in a marsh–pond–marsh wetland syste

in a marsh–pond–marsh wetland system. The present facultative
tanks displayed a much improved NH3-N reduction efficiency.
NH3-N removal in facultative WSP occurs essentially through
three processes: volatilization of gaseous ammonia to the atmosphere,
ammonia assimilation in algal biomass and biological nitri-
fication (Middlebrooks et al., 1999). Shilton (1996) quantified the
removal of NH3-N from a facultative lagoon treating piggery wastewater,
and found that the rate of volatilization varied from 355 to
1534 mg m2 day1
. Our test site was close to the sea and the
windy condition was expected to have accelerated NH3-N volatilization,
similar to the situation described by Poach et al. (2002).
However, data collected on December 24, 2008 and February 5,
2009 did not support this assumption (Table 2). Although water
hyacinth plants in T3 began to wither in November, reducing effective
biomass and giving out more than 1/3 open surface of water in
the tank, the average NH3-N removal was shown to be much lower
than when the tank was fully occupied by the plants. It seemed
apparent that NH3-N reduction in the present case involved mechanisms
more than volatilization.
Unlike phosphorus, the total nitrogen content was not enhanced
in the hyacinth materials retrieved from the facultative
tank (Table 5). It was observed that the spongy hyacinth materials
provided a solid medium for the growth of microbes, common vascular
plants, moss and lichen, zooplankton and insects. As microbes
play important roles in nitrification and denitrification,
while the lower food web helps further nitrogen transformation,
it was supposed that the diverse floral and faunal populations
might have contributed to the reduction of nitrogen nutrients in
the wastewater.
4. Conclusions
This study demonstrated a potential to recycle water hyacinth
for an economical swine wastewater treatment. According to data
contained herein, water hyacinth straw could be useful for waste
removal. The material acted as a phosphorus adsorbent and the removal
rate varied with the contact time. Compared with similar
facilities, the present facultative tank with water hyacinth straws
covering the water showed a much greater NH3-N reduction effi-
ciency. It is speculated that a similar result could be obtained on
a large-scale operation, and the present system would be able to
achieve WSP treatment effects with less land than the conventional
design.
Acknowledgements
This work was part of the Science and Technology Innovations
Program, Fujian Academy of Agricultural Science. It was funded
by the Fujian Environmental Protection Bureau. We are grateful
to Messrs. Yi-Chan Chen, Jia-Guan Chen and Ri-Yang Lin of Changle
Haili Animal Husbandry Co., Ltd., for their collaboration in the field