The most commonly used methods for

The most commonly used methods for removing Cr(VI) from
wastewater include reduction [9,10], precipitation [11], membrane
filtration [12,13], biological method [14], ion exchange [15–
18] and adsorption [19–23]. The first five conventional separation
methods have many disadvantages for instance, the high capital
and operational cost, the production of amount of chromium
sludge and possible generation of secondary pollution resulting in
high disposal costs [24], whereas adsorption has been widely used
in the removal of Cr(VI) from wastewater due to its simple
operation, high removal efficiency and low treatment cost. A
number of adsorbents from industrial wastes, agricultural byproducts
and biological materials have been reported for the
removal of Cr(VI), such as graphene/MgAl-layered double [25],
amino-functionalized titanate nanotubes [26], fertilizer industry waste material [3], glycine doped polypyrrole adsorbent [27], lowcost
dolomite adsorbent [28], pine needles [29], activated carbon
[30–34], etc. Among them, adsorption on activated carbon is still
by far regarded more advantageous due to its high specific surface
area and pore volume, simplicity of design, high efficiency and
relatively low cost. Therefore it is one of the most important
adsorbents for the removal of heavy metals from industrial
wastewater.
However, most of the commercial activated carbons are usually
expensive due to their high-cost sources, regeneration and
reactivation procedures, which restricts their extensive application.
In recent years growing research interest in the production of
low-cost and highly efficient activated carbon based has been
focused on the relatively cheap and effective raw materials with a
high carbon content and low inorganic, for like agricultural
residues, biomass and various solid substances. There are several
recent literatures on the removal of Cr(VI) by activated carbons
derived from rice husk and straw [35–37], hazelnut shell [38],
coconut shell [39], cornelian cherry, apricot stone, almond shells
[40], casurina equisetifolia leaves [41], tamarind wood [42], hevea
brasilinesis sawdust [43], date palm seed [44], olive bagasse [45],
peach stone [46], bael fruit shell [47], sugarcane bagasse [48],
eichhornia crassipes root [49], trapa natans husk [50], terminalia
arjuna nuts [51], etc. Longan, a very important south-asian tropic
fruit, is a famous sapindaceae fruit and has been cultivated for over
2000 years widely distributed in Asia including China and
surrounding countries. The longan seed accounts for 17% of the
total fresh fruit weight, whereas longan seed is often discarded or
burned as a waste material up to hundreds of tons per year because
of the lack of a comprehensive utilization [52]. Longan seed, a high
content of C, O and H, is a good precursor for the production of an
effective activated carbon due to its abundance and availability.
However, no studies have yet been published on the removal of
Cr(VI) from aqueous solutions by longan seed activated carbon
(LSAC). In this work, we report the synthesis of activated carbon
prepared from longan seed by chemical activation with NaOH and
the removal of Cr(VI) from aqueous solution by adsorption onto
LSAC. The influence of several important operating parameters,
such as shaking speed, LSAC dosage, initial pH and temperature,
were studied by batch experiments. Furthermore, the adsorption
kinetics, isotherms and thermodynamics of Cr(VI) on LSAC at
different temperatures were also investigated.