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Article

The Long-Term Detection of Suspended Particulate Matter Concentration and Water Colour in Gravel and Sand Pit Lakes through Landsat and Sentinel-2 Imagery

1
CNR–Institute for Electromagnetic Sensing of the Environmental, Via A. Corti 12, 20133 Milan, Italy
2
Department of Chemistry, Life Sciences and Environmental Sustainability, University of Parma, Parco Area delle Scienze 33/A, 43124 Parma, Italy
3
CNR–Institute of BioEconomy, Via Madonna del Piano 10, 50019 Firenze, Italy
*
Author to whom correspondence should be addressed.
Remote Sens. 2023, 15(23), 5564; https://doi.org/10.3390/rs15235564
Submission received: 2 October 2023 / Revised: 24 November 2023 / Accepted: 28 November 2023 / Published: 29 November 2023

Abstract

:
Over the past half century, the demand for sand and gravel has led to extensive quarrying activities, creating many pit lakes (PLs) which now dot floodplains and urbanized regions globally. Despite the potential importance of these environments, systematic data on their location, morphology and water quality remain limited. In this study, we present an extensive assessment of the physical and optical properties in a large sample of PLs located in the Po River basin (Italy) from 1990 to 2021, utilizing a combined approach of remote sensing (Landsat constellation and Sentinel-2) and traditional limnological techniques. Specifically, we focused on the concentration of Suspended Particulate Matter (SPM) and the dominant wavelength (λdom, i.e., water colour). This study aims to contribute to the analysis of PLs at a basin scale as an opportunity for environmental rehabilitation and river floodplain management. ACOLITE v.2022, a neural network particularly suitable for the analysis of turbid waters and small inland water bodies, was used to atmospherically correct satellite images and to obtain SPM concentration maps and the λdom. The results show a very strong correlation between SPM concentrations obtained in situ and those obtained from satellite images, both for data derived from Landsat (R2 = 0.85) and Sentinel-2 images (R2 = 0.82). A strong correlation also emerged from the comparison of spectral signatures obtained in situ via WISP-3 and those derived from ACOLITE, especially in the visible spectrum (443–705 nm, SA = 10.8°). In general, it appeared that PLs with the highest mean SPM concentrations and the highest mean λdom are located along the main Po River, and more generally near rivers. The results also show that active PLs exhibit a poor water quality status, especially those of small sizes (<5 ha) and directly connected to a river. Seasonal comparison shows the same trend for both SPM concentration and λdom: higher values in winter gradually decreasing until spring–summer, then increasing again. Finally, it emerged that the end of quarrying activity led to a reduction in SPM concentration from a minimum of 43% to a maximum of 72%. In this context, the combined use of Landsat and Sentinel-2 imagery allowed for the evaluation of the temporal evolution of the physical and optical properties of the PLs in a vast area such as the Po River basin (74,000 km2). In particular, the Sentinel-2 images consistently proved to be a reliable resource for capturing episodic and recurring quarrying events and portraying the ever-changing dynamics of these ecosystems.

1. Introduction

Our society relies on a huge amount of sand and gravel for the construction of infrastructure, roads, runways, railways, etc. Initially, most of the aggregates were directly withdrawn from riverbeds, causing a gradual incision of the riverbed and deep morphological and hydrological alterations. In the 1980s, given the serious degradation of river ecosystems, the quarrying activity was shifted from riverbeds to floodplains, leading to the formation of pit lakes (PLs) [1]. PLs are now widespread globally and increasingly affect the landscape of urbanized regions around the world [1]. The creation of PLs can impact the landscape and environment in several ways, both positive and negative. In general, these ecosystems can play some important ecological and socioeconomic roles; however, anthropogenic impacts and mismanagement can lead to a number of issues (e.g., water contamination, changes in groundwater quality, alteration to river hydromorphology, eutrophication, disruption of pre-existing habitats, etc.) [2,3,4,5,6,7,8,9].
Once quarrying activities are concluded, PLs may evolve towards ecosystems that provide processes and functions that can be useful to society, e.g., water storage and management, nutrient retention or removal, improvement of groundwater quality, creation of new aquatic habitats, etc. [1]. In the last two decades, several studies have been published on PLs focusing on the eutrophication issue [10], the management and regulation of these ecosystems [2,6], the hydro-chemical aspects [3,4,7,8] and biogeochemical processes and functions [9,11]. However, all of these studies only concern a small sample of PLs and are often limited both spatially and temporally, so there is a lack of systematic water quality products or datasets available for these ecosystems. With the aim of filling this gap, the main focus of this study is to assess the physical and optical properties of a large sample of PLs located in the Po River basin (Italy) from 1990 to 2021 using a combined approach of remote sensing and traditional limnological techniques. The Landsat mission satellites (Landsat-5 and Landsat-7) provide an opportunity to utilise data from a long time series to analyse PLs from the 1990s to 2014. Meanwhile, the more modern Sentinel-2 allows for the exploitation of additional spectral capabilities, high spatial resolution, and short revisit time for more frequent and detailed monitoring. Here, we focus on the calculation of the dominant wavelength (λdom, i.e., water colour) and the concentration of Suspended Particulate Matter (SPM); parameters that can contribute to the assessment of water quality.
Water colour is one of the oldest water observation parameters and is closely related to the optical properties of water, constituting a fundamental indicator for the optical water quality [12]. It is a result of water constituents and their interaction with sunlight, establishing the basis for water-quality monitoring through optical remote sensing. This suggests that the information obtained from the colour of PLs can contribute to the assessment of their quality status. As a consequence, this parameter has also been recognised by the Global Climate Observing System as a fundamental climate variable for inland waters [13]. SPM is another key parameter for describing water characteristics and can contribute to assessing aquatic ecosystems’ quality [14,15,16,17,18,19,20,21]. It is a bio-optical parameter consisting of a mix of inorganic substances (e.g., mineral sediments), organic constituents (e.g., algal particles and vegetation debris) and water-insoluble microorganisms. In particular, most SPM manifest as complex, floc-like aggregate structures composed of a variety of minerals and organic matter ranging from the molecular to the organismal level [22]. SPM concentration can directly and significantly influence the optical properties of water through the absorption and scattering of sunlight [23,24]. For example, it can directly reduce light penetration, affecting phytoplankton productivity and nutrient dynamics, as well as the living conditions of both aquatic animals and vegetation [21,24,25,26,27,28,29,30,31]. Therefore, monitoring temporal and spatial variations in SPM concentration is crucial for understanding the dynamics of aquatic ecosystems [15,17,19,23,24,32,33,34]. As a consequence, SPM plays a prominent role as an indicator to monitor the degradation of inland water resources and guide their management [35,36,37]. Particularly in inland waters, this parameter is often correlated with nutrient enrichment, such as that of nitrogen and phosphorus [38,39], while in many high-turbid lakes, it has been directly associated with dredging activity [40]. Given the importance of this parameter, many approaches and sensors have been adopted over the years to accurately estimate the SPM concentration from optical remote sensing data [26,38,41,42,43,44,45,46,47,48,49,50].
One of the advantages of Earth Observation (EO) data is its ability to obtain water quality information remotely over large areas and over the long term. It offers the opportunity to increase and improve the spatio-temporal coverage of inland water environmental monitoring [51]. In recent years, remote sensing has become a low-cost operational tool that, in support of traditional limnological measurements, provides information on the state of surface waters by deriving bio-geophysical parameters, such as chlorophyll-a concentration [52,53,54], turbidity [55,56], suspended particulate matter [31,57,58], phytoplankton types [59] and Secchi disk depth [60,61]. In particular, both water colour and SPM-concentration products can be retrieved from satellite images.
Recently, an algorithm based on multispectral information acquired from satellite sensors has been proposed to derive the hue angle, an indicator that can be used to determine the λdom of a water body (i.e., the water colour) [62,63]. This indicator is called the Forel-Ule Index (FUI) and is derived from Remote Sensing Reflectances (Rrs). The FUI is not based on local retrieval algorithms; therefore, it can characterise natural waters easily and effectively [64,65]. FUI, still used today, is a benchmark standard in numerous studies [13,51,65,66,67,68,69,70,71], and is characterised by having a relatively low uncertainty [62,63,66].
The monitoring of SPM concentration using traditional limnological techniques can provide accurate measurements; however, they are time-consuming, expensive and spatially limited [18,72,73,74,75]. On the other hand, remote sensing techniques can be useful to complement in situ measurements, as they allow for large-scale, long-term observations of Visible-Near infrared (VIS-NIR) spectral regions which can be exploited to map SPM concentration [18,23,24,32,33,37,75,76,77,78,79,80,81].
In the present study, we assess the evolution of the λdom and the SPM concentration in a large sample of PLs and we expect to find a clear difference according to their sizes and locations, as well as in according with quarrying activity and seasonal variations. Our study seeks to examine the reliability of Landsat and Sentinel-2 satellites in estimating these two water quality parameters in small and dynamic aquatic environments such as PLs. The results highlight that location and size are the principal factors influencing water quality status; moreover, it emerged that disturbance from quarrying activity does not have a long-term impact on water quality, because after the cessation of quarrying, SPM concentration decreases rapidly, although, on average, ceased PLs are characterised by higher a λdom than those still active.

2. Materials and Methods

2.1. Study Area

The Po River basin extends around one of the largest rivers in the Mediterranean Sea and the longest river in Italy. The Po River is 652 km long and its basin covers approximately 74,000 km2, of which ~71,000 km2 are in Italy. In terms of water resources, the Po River (with an average annual flow of 1540 m3 s−1 which has been gradually decreasing since the 21st century) is overexploited for irrigation, hydropower generation, and domestic purposes [82,83]. The Po River basin represents a key territory for the economy of the entire country; in fact, economic activities within it account for about 40% of Italy’s annual GDP [84,85]. In particular, the Po River basin contributes to about 60% of national sand and gravel production. The climax of this sector occurred from the post-World War II period until the 1980s, during which great amounts of inert materials were extracted directly from the riverbed to support post-war reconstruction, causing its gradual lowering [86]. Once the severity of the river alteration was felt, mining activity was moved to the floodplain, leading to the creation of numerous PLs. For more details regarding water resources and quarrying activities in the Po River basin, see [1].
In the Po River basin, 1580 PLs have been identified, of which 338 were still active in 2021 [1]. These PLs differ in location (isolated, in proximity to or connected to a river), size (<1 to 52 ha), and quarrying activity (active or ceased). For more details regarding identification and classification of PLs see [1].
For this study, a large subsample of PLs (320, both active and ceased) located in eight geographical areas within the basin was selected (Figure 1): Turin (TO), Po and Orba River Park (OR), Milan (MI), Trezzo sull’Adda (TR), Brescia (BS), Mantua (MN), Modena (MO), and along the Po River shaft (PO). These areas were selected because they are spatially well-distributed and representative of different land uses [1]. In each of these geographic areas, the density of PLs is high and consequently they exhibit a high degree of heterogeneity and well represent the entire basin.

2.2. The Processing of Satellite Images

Considering the wide time range used for this study (1990–2021), three different satellites were used: Landsat-5 (L5), Landsat-7 (L7) and Sentinel-2 (S2). The L5 and L7 belong to the Landsat constellation, and mount onboard TM (Thematic Mapper) and ETM+ (Enhanced Thematic Mapper) sensors, respectively. They are characterised by a spatial resolution of 30 m, a revisit time of about 16 days and 5 bands in the VIS-SWIR (Visible-Short Wavelength InfraRed) domain. The S2 mission, on the other hand, comprises two polar satellites (S2A and S2B), placed on the same orbit, but offset 180° from each other, allowing a revisit time of about 5 days. They mount onboard MultiSpectral Instrument (MSI) sensors, characterised by three different spatial resolutions (10, 20 and 60 m) and 13 bands in the VIS-SWIR.
All satellite images were downloaded as Level-1 (L1, i.e., not atmospherically corrected) from the following portals: https://catalogue.onda-dias.eu/catalogue/ (accessed on 1 October 2023) and https://earthexplorer.usgs.gov/ (accessed on 1 October 2023). All S2 images were resampled to the same spatial resolution (10 m). The years considered are listed in Table S1 and for each year, when available, six images were downloaded. Since there is no specific protocol for SPM concentration, we followed the protocol proposed by [87] for sampling lake phytoplankton, according to the European Water Framework Directive (WFD): winter (1 January–20 March), spring (1 April–15 May), spring-summer (16 May–15 June), summer (1 July–31 August), summer-autumn (1 September–1 October) and autumn (2 October–31 November). A total of 375 satellite images divided into the eight subsample areas were downloaded, and these images were free of clouds and other radiometric problems (e.g., sunglint).
ACOLITE v.2022 [88,89] was used to atmospherically correct satellite images and to obtain SPM concentration maps. ACOLITE is a neural network that groups atmospheric correction algorithms and allows users to derive different water quality parameters from Rrs values. In addition, it is particularly suitable for the analysis of turbid and small inland water bodies. ACOLITE requires L1 satellite images as inputs and can mask all water pixels autonomously. The atmospheric correction algorithm used was Dark Spectrum Fitting (DSF), which is able to estimate Aerosol Optical Depth at 550 nm (AOD550) from dark targets, while the algorithms used to estimate SPM concentration were: SPM_Nechad2010 (for Landsat images), adjusted with the in situ data specific to our case studies, and the SPM_Nechad2016 (for S2 images). The former was proposed by [46], while the latter was recalibrated in 2016 specifically for S2 images. Both exploit the spectral characteristics of the red band (630–690 nm). For more information regarding the two algorithms, see [46].

2.3. Field Campaigns and Validation

To validate SPM concentration maps obtained by processing Landsat images with ACOLITE code, we used SPM concentration data collected by the University of Parma from 1993 to 2013. To this aim, all cloud-free Landsat images with a maximum discrepancy of two days from in situ sampling were downloaded, totalling 76 images. To validate S2 data, we carried out seven specific field campaigns (11 April 2022, 13 April 2022, 20 June 2022, 27 June 2022, 13 September 2022, 28 September 2022, and 15 June 2023) in PLs located in the PO area between 2022 and 2023 (Table S2).
During these field campaigns, water samples were collected, and spectral signatures (Rrs) were acquired at the same sites. Water samples were filtered with Whatman GF/F fibre filters and used to determine gravimetrically the SPM concentration according to [90]. Dry filters where subsequently incinerated in the muffle at 450 °C for 4 h to obtain inorganic and organic fractions of the particulate. Reflectance measurements were collected using the handheld spectrometer WISP-3 [91] produced by Water Insight. The instrument is designed for water quality studies and can be used for the optical validation of satellite data. The optical range is from 400 to 800 nm, with a bandwidth (full width half maximum) of ~4.9 nm and is able to simultaneously measure water and sky radiances at 42° to the nadir (Lu and Lsky, respectively) and downwelling irradiance (Ed), using three different optics and appropriate geometry. Together, these three optics can be used to obtain the Rrs of the water surface. All measurements (5 replicates for every single station) were taken away from the shoreline to avoid any influence of the bottom on the radiometric measurements; in addition, measurements were taken at an azimuth angle of ~135° to the sun to avoid any sunglint effects.
To compare the satellite data with in situ data, Regions of Interest (ROIs) (3 × 3 pixels) centred around the sampling site were created and the mean value was extracted for both SPM and Rrs; afterward, a series of descriptive statistics were calculated to assess their consistency. In detail, the determination coefficient (R2), Mean Absolute Error (MAE), Root Mean Square Error (RMSE) and Mean Absolute Percentage Error (MAPE) were calculated for both parameters. In addition, for spectral signatures only, the Spectral Angle (SA) was also calculated, which was used to determine how similar the shape of satellite spectra is to in situ data [92,93]. The metrics used were computed as follows:
R 2 = 1 i = 1 n x i y i i = 1 n x i x ¯ i 2
M A E = i = 1 n x i y i n
R M S E = i = 1 n x i y i 2 n
M A P E = m e d i a n y i x i x i 100 % , i = 1 , N
S A = c o s 1 i = 1 n x i y i i = 1 n y i 2 i = 1 n x i 2
where x i are the in situ values, x ¯ i is the mean of the in situ values and y i are the values derived from satellite images.
In order to compare the spectral signatures acquired in situ (hyperspectral) with the spectral signatures of S2 (multispectral), a resampling of the hyperspectral signatures was performed based on spectral characteristics of S2. In particular, the higher spectral resolution of WISP data were spectrally resampled according to the full width half maximum (FWHM) of S2 data.

2.4. Pit Lakes Analysis

The identification of water pixels by ACOLITE is not always accurate because the pixels located at the water–land interface, which could lead to an overestimation of SPM concentrations, are often retained. For this reason, ACOLITE products were overlaid on the true colour images in order to verify the effective removal of terrestrial pixels and clouds. After that, starting from the ACOLITE water mask, all pixels located near the shorelines were manually removed. In addition, spectral signatures were examined for outliers within the water pixels. Once the ROIs were created, they were used to extract SPM concentration and Rrs values in the Visible domain, which were needed to obtain the λdom (water colour) via the Forel-Ule index [63]. More information on the procedure to obtain the λdom from Landsat and S2 images can be found in [63]. Finally, all outliers characterised by negative or excessively high values, often due to the presence of dredges in the middle of active PLs, were manually removed from these maps. Once the SPM concentrations were extracted from the PLs of all available images, the temporal trends of each lake and the average SPM concentration of each subsample area were calculated.
PLs were also divided into various thematic groups, with the purpose of understanding whether SPM concentration and λdom changed according to lake location, size, season (according to WFD protocol) and quarrying activity. Based on location, PLs were divided into three categories: isolated, in proximity to (at most 500 m away from a watercourse) or connected to a river. Based on dimension, they were divided into: small (<5 ha), medium (5–10 ha) and large (>10 ha). Based on season, the WFD protocol was followed, while based on quarrying activity, they were divided into: active and ceased. The Mann–Whitney and Kruskal–Wallis nonparametric tests were performed to assess whether there were significant differences in SPM and λdom among the categories that compose each thematic group.
To specifically assess the impact of quarrying activity on the evolution of the water quality of PLs, two types of analysis were conducted on a restricted number of PLs. The first involved the analysis of temporal trends of SPM concentration in 13 PLs whose quarrying activity ceased during the observed period (1990–2021). Specifically, the mean SPM concentrations before and after the end of quarrying activity was calculated for the 13 lakes, considering all available images. For this analysis, the cumulative precipitation during the seven days prior to the date of satellite acquisition was measured to understand the influence of this meteorological factor. The wind was not considered because the PLs examined were characterised by extensive areas of riparian vegetation in their surroundings (on average, 80% of the perimeter of those PLs were covered by vegetation). The second analysis concerned two adjacent PLs located in the MI area: one whose quarrying activity had ceased (MI-30), and the other which was characterised instead by frequent quarrying episodes (MI-31). For this analysis, 27 S2 images acquired during quarrying events were downloaded and processed with ACOLITE in order to obtain SPM concentration maps.

3. Results

3.1. Satellite Data Validation

The statistical comparison between the SPM concentrations obtained in situ and those derived from satellite images showed that there is a very strong correlation between both the data derived from Landsat images (R2 = 0.85) and those from S2 images (R2 = 0.82). However, it appeared that the SPM_Nechad2010 algorithm applied to the Landsat images overestimated the SPM concentration; consequently, two calibration coefficients were applied, one for the L5 and one for the L7 data, calculated on the basis of the slope of the regression lines. In both scatterplots, we removed a comparison related to a very turbid lake because, although there was a strong correlation between the in situ and satellite data, they distorted the R2 values, over-improving them.
The comparison of the spectral signatures obtained using WISP-3 and those derived from ACOLITE showed that there is a strong correlation in the visible spectrum, while some issues emerge in the NIR domain (a slight overestimation of satellite values). This overestimation is not impactful for this work, since the algorithms for estimating the SPM concentration were based on the red band (630–690 nm), while the calculation of the λdom was based on the visible bands. Furthermore, the accuracy of the spectral signatures obtained through ACOLITE is also justified by the low SA values obtained for the 28 comparisons performed (10.8° ± 5.7°). The graphs for the statistical metrics are shown in Figure 2 and Figure 3.

3.2. SPM Concentration and Water Colour

Figure 4 shows the mean SPM concentration and the mean λdom (1990–2021) for all PLs of the subsample investigated. SPM values range from 1 to 88 g m3, while λdom range from 480 to 589 nm. The PLs with the highest mean SPM concentrations are located along the Po River (especially in OR and PO areas) and more generally near rivers. For mean λdom, the pattern is also similar, although it is less pronounced than that of SPM concentration. In fact, PLs with high mean λdom are mainly located near rivers, although they are also present in other areas (e.g., MI area).
Based on the PLs’ locations, the analysis shows that those connected to a river (active: 21.4 ± 2.0 g m−3; ceased: 15.7 ± 5.9 g m−3) are characterised by higher mean SPM concentrations than both PLs located in proximity of a watercourse (active: 14.5 ± 7.9 g m−3; ceased: 12.8 ± 7.4 g m−3) and isolated ones (active: 12.4 ± 8.2 g m−3; ceased: 8.9 ± 3.7 g m−3), for both active and ceased PLs. The same result also emerges for the mean λdom. Based instead on size, smaller PLs (active: 18.2 ± 11.5 g m−3; ceased: 11.4 ± 6.6 g m−3) have the highest mean SPM concentrations compared to medium (active: 14.3 ± 7.2 g m−3; ceased: 9.3 ± 4.2 g m−3) and large lakes (active: 10.7 ± 5.3 g m−3; ceased: 9.7 ± 5.1 g m−3). In this case, the difference between the three categories is more pronounced for active PLs than for ceased ones. The mean λdom follows the same pattern only for ceased PLs (571 ± 3, 569 ± 3, 568 ± 3 nm, respectively), while smaller active PLs are characterised by lower mean λdom than medium sized PLs (565 ± 7, 568 ± 4, 565 ± 5 nm, respectively). Seasonal comparison shows the same trend for both SPM concentration and λdom: higher values in winter gradually decrease until spring–summer, then increase again. No differences are visible between active and ceased PLs. Finally, the comparison based on quarrying activity shows that active PLs (13.3 ± 8.2 g m−3) exhibit higher mean SPM concentration than ceased PLs (10.6 ± 5.9 g m−3); however, ceased PLs (570 ± 3 nm) show higher mean λdom than active PLs (566 ± 6 nm). All comparisons are shown in Figure 5, while the values divided into the eight subsample areas are reported in Tables S3 and S4.
By comparing the PLs characterised by low mean values of SPM and λdom (PLs low) with the PLs characterised by high mean values of SPM and λdom (PLs high), it was observed that the PLs low are larger (mean: 12 ha) and older (and consequently deeper). These PLs are predominantly isolated and consistently exhibit lower mean SPM concentrations compared to the overall mean of the subsample area where they are located. On the other hand, PLs high are smaller (mean: 5 ha) and younger (and consequently shallower). They are predominantly located in proximity or directly connected to a river, and consistently display higher mean SPM concentrations compared to the overall mean of the subsample area in which they are located.

3.3. The Impact of Quarrying Activity and Precipitation

Table 1 shows the mean SPM concentrations of the 13 PLs before and after the cessation of quarrying activity (Figures S1–S5). The results show that the mean SPM concentration decreases from a minimum of 43% to a maximum of 72% (a mean reduction of 54%).
A clear correlation between SPM concentration and cumulative precipitation was not found for the 13 PLs analysed. For these comparisons, we exclusively considered values obtained after the ending of the quarrying activity. This approach ensured the elimination of any variability introduced by the resuspension associated with dredging.
Figure 6 shows the SPM concentration of PLs MI-30 (ceased) and MI-31 (active) during some quarrying events. The results show that MI-31 is consistently characterised by higher SPM concentrations than MI-30, especially in the southern part where the dredge is located. In addition, it is evident how the SPM peak located in the excavation area moved and extended rapidly within a few days to the entire lake (e.g.,16 June 2018 to 21 June 2018, 9 September 2019 to 14 September 2019, 10 June 2021 to 15 June 2021).

4. Discussion

4.1. The Reliability of Remote Sensing for PLs’ Water Quality Assessments

Satellites used for land monitoring, such as Landsat and Sentinel-2, provide images characterised by high spatial resolution that enable the assessment of water quality parameters. In particular, recent studies have corroborated the capabilities of such satellites in monitoring inland waters and small lakes [18,94,95,96,97,98]. This success can be attributed to the increase in the average revisit interval, which has resulted in a concomitant increase in the number of cloud-free images. Such an abundance of data, therefore, allows a near real-time monitoring of such dynamic environments.
In this study, we conducted an in-depth analysis of the reliability of Landsat-5, Landsat-7 and Sentinel-2 satellites in assessing the physical and optical properties of PLs, focusing on the estimation of SPM concentration and λdom. Our approach included the comparison of SPM concentration data obtained in situ by limnological techniques with those retrieved through the use of the neural network ACOLITE on satellite data. The results of this comparison revealed a remarkable agreement; however, the SPM_Nechad2010 algorithm employed for the Landsat images showed a tendency to overestimate SPM concentrations. It was necessary to correct this overestimation by a recalibration process based on the reference data obtained in situ. The validation was mainly focused on PLs characterised by SPM concentrations below 20 g m−3, due to a logistic constrain that did not allow the access to many PLs for field measurements. However, although only a few data were available for PLs with particularly high SPM concentrations, the agreement between in situ and satellite values was very strong. Nevertheless, these data were not included in the main validation step, as they would have distorted the scatterplots (Figure 2), over-enhancing the coefficient of determination (R2). In the future, it would be appropriate to find accessible PLs with SPM concentrations above 20 g m−3. This would allow a more complete and detailed validation of the performance of the ACOLITE algorithm in environments characterised by such levels of SPM concentration. Moreover, it would be interesting to identify a few sample lakes and analyse their temporal evolution in detail through the integration of S2 data with products derived from, for example, Landsat-8 and Landsat-9 images, in order to avoid temporal gaps between data.
In addition to the SPM concentration, we also performed a comparison of the Rrs spectral signatures, obtained by the atmospheric correction of S2 images through ACOLITE, with those acquired through the Water Insight spectrometer WISP-3. This spectral parameter is essential for the calculation of λdom, and consequently, a robust agreement between the values obtained in situ and those detected by satellites is crucial. The comparison reveals strong agreement in the visible domain (400–700 nm), while some discrepancies were found in the NIR domain (a slight overestimation of satellite values). Specifically, the 740 nm band showed very good effectiveness for turbid waters, as the presence of high SPM concentrations increases reflectance levels in both the red and NIR domains. However, this band is not as effective in clearer waters, where reflectance values should tend to zero. This phenomenon could result from an error in atmospheric correction due to the intrinsic properties of water in the infrared domain [99,100]. This overestimation does not have a significant impact on our investigation, since the two algorithms used to estimate SPM concentrations (SPM_Nechad2010 and SPM_Nechad2016) were based on the red band (630–690 nm), while the calculation of λdom was based exclusively on the visible bands. More generally, the strong agreement between the spectral signatures collected in situ and those obtained from satellite data was confirmed by the low values obtained from the calculation of the SA statistical index (10.8° ± 5.7°).

4.2. The Assessment of PLs’ Water Quality

The use of a combined approach between Landsat and Sentinel-2 satellite images allowed for the estimation of the mean SPM concentration and mean λdom for each PL over a three-decade period (1990–2021). Most of the challenges in inland water observations are due to their optical complexity. These aquatic ecosystems can be a mixture of optically shallow and deep waters, with gradients of oligotrophic to hypertrophic productive waters and clear to turbid conditions. Hence, a large range in optical absorption and backscattering resulting in high optical variability can be found among and within lakes. This creates a challenge for algorithms applied to optical remote sensing for water-quality monitoring. Furthermore, another challenge is performing atmospheric corrections over such variable aquatic ecosystems, as their complexity requires different approaches than those for land and ocean applications.
The results of this temporal analysis revealed that the PLs with the highest mean SPM concentrations and highest mean λdom are located along the Po River (especially in the OR and PO areas) and, in general, near waterways and rivers. This finding is further confirmed through the subdivision of PLs into thematic groups; in fact, PLs connected to a river and those located in their proximity exhibited higher mean SPM concentrations and mean λdom than isolated PLs. These PLs are fed by river waters and, especially during flood periods, receive a large amount of suspended solids and nutrients that can lead to a higher trophic state [9]. Recent studies have shown that, as a consequence of climate change, periods of prolonged drought followed by short periods of flooding after intense precipitation are becoming more frequent and intense in the Po River basin [83]. Thus, our results suggest that there is a significant potential for climate change to affect the water quality of PLs, particularly those connected to rivers, with prolonged periods of higher transparency during droughts and more turbid waters following flood events.
Focusing on quarrying activity, it turned out, as might be expected, that active PLs are characterised by a higher mean SPM concentration than ceased PLs. This is mainly due to the mechanical action of the dredgers, which collect inert materials from the lake bottom and cause considerable resuspension of bottom sediments and stirring of suspended material. On the other hand, the mean λdom analysis shows that the ceased PLs show a higher mean λdom than the active PLs. Specifically, ceased PLs tend more toward a green-yellow colour, a feature attributable to the moderate presence of phytoplankton and Coloured Dissolved Organic Matter (CDOM). In fact, the absence of turbulence caused by dredges may contribute to greater water clarity, allowing sunlight to penetrate deeper and potentially promoting more algal particle growth. In addition, the high cover of riparian vegetation in the surroundings of the ceased PLs could result in an increased concentration of CDOM, via inputs of allochthonous dissolved organic matter [101,102].
The division of PLs according to size revealed that small lakes (<5 ha) on average have higher SPM concentrations than their larger counterparts. This trend is more pronounced in PLs that are still active, while it tends to diminish in those that have ceased the quarrying activity. The explanation for this phenomenon may lie in the fact that, in smaller active PLs, quarrying activity has only recently started. As a result, such lakes are generally shallow and subject to the mechanical action of dredges, and to wind and fish action. These phenomena can resuspend lake sediment from the bottom, causing a drastic increase in SPM concentrations. The same trend is also reflected in the analysis of the mean λdom in ceased PLs, while for active PLs, the results show that small-sized PLs are characterised by a lower λdom than medium-sized PLs. This result could be attributed to the sparseness or absence of riparian vegetation in small-sized active PLs. In fact, the presence of riparian vegetation may lead to the introduction of organic debris into the waters, which, once dissolved, may contribute to increases in the λdom.
Finally, the increase in SPM concentration during the winter and autumn periods can be attributed to water mixing, increased wind and rainfall, and a reduction in riparian vegetation; factors that promote the input of particulate material from outside. In addition, more organic debris may flow in lake waters during these periods, leading to an increase in CDOM. On the other hand, the green hue of the waters, predominant in the spring and summer months, may be explained by algal blooms, caused by increased nutrients reaching the lake from agricultural fields, associated with higher temperatures.

4.3. The Impact of Quarrying Activity and Precipitation

Quarrying activity has been proven to have a considerable impact on PLs. For example, the turbulence generated within the water column disrupts thermal stratification and resuspends significant amounts of sediment, exerting a significant influence on the lake’s planktonic community [103,104,105]. At the same time, sediment resuspension contributes to increased turbidity in the water, resulting in decreased sunlight penetration. This phenomenon, in addition to reducing the amount of light available to phytoplankton, influences macrophyte communities that may establish along banks characterised by gentle slopes. Such communities play a crucial role in maintaining high water quality standards [106], as well as providing habitats and food sources for numerous aquatic organisms [7,8].
The characteristics of the MSI sensor installed onboard the S2 have been proven suitable for analysing the impact of quarrying activity on the SPM concentration of PLs. This suitability extends to both the long-term, allowing for the evaluation of temporal trends in SPM concentrations before and after the cessation of quarrying activities, and the short-term, allowing for the detection of recurring and episodic turbidity events in specific PLs that occur at small spatio-temporal scales. However, despite a high spatial resolution and a short revisit time, the extent of some small, newly formed pit lakes and the presence of clouds at specific periods of the year may limit the observation of short, punctual quarrying episodes.
As was to be expected, the end of quarrying activity led to a marked decrease in SPM concentrations in all of the PLs examined (a mean reduction of 54%), mainly due to the cessation of the mechanical sediment-stirring action carried out by the dredges. However, even once quarrying activity was over, no direct correlation emerged between SPM concentrations and total precipitation, as might have been expected. This could depend on multiple factors, including the actual location of the weather station relative to the lake and the time scale adopted, as soil erosion responds not only to the total amount of rainfall but also to rainfall intensity. In our perspective, it would be interesting to identify a weather station near a lake and consider a change in the time interval considered for the total precipitation. A plausible hypothesis is that within the total precipitation, rainfall that occurs shortly after the satellite image acquisition may have a greater influence than rainfall that occurs days later. Moreover, there is a complex relation between precipitation intensity, plant biomass and composition and erosion [107] that could influence water quality. This analysis is beyond the scope of this work but, given the observed changes in land cover due to climate change and anthropogenic activities observed in the Po river watershed [108], the approach adopted in this work could be useful in the future for understanding the consequences of climate change and directing anthropic activity on the water quality of PLs.
An additional finding from this research indicates that the resuspension action actuated by the dredges is not confined to a single well-defined point. On the contrary, the increase in the SPM concentration found at the sampling point spread gradually throughout the entire lake over the course of a few days (potentially even more rapidly, given the frequency of the revisiting of S2, which occurred approximately every 5 days).

5. Conclusions

This research confirmed the reliability of Landsat and Sentinel-2 satellites in performing a basin-scale assessment of SPM and λdom concentrations in small, dynamic inland waters such as PLs. The approach adopted to quantify these two parameters allowed a comprehensive and in-depth assessment of the quality status of these ecosystems over three decades (1990 to 2021). The spatial and spectral characteristics of these satellites opened up new perspectives in the study of these lakes, which were otherwise inaccessible using traditional limnological techniques.
The key results include that the water quality status in these lakes depends on multiple factors, including their location and size. In fact, it was found that the lakes with a poor water quality status (based on both SPM concentration and λdom) were those of small sizes, often located near or directly connected to rivers. In addition, quarrying activity appears to have a significant impact on PLs, as it has been demonstrated that the end of such activities results in a marked decrease in SPM concentrations (a mean reduction of 54%). Inversely, the extraction of inert materials from the lake bottom causes an increase in SPM concentrations, an effect that propagates rapidly throughout the water body from the point of extraction. In this regard, the Sentinel-2 satellite has proven to be a reliable tool for detecting these episodic or recurrent events in a dynamic context.
A significant future step in the study of these aquatic ecosystems could be the installation of fixed instruments for collecting continuous spectral measurements to estimate SPM concentrations. This type of approach would allow for further insight into the study of water quality through continuous measurements that could overcome the limitations of satellite remote sensing, such as revisit time and cloud cover. The integration of in situ and remote data both radiometric and limnological combines synergistically to provide insight into waterbody bio-geochemistry, which can be extended over time, allowing their genesis and evolution to be explored.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/rs15235564/s1, Table of acronyms, Table S1. Landsat-5 (L5, red), Landsat-7 (L7, blue) and Sentinel-2 (S2, green) satellite images processed for subsample pit lake analysis. Turin (TO), Po and Orba River Park (OR), Milan (MI), Trezzo sull’Adda (TR), Brescia (BS), Mantua (MN), Modena (MO), and along the Po River shaft (PO). The seasons follow the WFD protocol: winter (Win.; 1 January–20 March), spring (Spr.; 1 April–15 May), spring-summer (Spr.–Sum.; 16 May–15 June), summer (Sum.; 1 July–31 August), summer-autumn (Sum.–Aut.; 1 September–1 October) and autumn (Aut.; 2 October–31 November). Table S2. In situ measurement campaigns to validate remote sensing (RS) products from Sentinel-2 satellite images. Table S3. Mean SPM concentrations (g m−3) divided into the four categories (location, dimension, season and quarrying activity) and into the eight subsample areas: Turin (TO), Po and Orba River Park (OR), Milan (MI), Trezzo sull’Adda (TR), Brescia (BS), Mantua (MN), Modena (MO), and along the Po River shaft (PO). Small (S.), medium (M.) and Large (L.). Winter (Win.; 1 January–20 March), spring (Spr.; 1 April–15 May), spring-summer (Spr.–Sum.; 16 May–15 June), summer (Sum.; 1 July–31 August), summer-autumn (Sum.–Aut.; 1 September–1 October) and autumn (Aut.; 2 October–31 November). Table S4. Mean λdom (nm) divided into the four categories (location, dimension, season and quarrying activity) and into the eight subsample areas: Turin (TO), Po and Orba River Park (OR), Milan (MI), Trezzo sull’Adda (TR), Brescia (BS), Mantua (MN), Modena (MO), and along the Po River shaft (PO). Small (S.), medium (M.) and Large (L.). Winter (Win.; 1 January–20 March), spring (Spr.; 1 April–15 May), spring-summer (Spr.–Sum.; 16 May–15 June 15), summer (Sum.; 1 July–31 August), summer-autumn (Sum.–Aut.; 1 September–1 October) and autumn (Aut.; 2 October–31 November). Figure S1. Temporal evolution of SPM concentration (orange columns) in some pit lakes in the OR area (Po and Orba River Park) in relation to cumulative precipitation (blue polygons) in the 7 days prior to satellite acquisitions. The green line indicates the end of quarrying activities and the mean percentage decrease in SPM concentrations after that event. Figure S2. Temporal evolution of SPM concentration (orange columns) in some pit lakes in the BS area (Brescia) in relation to cumulative precipitation (blue polygons) in the 7 days prior to satellite acquisitions. The green line indicates the end of quarrying activities and the mean percentage decrease in SPM concentrations after that event. Figure S3. Temporal evolution of SPM concentration (orange columns) of MN-2 pit lake in the MN area (Mantua) in relation to cumulative precipitation (blue polygons) in the 7 days prior to satellite acquisitions. The green line indicates the end of quarrying activities and the mean percentage decrease in SPM concentrations after that event. Figure S4. Temporal evolution of SPM concentration (orange columns) of MO-5 pit lake in the MO area (Modena) in relation to cumulative precipitation (blue polygons) in the 7 days prior to satellite acquisitions. The green line indicates the end of quarrying activities and the mean percentage decrease in SPM concentrations after that event. Figure S5. Temporal evolution of SPM concentration (orange columns) of some pit lakes in the PO area (Po River shaft) in relation to cumulative precipitation (blue polygons) in the 7 days prior to satellite acquisitions. The green line indicates the end of quarrying activities and the mean percentage decrease in SPM concentrations after that event.

Author Contributions

Conceptualization, P.V., D.N. and M.B.; methodology, N.G., M.B. and M.P.; validation, N.G., M.B. and M.P.; formal analysis, N.G.; investigation, N.G.; data curation, N.G.; writing—original draft preparation, N.G.; writing—review and editing, N.G., M.B., M.P., D.N. and P.V.; visualization, N.G.; supervision, M.B. and P.V.; project administration, N.G. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

No public dataset was created for this study. Upon request, we are, however, available to provide any data.

Acknowledgments

This study is part of the PhD project by Nicola Ghirardi, PhD course in Evolutionary Biology and Ecology, cycle 36. This study is a contribution to the management of the UNESCO MaB Reserve “Po Grande”. We are grateful to Rossana Caroni for revising the English of the manuscript. We are grateful to Giorgia Andreoli and Nicole Rossi for their help during the field campaigns. We are grateful to Gruppo Bassanetti, Sabbie di Parma srl, Bike Park Malaspina, Bacchi spa, and Emiliana conglomerati spa for granting us permission to conduct sampling in their lakes.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Pit lakes (PLs) divided into the eight subsample areas (blue boxes). The Po River is highlighted in light blue, green dots represent active PLs, red dots represent ceased PLs, and yellow dots represent doubtful PLs (all those are lakes that have the typical characteristics of PLs but whose origin or end of mining is uncertain). Turin (TO), Po and Orba River Park (OR), Milan (MI), Trezzo sull’Adda (TR), Brescia (BS), Mantua (MN), Modena (MO), and the Po River shaft (PO).
Figure 1. Pit lakes (PLs) divided into the eight subsample areas (blue boxes). The Po River is highlighted in light blue, green dots represent active PLs, red dots represent ceased PLs, and yellow dots represent doubtful PLs (all those are lakes that have the typical characteristics of PLs but whose origin or end of mining is uncertain). Turin (TO), Po and Orba River Park (OR), Milan (MI), Trezzo sull’Adda (TR), Brescia (BS), Mantua (MN), Modena (MO), and the Po River shaft (PO).
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Figure 2. Scatterplots between in situ data (y-axis) and satellite data (x-axis). The black triangles and black squares represent comparisons between in situ and ACOLITE SPM concentrations from Landsat (L5 and L7, calibrated) and Sentinel-2 (S2) images, respectively. “n” represents the sample size, “R2” the determination coefficient, “MAE” the mean absolute error, “RMSE” the root mean square error, “MAPE” the mean absolute percentage error, and the dashed gray lines refer to the regression lines.
Figure 2. Scatterplots between in situ data (y-axis) and satellite data (x-axis). The black triangles and black squares represent comparisons between in situ and ACOLITE SPM concentrations from Landsat (L5 and L7, calibrated) and Sentinel-2 (S2) images, respectively. “n” represents the sample size, “R2” the determination coefficient, “MAE” the mean absolute error, “RMSE” the root mean square error, “MAPE” the mean absolute percentage error, and the dashed gray lines refer to the regression lines.
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Figure 3. Scatterplots between in situ WISP-3 data (y-axis) and Sentinel-2 data (x-axis). The colored dots represent comparison between WISP-3 and ACOLITE spectral signatures for the first six bands of S2. “n” represents the sample size, “R2” the determination coefficient, “MAE” the mean absolute error, “RMSE” the root mean square error, “MAPE” the mean absolute percentage error, and the dashed gray lines refer to the regression lines.
Figure 3. Scatterplots between in situ WISP-3 data (y-axis) and Sentinel-2 data (x-axis). The colored dots represent comparison between WISP-3 and ACOLITE spectral signatures for the first six bands of S2. “n” represents the sample size, “R2” the determination coefficient, “MAE” the mean absolute error, “RMSE” the root mean square error, “MAPE” the mean absolute percentage error, and the dashed gray lines refer to the regression lines.
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Figure 4. Mean SPM concentrations (A) and λdom (B) for subsample PLs for the period 1990–2021. The blue boxes represent the eight subsample areas. In the black boxes are the mean ± st.dev, and minimum and maximum SPM concentrations for each area.
Figure 4. Mean SPM concentrations (A) and λdom (B) for subsample PLs for the period 1990–2021. The blue boxes represent the eight subsample areas. In the black boxes are the mean ± st.dev, and minimum and maximum SPM concentrations for each area.
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Figure 5. Boxplots of SPM concentrations (left column) and dominant wavelength (right column) of pit lakes (PLs) in the subsample (mean values referring to 1990–2021). Shown from top to bottom are comparisons of PLs’ locations, PLs’ sizes, season (according to WFD protocol), and quarrying activity. For location, size, and season boxplots, both active (left) and ceased (right) PLs are represented. In each boxplot, the circles represent the outliers. The “p” values refer to the Kruskal–Wallis and the Mann–Whitney (for quarrying boxplots only) statistical tests. For the Kruskal–Wallis test, the significant difference between two pairs of categories (p < 0.05) is indicated by the lack of identical letters.
Figure 5. Boxplots of SPM concentrations (left column) and dominant wavelength (right column) of pit lakes (PLs) in the subsample (mean values referring to 1990–2021). Shown from top to bottom are comparisons of PLs’ locations, PLs’ sizes, season (according to WFD protocol), and quarrying activity. For location, size, and season boxplots, both active (left) and ceased (right) PLs are represented. In each boxplot, the circles represent the outliers. The “p” values refer to the Kruskal–Wallis and the Mann–Whitney (for quarrying boxplots only) statistical tests. For the Kruskal–Wallis test, the significant difference between two pairs of categories (p < 0.05) is indicated by the lack of identical letters.
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Figure 6. SPM concentration maps of pit lakes MI-30 (ceased) and MI-31 (active) from 2017 to 2021 referred to quarrying events. MI-30 (45.406015N, 9.237314E); MI-31 (45.403253N, 9.241183E). SPM concentration maps were obtained from Sentinel-2 Level 1 images, processed with ACOLITE (SPM_Nechad2016 algorithm).
Figure 6. SPM concentration maps of pit lakes MI-30 (ceased) and MI-31 (active) from 2017 to 2021 referred to quarrying events. MI-30 (45.406015N, 9.237314E); MI-31 (45.403253N, 9.241183E). SPM concentration maps were obtained from Sentinel-2 Level 1 images, processed with ACOLITE (SPM_Nechad2016 algorithm).
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Table 1. SPM concentrations (mean ± st.dev.) before and after the end of quarrying activity for the 13 pit lakes (PLs) examined (observation period: 1990–2021).
Table 1. SPM concentrations (mean ± st.dev.) before and after the end of quarrying activity for the 13 pit lakes (PLs) examined (observation period: 1990–2021).
PLsCoordinatesQuarrying ActivityBefore
(g m−3)
After
(g m−3)
SPM Reduction (%)
OR-445.161294N; 8.548939E1995–20129.7 ± 4.45.5 ± 3.6−43
OR-2245.031655N; 8.873921E2005–200818.1 ± 7.77.4 ± 3.9−59
OR-2545.070040N; 8.895304E2003–200719.8 ± 6.87.7 ± 3.2−61
BS-1145.378769N; 10.181337E2006–201217.3 ± 7.88.5 ± 4.8−51
BS-4245.464501N; 10.250156E<1990–200512.5 ± 5.75.8 ± 2.5−54
BS-4945.491103N; 10.263158E<1990–200711.6 ± 6.06.6 ± 3.2−43
MN-245.245806N; 10.699478E1999–200714.3 ± 7.97.3 ± 2.8−49
MO-544.673111N; 10.817644E2006–201420.4 ± 6.95.9 ± 2.6−71
PO-945.059638N; 9.775130E<1990–200915.0 ± 8.17.3 ± 3.0−51
PO-1445.155322N; 9.801703E2002–201219.4 ± 12.95.5 ± 1.9−72
PO-1745.141368N; 9.849019E2002–201216.9 ± 7.28.3 ± 3.2−51
PO-5444.911351N; 10.623380E1998–201220.4 ± 10.110.4 ± 5.4−49
PO-7744.861300N; 11.524369E<1990–200814.0 ± 5.97.0 ± 3.3−50
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Ghirardi, N.; Pinardi, M.; Nizzoli, D.; Viaroli, P.; Bresciani, M. The Long-Term Detection of Suspended Particulate Matter Concentration and Water Colour in Gravel and Sand Pit Lakes through Landsat and Sentinel-2 Imagery. Remote Sens. 2023, 15, 5564. https://doi.org/10.3390/rs15235564

AMA Style

Ghirardi N, Pinardi M, Nizzoli D, Viaroli P, Bresciani M. The Long-Term Detection of Suspended Particulate Matter Concentration and Water Colour in Gravel and Sand Pit Lakes through Landsat and Sentinel-2 Imagery. Remote Sensing. 2023; 15(23):5564. https://doi.org/10.3390/rs15235564

Chicago/Turabian Style

Ghirardi, Nicola, Monica Pinardi, Daniele Nizzoli, Pierluigi Viaroli, and Mariano Bresciani. 2023. "The Long-Term Detection of Suspended Particulate Matter Concentration and Water Colour in Gravel and Sand Pit Lakes through Landsat and Sentinel-2 Imagery" Remote Sensing 15, no. 23: 5564. https://doi.org/10.3390/rs15235564

APA Style

Ghirardi, N., Pinardi, M., Nizzoli, D., Viaroli, P., & Bresciani, M. (2023). The Long-Term Detection of Suspended Particulate Matter Concentration and Water Colour in Gravel and Sand Pit Lakes through Landsat and Sentinel-2 Imagery. Remote Sensing, 15(23), 5564. https://doi.org/10.3390/rs15235564

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