Environmental, mechanical, and biochemical benefits of water hyacinth (Eichhornia crassipes).

Abstract

Water hyacinth (WH) has high tolerance in extreme environmental conditions. Here, we examined the potentials of WH (Eichhornia crassipes (Mart) solms) to remove excess nutrients from sewage wastewater. We used four prototypes of water systems: prototypes A (WH + underlay water) and C (WH + sewage water), whereas prototypes B and D were experimental control for A and C, respectively. For prototype A, the percentage removal efficiencies (%Re) for nitrate and phosphate achieved were 75.12 ± 4.22% and 78.90 ± 8.72%, respectively, with a pH increase from 6.29 to 7.69; whereas for prototype C, the values were 54.7 ± 8.11% and 86.10 ± 7.34%, respectively, with a pH decrease from 8.13 to 7.15. For the 3-week retention time, the biomass weight increased in both prototype A (33.26%; [Formula: see text] rate = 15.46g/week) and prototype C (26.43%; [Formula: see text] rate = 12.54g/week). Further, the respective mechanical strength and nutritional values of the WH's fiber and the organic extracts were examined. The air-dried WH stem showed an average tensile stress of 0.04MPa on a load at maximum stress of 137.1N. By comparison, a strand of WH has a tensile strength of 14MPa, inferior to 15, 61, and 400MPa shown by timber, wood, and steel, respectively. However, by knitting, four strands of WH yielded a much-improved tensile strength of 315MPa. Finally, a gas chromatography-mass spectrometer analysis of the plant's extract showed that it contains 35.51% oleic acid, a nutritional extract of high value. Thence, we established a profound economic significance of WH, a macrophyte with latent immense benefits.