|
Fluoride pollution is widespread in several parts of India. For normal and healthy
functioning of living being, less amount of fluoride is very much essential. According
to World Health Organization (WHO), the maximum allowable fluoride
concentration in drinking water is 1.5 ppm (Popat et al., 1994). Indian Standard
(1996) has recommended that the fluoride concentration should be less than 1 ppm
for drinking water. According to 1984 guidelines published by the WHO (1984),fluoride is an effective agent for preventing dental caries if taken in ‘optimal’ amounts.
Fluorine is the most highly electronegative and reactive element of the halogen
family (Waheed and Attar, 2008). It naturally exists in combined fluoride forms in
the atmosphere, water and soils (Hang and Liu, 2007). A high percentage of fluoride,
1 to 7.4 ppm, was reported in the eastern and southeastern belt of Karnataka,
covering the districts of Gulbarga, Raichur, Bellary, Chitradurga, Tumkur and
Kolar, and is scattered in rest of Karnataka (Achuta Rao et al., 1992). The intake of
large amounts of fluoride, whether via water or food, can cause serious health
problems for human beings and animals, ranging from discolored teeth (i.e., dental
fluorosis) to aching joints, brittle bones, stunted growth and deformed limbs
(i.e., skeletal fluorosis).
Earlier researchers have studied several techniques like adsorption, ion exchange,
precipitation, etc., to defluorinate the water. Investigations were carried using
different adsorbents to remove fluoride from aqueous solution, namely, activated
carbon, processed bone charpowder, activated bauxite, fly ash, granular calcite,
alum, lime (Choi and Chen, 1979; and Killedar and Bhargava, 1988a and 1988b) dry
powder, holly oke, neem bark powder, activated cotton, jutecarbon, leaf powder
adsorbents (Jamode et al., 2004a and 2004b), hydroxide (Toyoda and Taira, 2000),
aligned carbon nanotubes (Li et al., 2003), rare earth oxides (Raichur et al., 2001) and
tamarind seeds (Murugan and Subramanian, 2006). Waheed and Attar (2008) used
activated alumina R and D 651-X, as an adsorbent to defluorinate water by batch
adsorption technique. Hang and Liu (2007) used nanometer-size zirconia to adsorb
fluoride in ion exchange chromatography by dynamic adsorption method.
The objective of the present work is to synthesize Aluminium oxide (Al2O3)
and to use the same as an adsorbent to remove fluoride from aqueous solution.
Batch adsorption studies were conducted to study fluoride removal using synthetic
sodium fluoride stock solution. The effects of adsorbent dosage, pH of the solution
and initial fluoride concentration were studied. The effect of variables on
adsorption was also studied using statistically based experimental designs like
Central Composite Design (CCD) and Box Behnken Method (BBM).
|
