1. Introduction
Municipal wastewater is typically treated using suspended or attached growth mixed bacterial cultures in activated sludge systems, trickling filters, membrane or moving bed biofilm reactors [
1]. New technologies are developing for removing complex emerging pollutants such as constructed wetlands, microbial fuel cells and phytoremediation. [
2,
3,
4,
5] Activated bentonite removes oil-solution green pigments from food-processing wastewater [
6]. BiOX/TiO2 heterojunctions were observed as an excellent photocatalytic decomposer of Perfluorooctanoic Acid [
7]. These processes achieve the efficient removal of organic matter and the safe disposal or reuse of treated wastewater [
8]. However, they are characterized by high operational costs, high energy consumption and sludge production, which is also a crucial contribution to global warming due to their increased on-site and off-site greenhouse gas emissions [
9]. As a result, an outsized scientific effort has been directed over the last decade toward the development of alternative cost-effective processes that deploy various microalgae species or different macrophytes in municipal wastewater treatment [
10]. Currently, one of the most attractive research areas is the development of eco-friendly and efficient technologies for waste water treatment, such as phytoremediation [
11]. Macrophytes were first recognized in water quality improvement during the 1960s and 1970s [
12]. Macrophytes are used in waste water treatment as an alternative approach to remove pollutants and produce valuable biomass [
13]. This is due to the serious problem of the contamination of aquatic environments by various pollutants in the world [
14]. The efficiency of phytoremediation observed was improved by the use of metal-binding proteins and microbes [
15]. Controlled growth of aquatic plants can be achieved by regular harvesting of these plants; the harvested aquatic plants can be further converted into fertilizer [
16].
Macrophytes may be categorized into four basic types that include freely floating, floating leave, emergent, and submerged. The floating leaf types’ roots become stagnant in the saturated media with their entire body above the water surface, the emergent kinds may be observed at a significant height above the water’s surface, have their roots planted in soil, and greatly stabilize substrate [
4]. Two macrophytes (i.e., water lettuce and duckweed plants) have been chosen for this study. To optimize the results, local macrophyte species are preferred, as they can tolerate the conditions of a particular region.
Free floating macrophytes viz. Salvinia, Lemna, Eichornia and Pistia showed their phytoremediation eventuality for the sanctification of waters from organic pollutants. The Lemna gibba used in the phytoremediation of numerous biochemical processes is similar to BOD, total suspended solids, ammonium nitrate and phosphate, ammonia and total nitrogen. Furthermore, Lemna minor has implicitly ameliorated the quality of water defiled with blue and textile colorings. It has the capability to remove answerable Pb, Ni. It has accumulation capability for Cd and Cr. Azolla caroliniana, a small water fern implicit to purify the waters defiled by mercury and chromium [
17]. The studies published by the main pollution authority of India, the Central Pollution Control Board (CBPC), revealed in 2013 the working condition and inadequacy of pollution treatment infrastructure in India [
18]. The Ex-Planning Commission has suggested developing “treatment zones” in city drains. The Government of India has given a very innovative approach, which needs to be strengthened further by scientific implementations by researchers who have mastered the technique of the eco-treatment of polluted waters [
19].
Water pollution is becoming a serious problem due to rapid population growth, lack of sustainable technology and poor management. In large cities, municipal wastewater from almost the entire city is discharged, along with commercial/industrial wastewater, into water bodies (rivers, runoff, canals, etc.) in the immediate vicinity of the city. As a result, the pollution levels in water bodies are increasing [
20]. Water lettuce and duckweed are commonly observed in various rivers in Pimpri Chinchwad Municipal Corporation (PCMC) area located in Maharashtra, India. In the last few years, an exponential growth of water lettuce and duckweed was observed in river water. The engulfing presence of water lettuce and Duckweed blocks the sunlight, prevents oxygen transfer and drops the dissolved oxygen levels. This may be the reason due to which PCMC spends large amounts for complete removal of macrophytes every year. As these are natural purifiers, there is a need to study the effect of complete removal of water lettuce and duck weed on water quality of rivers (before and after removal). Furthermore, the removal of floating macrophytes from river water will not curb its growth, and 100% diversion of waste water from going into the river is practically very difficult, as the infrastructure required for the same is not well planned. Therefore, a balanced solution to this problem is the need of the hour. Municipal wastewater contains a large variety of contaminants generated from various sources. The most probable pollutants include pathogens, oil and grease, metals, organic matter, solids, and nutrients such as nitrogen and phosphorus [
21].
In previous literature, researchers have used phytoremediation, bioremediation with or without baffled tanks, vertical flow, or horizontal flow mixing. In this research paper, the combination of modified flow patterns, which allows zig-zag flows in vertical as well as in horizontal directions, were used along with locally available floating macrophytes, i.e., water lettuce and duckweed, for the removal of organic impurities. This research is an attempt through which a model study has been carried out with three different experimental set-ups for comparison. The investigation of various pollutants of raw wastewater, as well as treated wastewater, have been carried out with due regard to the removal efficiency of set ups. The investigation was conducted to evaluate the % increase in Dissolved Oxygen (DO), % decrease in Biochemical Oxygen Demand (BOD), Chemical Oxygen Demand (COD) and Total Solids (TS) with respect to the % plant area coverage. At the end of the study, it will lead to selecting more appropriate treatment for such kinds of water bodies.
3. Results and Discussions
3.1. Dissolved Oxygen
The dissolved oxygen concentration of influents was observed to be 0.9 ± 0.2 mg/L to 2.13 ± 1 mg/L and the maximum increase in DO was observed to be 5.99 ± 0.3 mg/L for Set up A at a three day DT (detention time) for 50% area coverage. For Set up A, DO increase was less than Set up C. Set up C had no aquatic plants, therefore, the contact area of water and air was comparatively more. The DO increase in Set up C was observed more than 50% and 90% area coverage by water lettuce. Another reason for the DO increase might be modified flow pattern. Due to the provision of the zig-zag flow pattern, water at the bottom was moved at the surface and contacted with air directly, similarly, water at the surface with high DO moved towards the bottom and increased DO at lower portions of Set up C, as shown in
Figure 2. DO increase was significantly affected by DT (
p < 0.05); as DT increased, flow rate decreased and churning effect due to modified flow pattern also decreased. Therefore, in Set up A, B and C, ‘increase in DO’ is reduced with ‘increase in DT’. For Set up B, the maximum DO increased to 89.79 ± 12.5 at two days of detention time, which was slightly more than Set up C; this was due to roots and lower frond surface of leaves, as they provide oxygen [
27]. The DT and area coverage of aquatic plants inhibit an increase in DO [
27]. The DO increase of Set up B was observed as slightly more than or equal to Set up C.
Figure 4a shows the comparison of DO increases in Set up A, Set up B, and Set up C. For 50% aquatic plant coverage, Set up B had best efficiency at two days of DT. Set up C had good efficiency to increase DO comparatively more than Set up A and Set up C. As shown in
Figure 4b, for 90% area coverage, an increase in DO was observed lowest at a five day DT. In Set up A, it might be due to longer DT and low flow rate. Set up B had more efficiency than Set up A and C, as duckweed roots oxygenate water. No Set up had given effluent having DO less than 4 mg/L. An increase in DO improves the taste of water [
28]. Standard deviation is a popular measure of variability. DO shows low variability for Set up C, medium for Set up A, and high for Set up B, with respect to increase in detention time (
Figure 4) [
29].
3.2. Bio-Chemical Oxygen Demand
As compared with Set up C, BOD reduction by Set up A was observed to be 89.17% at four days detention time and 90% plant coverage. Awuah et al. used water lettuce with complete area coverage at seven days of DT; water lettuce reduced 93% of BOD from their bench scale plant [
30]. Comparatively, set up A had given good efficiency at less DT. It may be due to a modified flow pattern which increases DO in the system. Minimum BOD removal was observed to be 43.48 ± 26.7 mg/L to 24.66 ± 11.4 mg/L at four days of DT with 50% area coverage; it may be due to higher BOD concentration at the inlet (
Figure 5a).
For set up A, the BOD of influents and effluents observed in between 29.56 ± 9.5 mg/L to 43.48 ± 26.7 mg/L and 4.56 ± 3 mg/L to 24.66 ± 11.4 mg/L for 50% area coverage, respectively. According to disposal standards, all DTs were observed with less BOD3 concentration (<30 mg/L) for disposing treated waste water in inland surface water. Three days and five days of DT also satisfy the disposal standards given for STPs at metro Politian cities (<10 mg/L).
Similarly, for 90% area coverage, BOD of influents and effluents were observed between 46.53 ± 5.3 mg/L 56.8 ± 19.9 mg/L and 4.96 ± 0.4 mg/L to 8.07 ± 4.9 mg/L, respectively (
Figure 5b). According to disposal standards, all DTs were observed at less BOD concentration (<30 mg/L) for disposing treated waste water in inland surface water. They also satisfy disposal standards given for STPs at metro Politian cities (<10 mg/L).
For set up B, the BOD of influents and effluents observed between 29.56 ± 9.5 mg/L to 43.48 ± 26.7 mg/L and 4.42 ± 2.5 mg/L to 22.27 ± 7.6 mg/L for 50% area coverage, respectively. According to disposal standards, all DTs were observed at less BOD concentration (<30 mg/L) for disposing treated waste water in inland surface water. Five days of DT also satisfies the disposal standards given for STPs at metro Politian cities (<10 mg/L). For 90% area coverage, the BOD of influents and effluents observed between 46.53 ± 5.3 mg/L 56.8 ± 19.9 mg/L and 3.92 ± 2.2 mg/L to 26.04 ± 15.5 mg/L, respectively. According to disposal standards, all DTs were observed with permissible BOD concentration (<30 mg/L) for disposing treated waste water in inland surface water. Four days of DT also satisfy disposal standards given for STPs at metro Politian cities (<10 mg/L).
For five days of DT, there was a slight decrease observed in BOD removal in set up B with 90% coverage, due to limited oxygen transfer into water. Percentage removal efficiency was highest in set up A (MF+WL), followed by set up B and Set up C (MF) at 88.86% (DT-5 days) [
31], 88.59% (DT-5 days) and 48.23% (DT-2 days), respectively, for 50% area coverage. For 50% area coverage, there was a statistical significance (ANOVA) of treatment provided (F-49.24) and DT adopted (F-31.92) in percentage removal of BOD. Both parameters had significant interaction (F-7.54) at
p < 0.05.
For 90% area coverage, percentage removal efficiency was highest in set up B, followed by Set up A and Set up C at 91.5% (DT-4 days), 89.17% (DT-4 days) and 49.18% (DT-2 days), respectively. The combination of modified flow patterns and types of plants used (F = 69.89) and detention time (F = 5.76) had a significant impact on the removal process and significant interaction (F-5.77) at
p < 0.05. It also shows the contribution of plants for aeration of natural bodies to reduce contaminants [
23]. As shown in
Figure 5, for 50% plant area coverage, BOD shows low variability for Set up C, medium for Set up A and high for Set up B with respect to increase in detention time. For 90% plant area coverage, BOD shows low variability for Set up A, medium for Set up C and high for Set up B with respect to increase in detention time [
29].
3.3. Chemical Oxygen Demand
For set up A, COD of influent and effluent observed in between 55.05 ± 27.6 mg/L to 137.7 ± 71.4 mg/L and 15.8 ± 10.2 mg/L to 46.54 ± 15.4 mg/L for 50% area coverage respectively (
Figure 6a). For 90% area coverage, COD of influent and effluent observed in between 106.46 ± 26.8 mg/L 223.07 ± 131.7 mg/L and 21.55 ± 9.6 mg/L to 49.97 ± 60.7 mg/L respectively (
Figure 6b). According to CPHEEO disposal standards all DTs were observed permissible COD concentration (250 mg/L) for disposing treated waste water in inland surface water. They also satisfy the disposal standards given for STPs at metro Politian cities (<50 mg/L). As the COD Concentration was more than the BOD concentration, the sample contained a large number of organic compounds that were not easily biodegraded [
20].
In Set up A, the highest percent removal of COD was observed at 77.21% with 90% area coverage, followed by 50% area coverage, and the least at Set up C.
For Set up B, the COD of influents and effluents was observed between 55.05 ± 27.6 mg/L to 137.7 ± 71.4 mg/L and 23.75 ± 16.4 mg/L to 62.11 ± 38.2 mg/L for 50% area coverage, respectively. For 90% area coverage, the COD of influents and effluents was observed between 106.46 ± 26.8 mg/L 223.07 ± 131.7 mg/L and 36.69 ± 9.1 mg/L to 75 ± 59.2 mg/L respectively.
According to CPHEEO disposal standards, all DTs were observed at permissible COD concentration (250 mg/L) for disposing treated waste water in inland surface water. Three days, four days and five days of DTs also satisfy the disposal standards given for STPs at metro Politian cities (<50 mg/L).
In Set up B, the highest percent removal of COD was observed at 66.72% with 90% area coverage, followed by 64.71 with 50% area coverage and the least at 47.16% modified flow pattern without aquatic plants. The growth of macrophytes such as, water lettuce and duckweed, showed high performance in removing COD, mainly due to a well-developed root system. Micro-organisms present in the water establish a symbiotic relation to the aquatic plants; this contributes to degradation of COD [
20]. As shown in
Figure 6a,b, Set up A has the highest COD removal followed by Set up B and Set up C for two days, three days, four days and five days of DT.
For 50% area coverage, the significance of the treatment provided in Model A, B and C and DT has been analyzed by using ANOVA at 95% confidence level for both cases, i.e., 50% and 90% area coverage. For 50% area coverage, the combination of the modified flow pattern and type of plant used (F = 11.17) had a significant impact on the removal of COD, with no significance of DT at p < 0.05. Similarly, for 90% coverage, Set up A has highest COD removal followed by Set up B and Set up C for two days, three days, four days and five days of DT. For the 90% area coverage, treatments given in set ups had a significant impact (F = 39.55) on the removal of COD with no significance of DT at p < 0.05.
As shown in
Figure 6, for 50% and 90% plant area coverage, COD shows low variability for Set up A, medium for Set up B and high for Set up C with respect to increase in detention time [
29].
3.4. Total Solids
Total solids represent the summation of total dissolved solids and total suspended solids. Regular monitoring of total solids (TS) may detect trends. Water lettuce growth decreased the salts from the waters by plant uptake or root adsorption, and it was concluded that the water quality in ponds was improved by phytoremediation with water lettuce, as evidenced by total solids [
32]. For Set up A, the TS of influents and effluents observed between 463 ± 55 mg/L to 635 ± 165 mg/L and 340 ± 63 mg/L 445 ± 32 mg/L for 50% area coverage, respectively. For 90% area coverage, the TS of influents and effluents observed between 531 ± 75 mg/L 613 ± 179 mg/L and 358 ± 89 mg/L to 514 ± 45 mg/L, respectively.
In Set up A, the highest TS removal was observed at three days of DT with 50% area coverage, followed by three days of 90% area coverage, and the least was at two days without aquatic plants in Set up C (
Figure 7a,b). In Set up B, the highest TS removal observed at two days of DT with 50% area coverage, followed by three days of 90% area coverage, and the least was at two days without aquatic plants in Set up C. The TS of influents and effluents observed between 463 ± 55 mg/L to 635 ± 165 mg/L and 365 ± 34 mg/L 439 ± 40 mg/L for 50% area coverage, respectively. For 90% area coverage, the TS of influents and effluents observed between 531 ± 75 mg/L 613 ± 179 mg/L and 393 ± 60 mg/L to 471 ± 64 mg/L, respectively. The significance of treatment provided in Set up A, B, C and DT was analyzed by using Two Way ANOVA at 95% confidence level for both cases, i.e., 50% and 90% area coverages. The author does not have enough evidence to say that the treatment provided in set up and DT were statistically significant in percent removal of total solids. As
p = 0.2 > 0.05, the author failed to reject the null hypothesis. For 90% area coverage, detention time had a significant impact (F = 4.29) on the removal of total solids with no significance of treatment given in set up at
p < 0.05. For 50%, as well as for 90% area coverage. As per
Figure 7a,b, the highest TS removal was observed in Set up A, followed by Set up B and Set up C. For 50% and 90% plant area coverage, TS shows low variability for Set up B, medium for Set up C and high for Set up A with respect to increase in detention time [
29].
3.5. Roll of Macrophytes in Experimental Set Ups for Removal of Pollutant
The macrophytes played very important role in the removal of pollutants. It is achieved by the ability to undergo a phenomenon known as phytoremediation. During the photosynthesis process, roots absorb water, it is split into the protons and the oxygen molecule by the process of photolysis. Therefore, these plants have a root zone which maintains comparatively high dissolved oxygen. It results in the symbiotic relation of micro-organisms and plants. Micro-organisms utilize the oxygen for their survival and biodegraded the organic matter [
20]. They need nutrients like nitrogen, phosphorus and potassium for their growth. These nutrients are present in wastewater in the form of organic impurities. The plants utilize these nutrients, and due to this, there were reductions in BOD, COD and TS. In present study, the length of the roots observed for water lettuce and duckweed were 10 cm to 15 cm and 2 cm to 8 cm, respectively. As the depth of wastewater in set-up was kept constant for both plants, percentage removal for BOD, COD and total solids were observed comparatively more in Set-up A containing water lettuce. In Set-up C (without macrophytes), the observed percentage removal of BOD, COD and TS was lowest. Phytoremediation is very promising technology, successfully removing heavy metals like cadmium from wastewater [
33].
4. Conclusions
Aquatic plants (water lettuce and duckweed) and the associated microorganisms are those from the surrounding habitat, hence, already adapted to the sewage. These plants have shown rapid growth throughout the study period; the growth at the first pot was observed fast, and plants were seen healthy as compared to the last pot of experimental set ups. This system, with 90% plant coverage and four days of detention time, removes 89% BOD, 77% COD with water lettuce and 91% BOD, 66% COD with duckweed. The combination of water lettuce and modified flow pattern treatment is recommended for the restoration of polluted streams, which are currently disposing untreated waste water in rivers. After treatment, treated wastewater will act as dilution water when it is mixed with river water, and the pollution load of rivers will be reduced. As compared with the conventional wastewater treatment, this treatment is cost effective, easy to set up, and requires low maintenance. For the prediction of the efficiency of experimental set ups, mathematical modeling using the appropriate methods is highly recommended.