Fluoride, arsenic, and nitrate are considered as major pollutants of water around the world,
affecting millions of people mainly through the potable groundwater. Presence of these contaminants
in drinking water can cause health issues like dental fluorosis, skeletal fluorosis, blackfoot disease,
blue-baby syndrome, reproductive disorders, skin cancer, thyroid dysfunction, hypertension etc. The
removal of fluoride, arsenic, and nitrate is mainly carried out through ion-exchange, membrane, adsorption,
and other chemical treatments. Owing to the cost competitiveness, energy consumption and
customized operating procedure, adsorption has been a popular choice for the removal of these contaminants.
The adsorbent based on natural material either in native form or modified at the surface,
have gained the momentum to be utilized for fluoride, arsenic, and nitrate free drinking water because
of their adequate disposability. Recently, adsorbent of nanomaterial has shown the significant
potential for water treatment because of their higher surface area and tailored selectivity. Nanoadsorbents
prepared by wet-chemical precipitation, co-precipitation, sol-gel, electro-coextrusion,
hydrothermal, thermal refluxing methods etc. can be effectively employed at comparatively lower
concentration for water treatment. The adsorption capacity, durability, recyclability, and toxicity of
nano-adsorbent are further explored particularly, at commercial scale. The present article is mainly
aimed to provide a comprehensive review about the applicability and challenges associated with the
use of nano-adsorbents for the removal of fluoride, arsenic, and nitrate with a brief discussion on
options and future perspective to meet the challenges of complexity for the selection of environmentfriendly
adsorbents.
Quality assessment of drinking water of Multan city, Pakistan in context with Arsenic and Fluoride and use of Iron nanoparticle doped kitchen waste charcoal as a potential adsorbent for their combined removal
