(Nasuha and Hameed, 2011). Coloured

(Nasuha and Hameed, 2011). Coloured wastewater is the direct
result of the production of dyes and a consequence of their
extensive use in the textile and others industries. CR is a
benzidine-based dye with two molecules of naphthenic acid
and is the first synthetic dye for the direct dyeing of cotton.
It is sensitive to acids and its colour changes from red
to blue in the presence of inorganic acids; CR is well known
for the metabolism of the benzidine, a carcinogenic agent
(Mall et al., 2005a). The Congo Red has been selected because
of its high pollution degree in water. Considering the large
discharged volume and effluent combustion, the wastewaters
from the textile industry are rated as the most polluting
among all industrial sectors. Their presence in water, even
at very low concentrations is highly visible; it is undesirable
and may dramatically affect the photosynthetic activity in the
aquatic life due to the reduced light penetration. Dyes are
toxic to micro-organisms and stable to both light and heat,
they cannot be easily removed by conventional treatment
due to their complex structure and synthetic origin. Nowadays,
various physical–chemicaltechniques have been studied
to assess their applicability for the treatment of industrial
effluents. Among these processes, may be included coagulation,
adsorption, precipitation, flocculation and ozonation.
The adsorption is considered to be an effective method for
the dyes removal due to its low maintenance, simple operation
and removal effectiveness. Moreover, it provides an
attractive alternative, especially if the adsorbent is inexpensive
and readily available. In this respect, activated carbon is
the versatile adsorbent and has been used regularly for the
adsorption process, but remains currently expensive. Consequently,
many groups have studied the feasibility of low cost
and available substances that can be used for the synthesis
of activated carbon. This has prompted a growing research
in the production of activated carbons from cheaper precursors
which are mainly industrial and agricultural by-products
for the water treatment. However, the available activated carbons
in commerce remain expensive and their production
and regeneration cost constitute limiting factors. Accordingly,
many researchers have focused on the search of new lowcost
precursors especially issued from agricultural wastes
such as rubber seed coat (Rengaraj et al., 2002), pecan shells
(Shawabkeh et al., 2002), jute fibre (Senthilkumaar et al.,
2005), nano-adsorbent (Behbahani et al., 2012), olive stones
(El-Sheikh et al., 2004), industrial waster (Jain et al., 2003),
sawdust (Malik, 2004), coir pith (Namasivayam and Kavitha,
2002a), rice husk (Guo et al., 2005), bamboo (Hameed et al.,
2007a), rattan sawdust (Hameed et al., 2007b), oil palm fibre
(Tan et al., 2007) and apricot stone (Mouni et al., 2011). The
remarkable adsorption capacity of activated carbons is due to
their well-developed porous structure and pore size distribution,
as well as the surface functional groups. The efficiency
strongly depends on the polarity, solubility, molecular size
of the adsorbate, the solution pH and the presence of other
ions in solution. However, the specific mechanism by which
the adsorption of organic compounds takes place on active
carbons is still not well elucidated. Agricultural by-products
exist in large amounts and about 20 000 t of apricot stones
per year are produced each year in Algeria (FAO, 2009), which
represents consequently a solid pollutant to the environment
(Table 1). Over the past, these by-products were used as fuel in
the rural areas but now the preparation of activated carbon is
considerably encouraged. Apricot stone is a cheap precursor
for activated carbon source and it is important to evaluate its
performance as adsorbent (Abbas, 2014). In previous studies,