Feb 26, 2018

Data application of the month: Water quality monitoring

Different sensors mounted on satellites and other platforms, such as airplanes, measure the amount of radiation at various wavelengths reflected from the water’s surface.

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Data application of the month: Water quality monitoring

What is the importance of water quality monitoring?

In order to consider water suitable for human consumption and for water to support proper ecosystem functionality or services, the physical, chemical and biological conditions have to meet certain requirements. Water quality is measured by several factors such as the concentration of dissolved oxygen, bacteria levels, the amount of salt (or salinity) and the amount of material suspended in the water (turbidity). In some water bodies, the concentration of microscopic algae and quantities of pesticides, herbicides, heavy metals, and other contaminants may also be measured to determine water quality. Despite scientific measurements for water quality, it is still very difficult to say if water is “good” or “bad”, therefore, the quality determination is made in relation to the purpose or need of the water.

How is water quality monitored from space?

Water has specific reflectance characteristics (measured at different wavelengths of light, so-called spectra), based on the scattering and absorbing properties of their optically active constituents. These are directly or indirectly related to relevant water quality parameters (indicator) such as turbidity and suspended matter, phytoplankton and its main pigment chlorophyll, detritus, salinity, total phosphorus (TP), Temperature, pH and dissolved colored organic matter. With the knowledge of their optical characteristics, it is possible to retrieve quantitative values of the concentrations for these water constituents, solely based on the reflectance of light measured by satellite sensors. Different sensors mounted on satellites and other platforms, such as airplanes, measure the amount of radiation at various wavelengths reflected from the water’s surface.

Measuring the amount of material suspended in the water (turbidity)

Water turbidity is an optical property of water, which scatters and absorbs the light rather than transmit it in straight lines. Turbidity from satellite measurements is determined by measuring the backward scattering of light between 450 and 800nm. It is a key parameter of water quality and is linearly related to the backward scattering of light by organic and inorganic particles in the water. It is also linearly related to total suspended matter (TSM) for low to moderate turbidity values. The measurement unit is Formazine Turbidity Unit [FTU], which is similar to the Nephelometric Turbidity Unit [NTU]. 1FTU corresponds to 0.0118/m backscattering at 550nm.

Combination/ Single Bands Sensor
Ratio between blue (0.40–0.50 μm) and red (0.60–0.70 μm Landsratios and ROBA-CHRIS, IRS-LISS-III
Ratio between green (0.50–0.60 μm) and red (0.60–0.70 μm) Landsat 5-TM, AISA
Ratio between near infrared (NIR) and red (0.60–0.70 μm) MODIS, ALOS-AVNIR-2
Near Infrared (0.75–0.90 μm) SPOT, Landsat 7-ETM+, CASI
Red (0.60–0.70 μm) Landsat 7-ETM+, Landsat 5-TM, HICO,
Green (0.50–0.60 μm) Landsat 5-MSS, IRS-LISS-III
Chlorophyll-a harmful algae bloom indicator (phytoplankton and cyanobacteria: phycocyanin, phycoerythrin)

Algal blooms, which are often driven by eutrophication phenomena in freshwater, are directly related to chl-a concentration since it is essential for photosynthesis Chl-a is used in oxygenic photosynthesis and is found in plants, algae, and cyanobacteria. Chl-a while mainly reflecting green, absorbs most energy from wavelengths of violet-blue and orange-red light, whose reflectance causes chlorophyll to appear green. The prominent scattering-absorption features of chl-a include strong absorption between 450–475 nm (blue) and at 670 nm (red), and reflectance reaches to peak at 550 nm (green) and near 700 nm (NIR), the reflectance peak near 700 nm and its ratio to the reflectance at 670 nm have been used to develop a variety of algorithms to retrieve chl-a in turbid waters (Gitelson 2008).

Chlorophyll, measured in [µg/l], is provided as a measure that is linearly related to the pigment-specific absorption at 440nm, with 1μg/l chlorophyll corresponding to 0.035/m pigment absorption.

On 1 May 2016, the Sentinel-2A satellite captured an algal bloom close to Belgium’s coast. Thanks to the multispectral capabilities of Sentinel-2’s main instrument, chlorophyll a absorption and hence concentration can be derived, revealing an intense phytoplankton near the Port of Ostend. Images: Contain modified Copernicus Sentinel data (2016), processed by RBINS.
Spectral Bands Combination Sensor
Ratio between green (0.50–0.60 μm) and red (0.60–0.70 μm Landsat 5-TM.Landsat 5-MSS, Landsat 7-ETM+, SPOT, IRS-LISS-III
Ratio between near infrared (NIR) and red Landsat 5-TM, HICO, PROBA-CHRIS, MODIS, MERIS, ALSA
Ratio between green and blue (B2/B1) Landsat 5-TM, Landsat 7-ETM+, MERIS, PROBA-CHRIS, EO-1 Hyperion,
Ratio between blue (0.40–0.50 μm) and red (0.60–0.70 μm) Landsat 5-TM, Landsat7-ETM+
Blue (0.40–0.50 μm) Landsat 5-TM
Red (0.60–0.70 μm) PROBA-CHRIS, Landsat 5-TM, CASI
Green (0.50–0.60 μm) Landsat 5-TM
Colored dissolved organic matters (CDOM) and inorganic substances
Colored dissolved organic matters, also called gelbstoff and gilvin, consists of naturally occurring, water-soluble, biogenic, heterogeneous organic substances that are yellow to brown in color (Aiken 2005). There is a very strong overlap in the absorption frequency of CDOM and chlorophyll the wavelength 443nm, due to this chlorophyll value inversion of remote sensing data provides an efficient method to estimate CDOM concentration within a large spatial and temporal scale with the assumption that CDOM covaries with chlorophyll (Hoge et al 1995).

To estimate Total Absorption (ABS), for example, absorption of light by particulate and dissolved organic and inorganic matter is measured. The relative contribution of inorganic absorptions varies for changing specific inherent optical properties (SIOPs), which are monitored within the retrieval algorithms. The unit is absorption at 440nmin [1/m]. The total absorption product includes the absorption of organic and inorganic components, which are not shown separately at this portal. In ocean color studies, CDOM absorption properties, for example, its absorption coefficients at 440 nm, are usually used as a representative of CDOM concentration.

Spectral Bands Sensor
Single blue band (0.40–0.50 μm) Landsat 5-TM, EO-1 Hyperion, SeaWiFS + MODIS-Aqua, HICO, CZCS
Ratio between blue (0.40–0.50 μm) and green (0.50–0.60 μm) ALOS-AVNIR-2, MODIS, SeaWiFS
Ratio between green (0.50–0.60 μm) and red (0.60–0.70 μm) MODIS, HICO, EO-1 ALI, EO-1 Hyperion, SeaWiFS, MERIS
Water temperature
This is an important parameter for the physical and biochemical processes occurring within water as well as in air-water interactions because temperature regulates physical, chemical, and biological processes in water. Thermal Infrared bands can measure the quantity of infrared radiant heat emitted from the radiant temperature of water bodies.

Remote measurements of water temperature can be obtained with a sensor that detects thermal radiation (3–5 and 8–14 μm wavebands) emitted from the upper 0.1 mm of the water surface (Atwell 1971, Anderson 1983). The emitted TIR radiation (3–14 μm) is a well-established practice, particularly in oceanography where daily observations of regional and global sea-surface temperature (SST) are made from satellites at the accuracy of 0.5°C, passive microwave techniques are used in cloudy areas with an accuracy limit of about 1.5–2 °C.

Common satellite sensors applied in sea surface temperature TIR band of Landsat sensors (TM, ETM+, and OLI/TIRS), TIR band of MODIS, TIR band of ASTER, TIR band of AVHRR, TIR band of airborne MODIS/ASTER (MASTER) and microwave radiometers (MWRs).

Salinity, dissolved oxygen, and total phosphorus
The salinity of the sea surface is an important factor determining the density of the seawater and could be monitored through remote sensing using Moisture and Ocean Salinity satellite (SMOS), it employs the Microwave Imaging Radiometer using Aperture Synthesis (MIRAS), as the primary instrument on the SMOS sensing at wavelengths (20–30 cm), Aquarius is another salinity-related sensor that provides sea surface salinity at global resolution; Total phosphorus is an indicator of plant nutrient availability in water bodies, which could promote eutrophication. Total phosphorus is monitored withing spectral bands combination Blue (0.45–0.51 μm) and green (0.50–0.60 μm) bands, and integration of red (0.60–0.70 μm) and green (0.50–0.60 μm) bands available on Landsat 5-TM, MODIS, PROBA-CHRIS, CASI, and SPOT sensors

How can I access space-based information for water quality monitoring?

A large variety of data could be used for water quality monitoring as listed in the table below which includes a wide variety of bands spectrum and sensors. Through the recently published UNESCO-IIWQ World Water Quality Information and Capacity Building Portal, it is now possible to monitor water quality without starting from scratch and computing the raw data.

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