Constructed Wetlands as a Natural Resource for Water Quality Improvement in Malaysia ()
1. Introduction
In wet equatorial countries with high intensity rainfalls, stormwater runoff has not only caused severe flooding but also pollution of surface waters [1] [2] . Consequently, issues related to stormwater runoff have become one of the priority agendas of government and non-government sectors, local authorities, agencies and developers all around the world in order to solve the problems of urban runoff and water pollution in rapidly urbanizing areas. Urban runoff and subsequent pollution have serious effects on water resources that need to be addressed [3] . Urban stormwater runoff is well recognized as one of the major source of pollution that could adversely affect water quality if the runoff is discharged untreated. Another impact from stormwater runoff is habitat-destroying, which can cause harm to many wildlife population such as fish and birds, and also can kill the native vegetation, which is the primary building in the pyramid chain. Malaysia is taking a proactive step by implementing a new Urban Drainage Manual in 2000 known as Urban Stormwater Management Manual for Malaysia (MSMA) [4] . A pilot project, entitled Bio-Ecological Drainage System (BIOECODS), was carried out at Universiti Sains Malaysia (USM) Engineering Campus based on 1st Edition of MSMA and the design was continuously improve in the 2nd Edition of MSMA. A constructed wetland which is one of the components in BIOECODS was built in order to provide ecological and biological stormwater treatment after purification through infiltration in swale and settling in wet pond and detention pond. The aim of the present study is to investigate the performance of constructed wetland in BIOECODS system for water quality treatment from stormwater runoff as well as the performance from species and biodiversity composition.
2. Material and Methods
The constructed wetland in this study is located in the Universiti Sains Malaysia (USM) Engineering Campus, lies between latitudes 100˚29.5'South and 100˚30.3'North and between longitudes 5˚9.4'East and 5˚8.5'West. In this study, seventeen sampling stations were identified and chosen as the study sites (Figure 1). The sampling area consists of Inlet Wetland (Inlet Wet) which is located at the inlet wetland, Wetland 1 (W1) located on the right bank and Wetland 2 (W2) located on the left bank, after the inlet wetland. For the Wetland 3 (W3), 4 (W4), 5 (W5) and 6 (W6), the station located in the middle of wetland, with W3 and W5 located right bank and W4
Figure 1. Sampling stations in the study area of constructed wetland USM.
and W6 at the left bank. The area from Inlet Wetland until Wetland 5 and 6 are called Macrophyte Zone. The Micropool was divided into three rows (Micropool (M); MA, MB, MC) and each row consists of 3 equal distances (15 meter) point of station. The sampling station was chosen based on the consideration of certain numbers of aspects such as type of macrophyte or wetland plants and range of water depth. Different depth affects settlement process, treatment of water quality and distribution of biodiversity. Different wetland plants and densities of plant affect the treatment and nutrient uptake process. Figure 2 shows the cross section and range of depths of stations in USM Wetland.
Basically, the wetland was design based on 3 month ARI [5] . The general design criteria of constructed wetland can be seen in the Table 1 and Table 2 below shows type of macrophyte present at the macrophyte zone (W1 - W6). The design criteria are based on Stormwater Management Manual for Malaysia (MSMA).
Sampling procedure was separated into two procedures, biological sampling and water quality sampling. Three types of species or indicators [6] had been chosen to study the biodiversity; phytoplankton, zooplankton, freshwater fish. The water samples were collected using grab sample. The in-situ parameter was taken at the sampling stations during the sampling. The parameters that involved are the physico-chemical parameter including temperature, pH, dissolved oxygen and conductivity. The nutrient parameter, duplicate bottles were used to run the analysis in the lab. The types of analysis were total suspended solid (TSS), nitrite, nitrate, ammoniacal nitrogen NH3-N, biochemical oxygen demand (BOD), chemical oxygen demand (COD), and Ortho-phosphate.
Figure 2. Cross section and range of depth of station in USM Wetland.
Table 1. Design criteria for the constructed wetland, USM.
Table 2. Wetland plant in macrophyte zone.
3. Results
Water Quality
Table 3 showed the mean and range value for each parameter measured at 17 sampling stations starting from December 2010 until December 2011. The standard deviation varied for each parameter, which some parameter showed low standard deviation (DO, pH, Nitrite, Nitrate, Ammoniacal Nitrogen, ortho-phosphate and BOD) while other showed high standard deviation (conductivity, COD, TSS and Temperature). The lowest standard deviation indicated that the value tend to be very close to mean value while highest standard deviation indicated that the values spread out over a large range of values.
Based on the results obtained in Table 3, most of the nutrient analysis show some reduction after the stormwater flowed through the wetland. For nitrite concentration reduce from 0.035 mg/l to 0.007, remove 80%;
Table 3. Mean for water quality parameters for 17 sampling stations for 13 month period (December 2010-December 2011).
nitrate reduce from 2.94 mg/l to 1.13 mg/l remove 61.56%, ammoniacal-nitrogen reduce from 0.303 mg/l to 0.147 mg/l, remove 51.49%, orthophosphate reduce from 0.41 mg/l to 0.16 mg/l, remove 60.98%, TSS reduce from 28 mg/l to 9 mg/l, remove 67.86%, BOD reduce from 2.78 mg/l to 2.01 mg/l, remove 27.7% and COD reduce from 28 mg/l to 15 mg/l, remove 46.43%. Most of the concentration laid on Class IIB and Class IIA. The improvement shown was due to favorable physic-chemical such as high dissolve oxygen and average level of water temperature. Plant uptake is also one of the factor involve to this improvement and help to reduce to input nutrient concentration. Macrophyte, which dense with plant, helps to polish the nutrient concentration as well as provide favorable habitat for wildlife to live. Figures 3(a)-(c) showed the results of biological measurement and observation from phytoplankton, zooplankton and freshwater fish. Based on the Figure 3(a), high percentage of species distribution, which was in the range 14.6 to 14.9% and number of individual species, from 1922 ind. species to 1959 ind. species, found in Wetland 1 and 2 (W1 and W2). The lowest data recorded for phytoplankton found in the inlet wetland. The pattern in the graph showed the number of individual species and percentage distribution is decreasing until it reach outlet wetland (3.5% and 461 ind. species). The same situation obtained for zooplankton data in the Figure 3(b), whereas the highest percentage of species distribution and number of ind. species recorded in W1 (14.1% and 539 ind. species) and the lowest found in inlet wetland (3.5% and 135 ind. species). The trend of distribution in the wetland for zooplankton was almost like phytoplankton result, which is the percentage species distribution and number of individual species is decreasing until it reach outlet wetland (3.9% and 150 ind. species). The distribution of phytoplankton and zooplankton are closely related to the water quality measure and nutrient availability. Less nutrient concentration supply will affect the distribution of phytoplankton and zooplankton species became lower. 7 different freshwater fish was caught and identified in the constructed wetland throughout the sampling period. The highest distribution based on the number of species caught was Oreochromis niloticus, 30% out of others species caught, followed by Barbodes schawanenfeldii, Colossoma macropomum, Labeo rohita (each species contribute 15% of percentage distribution), Oxyeleotris marmoratus (10%), Barbodes gonionotus (10%), Channa micropleti, Channa striata, and Pangasius spp (contribute 5%). The abundance of fish mostly centralizes in the micropool area due to favorable area and water depth except for Oxyeleotris marmoratus, which highly found the shallow area (W1 until W6).
(a)(b)(c)
Figure 3. Graph for biological measurement: (a) Percentage distribution and number of species for phytoplankton; (b) Percentage distribution and number of species for zooplankton; and (c) Percentage distribution of freshwater fish.
4. Discussion and Conclusion
Mohammad Baneshi et al. [7] have shown that plants such as Sorghum and Onobrychis sativa can be used effectively to remove pollutants from soil via bioaugmentation. This paper has shown that the pollution effects of dirty urban stormwater runoffs can be addressed by using constructed wetlands. Such wetlands can be easily constructed in housing areas, municipal parks, along river floodplains and wherever there is empty land in the city. It needs political will and prudent urban planning within an enabling environment of integrated water resources management to ensure constructed wetlands are put into the government agenda [8] [9] . In the case of Malaysia, the use of constructed wetlands for flood attenuation and pollution control remains an important challenge in water resources governance [10] . The results showed that pollutants such as nitrite, nitrate, ammoniacal nitrogen and phosphate were significantly reduced after the stormwater passed through the constructed wetland. Their concentrations were significantly reduced from the macrophyte area (Wetland 1 and Wetland 2) until the Micropool area. The area design for the wetland and the present of dense vegetation in the macrophyte area help to reduce the concentration of the total suspended solid as well as the COD and BOD levels. This study confirms and concludes that the USM constructed wetland possess high dissolve oxygen (DO) and favourable water temperature, with the range between 28˚C - 32˚C, and most of the time neutral in pH, helped to maintain the ecological quality with diverse biodiversity. The improvement of water quality had created sustainable habitats for wildlife to live, starting from low trophic level to species of higher trophic levels. Wetlands therefore had positively enhanced the water security for humans, but also for ecosystem and species biodiversity.
Acknowledgements
The authors wish to acknowledge the support from the Malaysian Ministry of Education LRGS Project 203/PKT/6720004, the Ministry of Science and Technology of China (2008CB425803) and State Key Lab of Water Science and Engineering (2009-ZY-2).
NOTES
*Corresponding author.