers and pesticides in Kuttanad agriculture areas [43]. Vembanad Lake was the recipient of the 47 tons/year of PO43− that is transported by the River Pamba [35]. Correlation studies reveal that a strong positive correlation exists between TP and TOP; however, a moderate positive correlation between TP and TAHP was also noticed. No correlation existed between TRP with any other phosphate species (Table 4). The variation of TRP, TAHP, TOP, and TP concentration in water according to the seasons is shown in Figure 4, respectively.
Aquatic weeds including Eichhornia crassipes, Monochoria vaginalis, and Salvinia are proliferating unchecked in Vembanad and its interconnecting waterways. This rampant growth serves as a clear indicator of nutrient contamination in the southern part of Vembanad Lake. Eichhornia crassipes, in particular, is highly prevalent in tropical and subtropical water bodies due to its high nutrient content. This nutrient abundance stems from agricultural land runoff, deforestation, and inadequate water treatment processes [57].
Following the construction of the Thanneermukkom Bund, the southern section transformed into a dumping ground for pesticides, herbicides, fertilizers, and other agrochemicals utilized in the surrounding paddy fields [22]. The construction of the Thanneermukkom Bund has led to the southern section of the Vembanad Lake becoming a freshwater-dominant zone. This alteration was intended to facilitate double cropping in “Kuttanadu”. However, the absence of salinity in the water actively encourages the growth of Eichhornia, exacerbating the proliferation of this invasive species [58]. The eutrophication of the Vemband Lake system stands as the primary environmental factor fueling the growth of waterweeds. The combination of nutrient abundance and freshwater conditions within the lake system fosters the unchecked proliferation of these weeds. However, Eichhornia can be harvested promptly for use as compost, vermicompost, or biochar. These products not only decrease the nutrient levels in the water body but also improve soil fertility and crop productivity [59,60,61,62].

3.5. Principal Component Analysis

Understanding the intricate physicochemical and nutrient dynamics at river–lake interfaces presents a formidable challenge due to the complex and ever-changing nature of these ecosystems. Principal Component Analysis (PCA) provides valuable insights into these dynamics, as exemplified by the extracted principal components (Table 5 and Figure 5).
PC1, explaining 51.5% of the total variance, reveals significant positive loadings on various parameters such as TRP, Cl, SO4, Na, K, Mg, Ca, temperature, EC, TDS, salinity, and TH. These findings, along with the positive loading on PO4, temperature, conductivity, and salinity, strongly suggest the influence of agricultural and sewage runoff. The observed high association between these variables underscores the anthropogenic origins of the observed changes in water quality [43].
PC2, contributing 13.16% of the variance, demonstrates positive loadings on DO and pH. The correlation between DO and pH highlights potential eutrophication processes [63], with a high pH indicating fertilizer contamination [64] and high DO levels suggesting organic compound pollution [65]. The visible proliferation of aquatic plants during sampling further supports the notion of eutrophication affecting water quality
Explaining 7.49% of the variance, PC3 displays a high positive loading for TOP and temperature. This association implicates agricultural nonpoint-source pollution, the residues of aquatic plants, and algae in sediment organic phosphorus contributions [66]. Additionally, temperature variations may trigger sediment phosphorus release into the water column, intensifying nutrient dynamics [67].
In PC4, significant positive loadings for NH4 and pH point towards bird droppings and poultry farming as substantial sources of ammonia contamination [65]. The widespread presence of poultry farming and large flocks of migratory birds and heronries in the study area further accentuates the impact of these anthropogenic inputs on water quality [68,69].

3.6. Hierarchical Cluster Analysis (HCA)

Normally, cluster analysis serves to elucidate similarities between sampling sites. However, in this study, we employed hierarchical cluster analysis (HCA) to group sites with similar origins of pollutants and comparable water quality parameters. The HCA generated a dendrogram (Figure 6), revealing four significant clusters with related characteristics.
Cluster 1 includes river points from multiple rivers (S2, S13, S6, S15, S8, and S10). The sites in this cluster exhibit lower values of various physicochemical parameters, likely reflecting the relatively pristine conditions of these river points. The similarity in characteristics could indeed be attributed to their common classification as river points.
Cluster 2, comprising mostly river–lake interface points (S3, S16, S5, S12, and S9), exhibits significantly higher values of physicochemical parameters compared to Cluster 1. This suggests potential pollution sources or environmental influences at these locations, likely due to their proximity to both river and lake environments.
Cluster 3, encompassing sites S1 and S7, exhibits markedly elevated values in conductivity, total dissolved solids, salinity, hardness, chloride, and sulfate. This significant deviation in water quality parameters can be directly linked to the presence of the lime industry situated in S1 (Achinakam). The water from site S1 flows downstream to site S7, positioned at the lake–river interface. This hydraulic connection underscores the association between the industrial activities in Achinakam and the observed alterations in water quality parameters downstream, emphasizing the impact of anthropogenic influences on environmental conditions.
Cluster 4 consists of sites (S11, S14, and S4) with similar concentrations of chloride, sodium, potassium, and magnesium, with high values observed at these points. This suggests a distinct water quality profile possibly influenced by specific local pollution sources or geological factors.

4. Conclusions

In this study, we conducted an extensive assessment of phosphorus (P) levels in the water of Vembanad Lake, a Ramsar site, focusing particularly on the mouths of the rivers flowing into the lake. Our findings revealed widespread contamination by phosphates at the majority of our sampling sites. The mean concentrations of the total reactive phosphorus (TRP), total acid hydrolyzable phosphorus (TAHP), total organic phosphorus (TOP), and total phosphorus (TP) exceeded the permissible limits set by USEPA for uncontaminated lakes, causing a troubling level of eutrophication.
The presence of dense mats of Eichhornia and Monochoria across Vembanad Lake suggests an environment enriched with nutrients. One of the in-flowing rivers, Meenachil, stood out as a hotspot for TRP and TOP concentrations during both the pre-monsoon (PRM) and post-monsoon (POM) seasons. Moreover, the confluences of River Meenachil exhibited high values of TOP, TAHP, and TP during the POM season. Interestingly, while significant seasonal variations were observed for TOP, no such fluctuations were evident for TRP, TAHP, and TP.
During PRM, elevated concentrations of ions, notably chlorides, sulfates, sodium, potassium, and magnesium, were positively associated with reactive phosphate, indicating a common source of origin. Given the predominantly agrarian nature of Vembanad Lake and its surroundings, characterized by unique paddy cultivation below sea level, extensive fertilizer use and the local landscape play a significant role in phosphate accumulation in the lake system. Additionally, tourism activities in the region may exacerbate phosphate pollution.
Understanding the individual contributions of each adjoining river to phosphate loading is paramount. Our study offers crucial baseline data for phosphorus mapping in Vembanad Lake and its adjoining rivers, emphasizing the urgent need for a systematic and scientific approach to managing nutrient inputs into these aquatic ecosystems.
We advocate for measures aimed at reducing or preventing nutrient loads, alongside regular openings of the Thanneermukkom saltwater barrage, as effective strategies to curb the proliferation of aquatic weeds. This research underscores the importance of proactive initiatives to safeguard the ecological equilibrium of Vembanad Lake and its surrounding river networks.

Author Contributions

A.V.: Conceptualization, Methodology, Formal analysis, Writing—original draft. A.M.A.: Methodology, part of writing. G.M.I.: Methodology, Writing—review and editing. V.S.M.: Formal analysis, part of writing. M.I.S.: Writing—review and editing. V.J.K.: Methodology, Editing. U.K.A.: Writing—review and editing, Supervision. C.T.A. Writing—review and editing, Supervision. All authors have read and agreed to the published version of the manuscript.

Funding

The research work was carried out on the basis of project No. 30-PCF-23-24 dated 25 January 2023, subject: BR18574143 «Development and implementation of groundwater purification technology and provision of drinking water to the population and animals of an agricultural enterprise» financed by the Ministry of Science and Higher Education of the Republic of Kazakhstan. The partial funding from RUSA and SPARC is also acknowledged.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data will be made available upon request.

Acknowledgments

A.V. is thankful to UGC-RGNF (F1-17.1/2016-17-SC-KER-18885) for the doctoral research fellowship.

Conflicts of Interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

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Figure 1. Map of the sampling location along the Vembanad Lake and adjoining rivers.
Figure 1. Map of the sampling location along the Vembanad Lake and adjoining rivers.
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Figure 2. Spatial and temporal variations in physicochemical parameters in the study area.
Figure 2. Spatial and temporal variations in physicochemical parameters in the study area.
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Figure 3. Spatial and temporal variations in the ionic concentration of the study area.
Figure 3. Spatial and temporal variations in the ionic concentration of the study area.
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Figure 4. Seasonal variation in concentration of total reactive phosphorus (TRP), total acid hydrolysable phosphorus (TAHP), total organic phosphorus (TOP), and total phosphorus (TP).
Figure 4. Seasonal variation in concentration of total reactive phosphorus (TRP), total acid hydrolysable phosphorus (TAHP), total organic phosphorus (TOP), and total phosphorus (TP).
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Figure 5. Principal component analysis factor loadings for the variables.
Figure 5. Principal component analysis factor loadings for the variables.
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Figure 6. Dendrogram from HCA of sampling sites.
Figure 6. Dendrogram from HCA of sampling sites.
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Table 1. Variations in hydrographical parameters in the study area. Results of ANOVA also presented.
Table 1. Variations in hydrographical parameters in the study area. Results of ANOVA also presented.
ParameterSeasonal VariationsANOVA-p Value
(Seasonal)
Pre-MonsoonPost-Monsoon
RangeMeanRangeMean
Temperature (°C)28.5–32.231.0126.8–30.829.20.000
pH5.1–7.86.435.3–7.26.470.862
Conductivity (μS/cm)64–46182128.7546.1–2760669.450.014
TDS (ppm)41–30031382.7532.2–1970475.710.017
Salinity (ppm)20–24601092.528.2–1420332.230.051
DO (ppm)1.6–8.76.452.3–7.85.260.094
Hardness (ppm)18–526220.5616–25274.120.035
Chloride (ppm)8.31–3230.57936.064.01–1168.33210.920.021
Nitrate (ppm)ND–2.110.91ND–4.21.450.002
Sulphate (ppm)2.74–420.93121.251.89–116.2336.530.007
Sodium (ppm)16.34–1449.55443.852.72–413.7398.690.005
Ammonium (ppm)ND–12.557.88ND–12.527.440.564
Potassium (ppm)9.49–76.241.820.81–27.7114.490.000
Magnesium (ppm)3.26–174.5154.061.01–50.7715.230.023
Calcium (ppm)10.36–68.1729.012.45–79.8823.380.254
Table 2. Correlation matrix for the different physicochemical parameters of surface water measured in Vembanad Lake and adjoining rivers. * Correlation is significant at the 0.05 level (2-tailed), ** Correlation is significant at the 0.01 level (2-tailed).
Table 2. Correlation matrix for the different physicochemical parameters of surface water measured in Vembanad Lake and adjoining rivers. * Correlation is significant at the 0.05 level (2-tailed), ** Correlation is significant at the 0.01 level (2-tailed).
TRPTAHPTOPClNO3SO4NaNH4KMgCaTemppHECTDSSalinityDOTH
TRP1.000
TAHP−0.2321.000
TOP−0.067−0.400 *1.000
Cl0.399 *−0.359 *0.2221.000
NO3−0.0540.056−0.133−0.2161.000
SO40.359 *−0.3000.2160.952 **−0.1761.000
Na0.424 *−0.3480.2290.960 **−0.1770.934 **1.000
NH4−0.352 *0.2880.020−0.395 *0.059−0.361 *−0.3371.000
K0.375 *−0.402 *0.2890.713 **−0.2630.708 **0.833 **−0.2231.000
Mg0.469 **−0.3221900.953 **−0.0690.950 **0.964 **−0.370 *0.775 **1.000
Ca0.326−0.035−0.1180.682 **0.1110.669 **0.705 **−0.1320.616 **0.786 **1.000
Temp0.052−0.3130.3210.487 **−0.399 *0.519 **0.469 **−0.1050.534 **0.431 *0.2611.000
pH−0.0430.133−0.033−0.117−0.237−0.146−0.1690.280−0.212−0.180−0.1560.0071.000
EC0.317−0.364 *0.2170.960 **−0.1870.940 **0.940 **−0.415 *0.689 **0.937 **0.665 **0.444 *−0.2011.000
TDS0.321−0.372 *0.2300.956 **−0.1710.941 **0.935 **−0.418 *0.679 **0.935 **0.652 **0.421 *−0.1990.999 **1.000
Salinity0.322−0.3130.2220.941 **−0.1070.927 **0.929 **−0.425 *0.662 **0.933 **0.644 **0.378 *−0.2140.984 **0.988 **1.000
DO−0.084−0.0200.354 *−0.047−0.257−0.010−0.0460.1000.056−0.081−0.2570.396 *0.615 **−0.084−0.085−0.0871.000
TH0.404 *−0.2780.2020.975 **−0.1430.968 **0.957 **−0.386 *0.707 **0.974 **0.727 **0.442 *−0.1550.959 **0.957 **0.957 **−0.0821.000
Table 3. Minimum, maximum, and average values of total reactive phosphorus (TRP), total acid hydrolysable phosphorus (TAHP), total organic phosphorus (TOP), and total phosphorus (TP).
Table 3. Minimum, maximum, and average values of total reactive phosphorus (TRP), total acid hydrolysable phosphorus (TAHP), total organic phosphorus (TOP), and total phosphorus (TP).
Period of SamplingPhosphate SpeciesLowestHighestAveragePhosphate SpeciesANOVA
(Seasonal)
PRMTRP (ppb)76.66676.66332.91TRP0.567
TAHP (ppb)100.01033.33475.0
TOP (ppb)33.331243.34676.04TAHP0.064
TP (ppb)1020.02286.661483.95
POMTRP (ppb)110.0476.66303.74TOP0.024
TAHP (ppb)243.331276.67683.12
TOP (ppb)23.33890.0402.29TP0.459
TP (ppb)743.331876.661389.16
Table 4. Correlation between phosphate species, correlation is significant at p < 0.05.
Table 4. Correlation between phosphate species, correlation is significant at p < 0.05.
TRPTAHPTOPTP
TRP1
TAHP−0.2321
TOP−0.067−0.4001
TP0.110.410.601
Table 5. Principal component analysis.
Table 5. Principal component analysis.
Component
C1C2C3C4
TRP0.454−0.113−0.010−0.134
TAHP−0.1770.135−0.8010.110
TOP0.0850.2270.7910.048
Cl0.9650.0620.071−0.104
NO3−0.072−0.715−0.0510.133
SO40.9320.0810.074−0.076
Na0.940−0.0390.103−0.066
NH4−0.314−0.0490.0620.809
K0.817−0.0620.3370.000
Mg0.948−0.0620.073−0.047
Ca0.702−0.520−0.0740.348
Temperature0.4350.3570.4760.176
pH−0.1120.599−0.1780.598
Conductivity0.9320.0570.190−0.153
TDS0.9280.0370.188−0.159
Salinity0.9340.0660.182−0.154
DO−0.0340.8850.1300.165
Hardness0.9660.0640.133−0.084
Extraction Method: Principal Component Analysis. Rotation Method: Varimax with Kaiser Normalization. Rotation converged in 6 iterations.
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MDPI and ACS Style

Venukumar, A.; Azimov, A.M.; Iztleuov, G.M.; Moorchilot, V.S.; Aravind, U.K.; Sataev, M.I.; Koshy, V.J.; Aravindakumar, C.T. Temporal Assessment of Phosphorus Speciation in a Model Ramsar Lake System in Asia. Hydrology 2024, 11, 70. https://doi.org/10.3390/hydrology11050070

AMA Style

Venukumar A, Azimov AM, Iztleuov GM, Moorchilot VS, Aravind UK, Sataev MI, Koshy VJ, Aravindakumar CT. Temporal Assessment of Phosphorus Speciation in a Model Ramsar Lake System in Asia. Hydrology. 2024; 11(5):70. https://doi.org/10.3390/hydrology11050070

Chicago/Turabian Style

Venukumar, Anjali, Abdugani M. Azimov, Gani M. Iztleuov, Vishnu S. Moorchilot, Usha K. Aravind, Marat I. Sataev, Valsamma J. Koshy, and Charuvila T. Aravindakumar. 2024. "Temporal Assessment of Phosphorus Speciation in a Model Ramsar Lake System in Asia" Hydrology 11, no. 5: 70. https://doi.org/10.3390/hydrology11050070

APA Style

Venukumar, A., Azimov, A. M., Iztleuov, G. M., Moorchilot, V. S., Aravind, U. K., Sataev, M. I., Koshy, V. J., & Aravindakumar, C. T. (2024). Temporal Assessment of Phosphorus Speciation in a Model Ramsar Lake System in Asia. Hydrology, 11(5), 70. https://doi.org/10.3390/hydrology11050070

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