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uses macrophytes and related phytobiome to clean up environments. These technologies are environmentally friendly and cost-effective and do not require sophisticated equipment, to manage contaminated water (Krzeminski et al., 2019).

      1.7.1 Phytoremediation Techniques

Schematic illustration of various processes involved in phytoremediation of contaminants in aquatic environment.

      In aquatic systems, macrophytes promote the oxygenation of sediment and favour purification processes by enhancing and diversifying microbial activities through its rhizosphere. Moreover, various parts in macrophytes hyper-accumulate contaminants by absorption (phytoextraction) (Rulkens et al., 1998). Some macrophytes have the ability to consume and volatilize the contaminants directly into the atmosphere through the leaves. Phyto-volatilization process is cost effective in elimination contaminants from soils, groundwater, residues, and sludge (Girdhar et al., 2014). Rhizo-filtration involves adsorption and precipitation of the metal contaminants into the growth substrate surrounding the root zone. Moreover, macrophytes are in constant interaction with their phytobiome: their roots secrete specific exudates and compounds, which attract some specific microbial communities, and develop a thick coating or biofilm around them (rhizosphere). Because of its various physical- chemical conditions, creating various microbial growth niches, the rhizosphere accommodates various microbial consortia, and it can, even in surrounding aerobic conditions, host some anaerobic consortia, such as denitrifying, sulfate-reducing, and methanotrophic bacteria (Shahid et al., 2020b).

      1.7.2 Aquatic Phytobiome

      The phytobiome consists in the community of micro-organisms, fungi, protists, invertebrates, and other plants, in more or less mutualistic or symbiotic way, associated with plants (Leach et al., 2017). Unique physiological and anatomical adaptations in the root system of wetland plants exist, allowing them to exploit the light, water, and nutrients. The adapted wetland plant roots are surrounded by a rhizosphere, which attracts by its water, oxygen, and nutrients a myriad of wetland organisms. Phytobiome plays a major role in phyto-technology.

      1.7.3 Various Aquatic Plants Used

      Aquatic plants are plants whose entire life cycle is dependent on the aquatic environment (water or waterlogged soil). This category of plants includes algae, bryophytes, and some vascular plants that do not usually produce real roots because they can directly take the necessary nutrients from the water. Some of them produce rhizomes that store energy for the next season. Whether in the laboratory by hydroponic culture or in the field, various species of aquatic plants have been identified and recognized for their effectiveness in accumulating and degrading mineral and organic contaminants in water (Prasad, 2007). In order to achieve the best results in decontamination of pollutants the aquatic macrophytes should be selected upon their efficacy to accumulate dissolved nutrients, metals and other contaminants (Lu, 2009). The selected aquatic plants should be fast growing, easily to handle and to harvest (De Stefani et al., 2011). The severity of the pollution is another factor that might affect the success of a phytoremediation system. From a functional ecology point of view, a distinction is made between emergent, floating leaved, free-floating, and submerged aquatic plants. If emergent macrophytes are found in subsurface and surface-flow CWs, then the other types of macrophytes are exclusive to surface flow systems.

      1.7.4 Emergent Aquatic Plants

      Because of its large spread in natural habitats as well as its large use in CWs, P. australis is the emergent macrophyte, whose phenology has been probably the most extensively studied. Its yearly cycle begins with the start of growth, corresponding to start of the remobilization of resources (C, N, and P) stored in the rhizomes, when the accumulated degree days is high enough. Photosynthesis is taking place from the start of the growth, until the start of the senescence, after flowering. At that time, the resources are reallocated to the rhizomes and the plant starts decaying. The full decaying process is quite long (2 or more years), due to the silica content of the aboveground biomass [≈18 mg/g dry weight (Gao et al., 2019)]. By leaching of the decomposing litter, C, N, P, as well as minerals stored in the biomass are slowly released to the aquatic environment. Typha sp., P. arundinacea, Scirpus sp., and G. maxima are other groups of emergent plants, whose phenology is similar to Phragmites.

      1.7.5 Floating Leaved Aquatic Plants

      Floating-leaved macrophytes have roots and are anchored in the sediment. Water lilies or Nymphaeaceae are good examples of these rhizomatic plants, whose leaves are floating at the surface of the water. Their flowers can be emergent or floating.

      1.7.6 Floating Aquatic Plants

      Because of their ubiquitous or even invasive nature, their bioaccumulation capacity, and their resilience in a polluted environment, duckweeds are widely studied in phytoremediation (Ekperusi et al., 2019), especially the species L. gibba and L. minor (Mkandawire and Dudel, 2007). Duckweeds are known for their cold tolerance property (they can grow in all seasons), whereas water hyacinth (P. crassipes) can survive only in summer. Duckweeds can also propagate over wide pH range (Raskin et al., 1994). The biomass production of duckweed is rapid and it is largely used for exploiting the phytoremediation process when compared to other aquatic plants (Cunningham

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