per acre and population doubles eve

per acre and population doubles every 5–15 days (Craft et al.,
2003). Water hyacinth mainly removed by three methods hand cutting/
pulling, mechanical removal and biological control. Harvesting
and transport of water hyacinths can be conducted manually on a
small scale and does not require a new harvesting technique to be
introduced. Presently, the water hyacinths are only harvested to
control their propagation where chemical or biological (e.g., introduction
of water hyacinth eating insects) methods are prohibited
or unsuccessful, while mechanical harvesting is too expensive and
time-consuming (Petrell and Bagnall, 1991). Mechanical smearing
of this water plant does not completely solve the problem since
it grows again and the removed plant if kept on the ground will
cause pollution (Abdel-Fattah and Abdel-Naby, 2012). Mechanical
smearing helps lowering the plant population while providing
a simple and low-cost process that is suitable to the developing
countries; where the cellulose portions of the herbs are hydrolyzed
by enzymes into glucose sugar that are fermented to bioethanol
(Ganguly et al., 2012). Also aquatic biomass has added advantage
of not being a competition to food crops for arable land resources
(Mishima et al., 2008). Effective technologies for ethanol production
from water hyacinth biomass can serve the purpose of weed
removal as well as generation of employment and income in rural
areas (Aswathy et al., 2010).
In the present study, various pretreatments of water hyacinth
such as acid, alkali and hydrogen peroxide were evaluated.
The best pretreatment was further optimized by central composite
design of response surface methodology. The pretreated
biomass was hydrolyzed with crude on-site produced enzymes and