Precedency of nano-biosystems over conventional methods for the remediation of heavy metals from industrial effluents
摘要
Environmental pollution caused by rapid industrialization is becoming a growing concern and challenge for humans. Environmental pollutants are hazardous and toxic substances that are released into the environment, causing lethal effects on living organisms and ecosystems. Water pollution is the contamination of water bodies by harmful pollutants such as organic and inorganic pollutants, chemicals, excessive nutrients, pathogens, and heavy metals. Heavy metals occur naturally, but large amounts of heavy metals are present in industrial effluents and are highly prevalent. Lead, mercury, cadmium, chromium, and arsenic, found in industrial wastewater, are non-biodegradable and can cause serious health disorders, including nervous disorders, respiratory disorders, and cancer. Conventional methods used for the remediation of heavy metals from industrial effluents include physical, chemical, and biological methods such as ion exchange, chemical precipitation, bioremediation, adsorption, and soil washing. However, these methods are not eco-friendly, produce secondary waste, and require sophisticated machinery and trained professionals. Furthermore, these are expensive, take a longer time for treatment, and require optimal conditions for effective treatment. In contrast, nano-biosystems and synthesized nanomaterials offer a promising and more efficient alternative. According to the latest findings, carbon-based nanomaterials (such as carbon nanotubes and graphene), metal-oxide nanoparticles, magnetic nanocomposites, and bio-supported nanosorbents are examples of nanoadsorbents that exhibit exceptionally high adsorption capacities, selective affinity toward specific heavy metals, and tolerance to stressful environmental conditions, making them highly effective even at trace contamination levels. Strong binding is made possible by their large surface area, flexible surface chemistry, and functionalization with particular ligands by complexation, sorption-reduction, and electrostatic attraction. Moreover, some nanomaterials can be magnetically recovered and reused, thereby improving their sustainability and enabling scale-up and commercial-level applications. The potential of nanoparticles to effectively eliminate various pollutants from industrial effluents makes them a promising choice for future applications. The use of nano-biosystems worldwide can create a cleaner, safer, and healthier environment for future generations.