Chapter 16
Remediation for Heavy Metal
Contamination
A Nanotechnological Approach
Rubina Khanam, Amaresh Kumar Nayak* and
Dibyendu Chatterjee
16.1 Introduction
Pollution is defined as the presence of undesirable chemical objects that obstruct natural processes
or have negative consequences for living beings and the environment. Pollution is increasing
at an alarming rate as a result of industrialization and the massive rise in population that leads
to rising urbanization. Environmental pollution identification, treatment and prevention is a
critical step toward long-term environmental sustainability. Environment sustainability refers to
the responsible and justifiable relationship between humans and the environment, as well as the
intelligent use of resources, ensuring environmental safety for current and future generations.
Economic and environmental sustainability are inextricably linked (Fajardo et al. 2020). A lot of
work is being done right now to discover and create persuasive and dependable ways for degrading
or transforming environmental contaminants of concern. Nanoremediation is a groundbreaking
remediation technique that employs nanomaterials having high surface: volume ratio, low reduction
potential and quantum confinement making them efficient for the detoxification and alteration of
hazardous recalcitrant pollutants in the system (Fajardo et al. 2020). In particular, when compared
to standard remediation procedures (viz., chemical oxidation, thermal decomposition and solvent
co-flushing), the use of nanomaterials in environmental remediation has gained a lot of attention.
Nanoremediation methods have drawn a lot of interest because of their unique qualities, such as cost-
effectiveness, sensitivity, superior electrical properties, high surface area and improved catalytic
properties (Shafi et al. 2021). These techniques have the potential to give long-term solutions
to environmental pollution issues, while also reducing the cost of cleaning (Shafi et al. 2021).
Nanostructure-based technologies have the potential to reduce not only the overall costs of cleaning
up large-scale contaminated areas but also to reduce clean-up time, minimize the need for polluted
material treatment and disposal, and decrease pollutant concentrations to near zero-all in-situ
(Corsi et al. 2018). Nanoremediation involves the applications of nano-sized metal and bimetallic
ICAR-National Rice Research Institute, Cuttack 753006, Odisha, India.
* Corresponding author: aknayak20@yahoo.com