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Introduction
Wetlands include a wide range of aquatic habitats such as marsh, fen, peat land/open water, flowing water (rivers and streams) or static (lakes and ponds). These ecosystems being the transition zone between land and water are ecologically important in relation to stability and biodiversity of a region and also in terms of energy and material flow. These ecosystems perform a vital function of uptake of nutrients and bioremediation of heavy metals, volatile organics and other xenobiotic compounds and are aptly referred as “Kidneys of the landscape”. They also aid in recharge of groundwater aquifers and stabilization of shorelines (Ramachandra and Bharath 2015). These transitional zones or ecotonal region are repository of rich biodiversity and support food chain. Wetlands act as giant sponges, which help in slowing runoff, lower flood heights, reduce shoreline and stream bank erosion. The functional ability of wetlands is dependent on the type of trophic structure and material exchange. The trophic structure includes various trophic levels as producers (algae, etc.), primary consumers (zooplanktons and grazers), secondary consumers (small fish), tertiary (large fish, birds, etc.). Algae being the primary producers synthesize carbohydrates during photosynthesis and give out oxygen along with the production of other essential metabolites. Bulk of the CO2 gets sequestered into algal biomass in these wetlands systems that aids in combating global warming through reductions of GHG (Greenhouse gases) in the environment. However the stability of every system depends upon the balance between production and consumption of energy and matter at different trophic levels in any system. The functional aspects of wetlands are tied to the tradeoff between the ecosystem function and the anthropogenic impact that makes it very sensitive and delicate. Human impacts include altering the catchment (changes in land cover), encroachment, solid waste disposal in lake beds, sustained inflow of untreated sewage from urban localities, etc. (Ramachandra and Bharath 2015; Ramachandra 2001, 2009a, 2009b, 2010; Ramachandra et al. 2003, 2018a).
Bangalore had flourished during 19th and early 20th century owing to a salubrious microclimate and abundance of water in the city of lakes. Globalisation, liberalization, privatization are the agents fuelling urbanization in most parts of India during early 1990’s. Consequences of the unplanned urbanisation are enhanced pollution levels, lack of adequate infrastructure and basic amenities. This is evident in Bangalore with severe scarcity of water, frequent flooding, enhanced pollution levels, uncongenial buildings, mismanagement of solid and liquid wastes, etc. Increased and unprecedented population growth has resulted in enormous stress on potable water from a daily consumption point of view and also in regards to increased wastewater generated by the city. Unplanned growth has led to radical land use conversion of forests, surface water bodies, etc. with the irretrievable loss of land resources (Ramachandra et al. 2013a). Land use analyses show 1028 percent growth in built-up area during the last four decades with the decline of vegetation by eight-eight percent and water bodies by seventy-nine percent (Ramachandra et al. 2017; Ramachandra and Bharath 2016). Analyses of the temporal data reveals an increase in urban built up area of 342.83 percent (during 1973 to 1992), 129.56 percent (during 1992 to 1999), 106.7 percent (1999 to 2002), 114.51 percent (2002 to 2006) and 126.19 percent from 2006 to 2010 (Ramachandra et al. 2009a, 2012a; Bharath et al. 2018).
Rapid urbanization in recent times has led to the large scale generation of wastewater. Untreated or partially treated wastewaters are fed to surface water that finds its way into ground water sources. The sustained inflow of untreated or partially treated sewage to wetlands leads to the enrichment of nutrients such as nitrogen (N) and phosphorus (P), evident from the algae bloom and profuse growth of macrophytes. This has led to the contamination of existing water resources with pathogens and nutrients resulting in algal bloom due to eutrophic status of surface water.
Cauvery River caters to only fifty-five percent of over 9 million population and balance is met through groundwater. Bangalore city is facing severe water shortages today due to insufficient piped supply coupled with the fast decline of groundwater table. Plummeting groundwater table is due to poor infiltration because of increasing paved surface and also over exploitation. Sustained inflow of untreated sewage to lakes has also contaminated nearby groundwater sources (Department of Mines and Geology 2011; Government of India 2008) affecting the human health. Nitrogen as nitrate-N pollution leads to physiological disorders including blue baby syndrome (methemoglobinemia) and the persistent assimilation of nitrate rich water leads to carcinogenic symptoms (as nitrates get reduced in the body forming nitrosamines, which are carcinogens). Macrophytes grow profusely in these nutrient rich environments and progressively cover the entire surface of the water body hindering the passage of sunlight and diffusion of gases to the underlying water layers. Absence of sunlight affects trophic levels with the reduced algae and photosynthetic O2 generation depleting the dissolved oxygen concentration and hence affects the local biota. This study explores the feasibility of bioremediation path to treat wastewater for reuse and mitigate the water crisis in the city (Mahapatra et al. 2018; Ramachandra et al. 2018a).
Wetlands are the regional ecological barometers reflecting the health of a region due to the ecosystem services such as regulating the regional micro-climate (Ramachandra and Kumar 2010; Ramachandra and Bharath 2014), recharging groundwater aquifers (Government of India 2008), thereby influencing the life of the people adjacent to it. The city landscape (in the current spatial extent of 741 sq.km) had enjoyed 1452 interconnected water bodies in 1800 catering the domestic and irrigation water demand and now there were 193 wetlands (Ramachandra et al. 2017; Ramachandra and Kumar 2008, 2010). Urban water bodies are prone to an increased anthropogenic stress in recent times due to dumping of solid waste, encroachment of wetlands, sustained inflow of domestic sewage and industrial effluents leading to poor water quality with a very frequent algal blooms and rapid macrophyte growth with periodic successions (Mahapatra et al. 2011a, 2011b, 2018; Raj 2013). Influx of partially treated and untreated sewage has resulted in overgrowth, ageing, and subsequent decay of macrophytes creating anoxic conditions and devouring the system from life giving oxygen. This has impacted the food chain and hence the ecological integrity of the system.
Bangalore city is located on two ridges (North-Northeast and South-Southwest) with three watersheds (Hebbal-Nagavara, Koramangala-Bellandur, Vrishabhavathi). Northern and eastern parts of the city are with gentle slopes, while southern and western parts are very rugged undulating terrain of the region has helped in the creation of interconnected water-bodies to meet the domestic and irrigation requirements during the pre-colonial period. These interconnected drainage system is supposed to transfer the storm water from one water-body to another, started receiving sewage with rapid population growth and lack of appropriate sewage treatment systems. Population in Bangalore has increased from 5.6 million (2001) to 9.5 million (2011). Population increase has led to large quantum of sewage influx into wetlands leading to contamination of wetlands and associated groundwater systems.
Collapse of land regulation is evident during the past two decades due to large scale unauthorized occupation of open spaces (wetlands, grasslands, parks) by the influential section of the society in collusion with the bureaucracy. Large scale land conversion of common lands to built-up in recent times further substantiates the nexus (Ramachandra et al. 2017; Ramachandra and Bharath 2016; Ramachandra et al. 2007; Ramachandra and Sudhira 2007). Changes in the land cover have altered the regional hydrology evident from frequent floods, conversion of perennial wetlands to seasonal wetlands and decline of groundwater table. However, authorities have kept some wetlands alive by diversion of sewage, which flows consistently and maintains the water levels in the system of interconnected lakes.
Water Supply in Bangalore:
Water is being pumped from Cauvery River ~100 km from the city with an electricity requirement of 75-100 MW. Bangalore is located at higher elevation (900 m above mean sea level) and Cauvery river courses are at 500 m above mean sea level. This exercise suffices the need for approximately fifty-five percent of Bangalore city dwellers, while the rest are dependent on ground water and unauthorized drinking water supplies. Arkavathy River, with two reservoirs at Hesaraghatta (built in 1894, now dry) and Tippagondanahalli (built in 1933) insignificantly and irregularly contribute to a small fraction of the demand (30 MLD). The Chamrajasagar reservoir at Thippagondanahalli (or TG Halli reservoir), located at the confluence of the Arkavathy and Kumudavathy rivers, receives inflow mostly from the Kumudavathy but with a low flow rate (Lele et al. 2013; Ramachandra and Solanki 2007; Sawkar 2012). Water demand in Bangalore is roughly about 150 liters per day (lpd) per person and the total water requirement for domestic purposes is about 1, 400 million liters per day (MLD). Water available from Cauvery (Stages I to IV, Phase I) and Arkavathy (Hesarghatta and Tippagondanahalli reservoirs) rivers is about 975 MLD. The loss of water during transportation and distribution is about thirty percent. The surface meets about sixty percent of the city demand while the significant portion is met from groundwater sources (39%) and zone –wise details are indicated in Table 1 and Fig. 1. Zone wise water share from Cauvery (compared to groundwater usage) ranges from forty-three percent (south Bangalore), fifty-five percent (west Bangalore), sixty percent (south east Bangalore), sixty-three percent (central Bangalore), seventy percent (north Bangalore) and seventy-seven percent (east Bangalore).
Due to insufficient water from Cauvery River, most of the new city municipal councils and town municipal council (merged with Bangalore city, in the formation of BBMP) are dependent on groundwater sources. A rapid increase in the number of groundwater wells in Bangalore, was observed over the last three decades from 5,000 to around 4.08 lakh. It is estimated that forty percent of population of Bengaluru are dependent on 750 MLD of ground water, which is extracted every day. According to the CGWB (Central Ground Water Board), between 2001 and 2007, the water level in Bengaluru has declined by 7 meters (m) at the rate of about 1m per year. Over exploitation of groundwater coupled with minimal recharge due to changes in land over (increase in paved surface with the loss of vegetation and water-bodies) has led to decline in groundwater table (as high as 500 to 600 m), evident from the prevalence of gray, dark and over-exploited groundwater blocks in the major part of Bangalore.
Communities are dependent on wetlands for food, domestic, agricultural and industrial requirements. The economic benefits from wetlands to the society are in the form of water supply, commercial fisheries, agriculture, energy resource, wildlife resource, recreation, tourism, cultural heritage, biodiversity, etc. (Ramachandra et al. 2011). The myriad ways, in which wetlands are used, along with the numerous anthropocentric activities, have stressed wetlands in diverse ways. This has altered the wetlands quality disrupting its natural functions. Anthropogenic activities include direct physical destruction (drained for agricultural and developmental activities), siltation (soil erosion and removal of vegetative cover) and pollution from both point sources (municipal sewage and industrial effluents) and non-point sources (urban and agricultural runoffs) within the watershed (Ramachandra and Rajinikanth 2003).
Treatment and disposal of wastewater generated in the neighbourhood constitute key environmental challenges faced in urban localities due to burgeoning population in the recent decade. Nutrient laden wastewater generated in municipalities is either untreated or partially treated and is directly fed into the nearby water bodies regularly, resulting in nutrient enrichment resulting in algal blooms. Conventional wastewater treatment options are energy and capital intensive apart from their inability to remove nutrient completely. In this backdrop, algal processes are beneficial and remove nutrients with carbon sequestration and resultant biomass production. Algae grows rapidly and uptake nutrients (C, N and P) available in the wastewater (Ramachandra et al. 2018a, b, 2013a; Mahapatra et al. 2013a) and hence are useful in nutrient remediation. Treatment of sewage and letting into wetlands would help in further treatment (removal of N, P and heavy metals). This also prevents contamination of groundwater resources. Thus wetlands provide a cost effective option to handle sewage generated in the community and also helps in addressing the water crisis in the region.
Microalgae and native macrophytes of the wetlands help in the treatment due to abilities to uptake nutrients and heavy metals. Techniques have been developed for exploiting the algae’s fast growth and nutrient removal capacity (Larsdotter 2006; Oswald 1988). The nutrient removal is basically an effect of assimilation of nutrients as the algae grow. Also, nutrient stripping happens due to high pH induced by the algae as in ammonia volatilization, phosphorus precipitation, etc.
Constructed Wetlands with Algal Pond as Wastewater Treatment Systems
Wetlands aid in water purification (nutrient, heavy metal and xenobiotics removal) and flood control through physical, chemical and biological processes (Ramachandra et al. 2018a). When sewage is released into an environment containing macrophytes and algae a series of actions takes place. Through contact with biofilms, plant roots and rhizomes processes like nitrification, ammonification and plant uptake will decrease the nutrient level (nitrate and phosphates) in wastewater (Garcia et al. 2010). Algae based lagoons treat wastewater by natural oxidative processes. Various zones in lagoons function equivalent to cascaded anaerobic lagoon, facultative aerated lagoons followed by maturation ponds (Mahapatra et al. 2011b; Garcia et al. 2001, 2010). Microbes aid in the removal of nutrients and are influenced by wind, sunlight and other factors (Ramachandra et al. 2018a; Mahapatra et al. 2011b, 2013a, b).
Nutrients as Source of Contamination
The conventional wastewater treatment systems (sewage treatment plants - STP) are expensive and require input of external energy sources (for example, electricity, organic carbon) and chemical additives. These treatment systems generate concentrated waste streams necessitating environmentally sound disposal.
There is an urgent need to develop innovative, environmental friendly and cost effective sustainable technologies for treating sewage generated in the community every day. Untreated sewage leads to the neighborhood contamination of land and water resources (groundwater). An easy way to check the sewage contamination is to test the level of nutrients (nitrates and phosphates). Nitrate is a substance that develops from organic waste. Algae convert nitrate into organic compounds (proteins, lipids) through photosynthesis in the presence of sunlight. Algae can exhibit growth rates that are higher than other plants due to their extraordinarily efficient light and nutrient utilization. By taking advantage of rapid availability of nutrient enriched water, high solar intensity and favorable microclimate for algal growth, higher densities of algae can be grown continuously that provides ample biomass and at the same time treat wastewater within a short period of time.
Algal bacterial symbiosis is very effective in these tropical conditions. Algae, the primary producers generate O2 (during photosynthesis) which aid in the efficient oxidation of organic matter with the help of the chemo-organotrophic bacteria. The type and diversity of the algae grown are potential indicators of treatment process (Morro et al. 2012; Mahapatra et al. 2013a, b; Mahapatra et al. 2014; Ganapati and Amin 1972) and bacterial system disintegrates and degrades the organic matter providing the algae with an enriched supply of CO2, minerals and nutrients.
Focus of the current research is to assess the efficacy of integrated treatment system of wetlands with algal pond at Jakkur lake. This has been done through water quality assessment (physicochemical analysis) at various stages of the integrated wetland system consisting of sewage treatment plant (10 MLD), wetlands (with macrophytes), algal pond and Jakkur lake. Nitrate and phosphate levels were monitored at various stages of wetlands ecosystem.
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