Free Courses Sale ends Soon, Get It Now


AEROGELS

1st November, 2023

Disclaimer: Copyright infringement not intended.

Context

IIT Madras, Tel Aviv varsity researchers develop aerogels to remove trace pollutants from wastewater.

Details

Key highlights from their research

  • Aerogel Adsorbent for Pollutant Removal: The graphene-modified silica aerogel, an innovative adsorbent material, demonstrated the capability to remove over 76% of pollutants at parts per million levels in flowing water, highlighting its efficiency in wastewater treatment.
  • Aerogels and their Properties: Aerogels, characterized by their high porosity and low density, are composed mostly of air and possess adjustable chemistry. Often referred to as "solid air" or "frozen smoke," they can be fabricated easily and are known for their capacity to remove contaminants from various substances.
  • Water Pollution Scenario in India: With only 4% of global water resources and 18% of the world's population, India faces significant challenges in water management. Industries such as pharmaceuticals and textiles contribute significantly to water pollution, discharging large quantities of synthetic dyes annually.
  • Leaders of the Research: Rajnish Kumar, a professor in the Department of Chemical Engineering at IIT-M, and Hadas Mamane, a professor in the School of Mechanical Engineering at Tel Aviv University, spearheaded this groundbreaking research, which was published in Nature Scientific Reports.
  • Advantages of Aerogels in Wastewater Treatment: Professor Kumar emphasized the importance of indigenous techniques for wastewater purification, citing the limitations of conventional treatment methods in removing trace pollutants, particularly pharmaceuticals. He highlighted the eco-friendly nature, cost-effectiveness, and efficient pollutant removal capabilities of adsorption as an attractive feature for water treatment.
  • Customizability and Reusability: Professor Mamane underscored the adaptability of aerogels in targeting specific contaminants through surface chemistry modifications, making them versatile in diverse water treatment applications. Furthermore, their ability to be regenerated and reused multiple times enhances their sustainability, reducing waste and operational costs.

Aerogels

Definition:

  • Aerogels are a class of highly porous materials derived from a gel, in which the liquid component of the gel has been replaced with gas.
  • They are known for their extremely low density, high porosity, and unique thermal and acoustic insulating properties.

Composition:

  • Aerogels are typically composed of a network of interconnected nanoparticles or polymers, forming a solid, three-dimensional porous structure with high surface area.
  • Common materials used in aerogel production include silica, carbon, metal oxides, and polymers.

Properties:

  • Low Density: Aerogels are renowned for their exceptionally low density, often referred to as "frozen smoke," making them one of the lightest solid materials known to man.
  • High Porosity: With porosities ranging from 50% to 99.8%, aerogels have an extensive internal surface area, providing excellent potential for various applications, such as in filtration, insulation, and catalysis.
  • Thermal Insulation: Aerogels exhibit remarkable thermal insulating properties, making them highly effective in applications where heat transfer control is essential, such as in aerospace, construction, and energy-efficient technologies.
  • Acoustic Insulation: Their porous structure also enables exceptional sound-absorbing capabilities, making them valuable in noise reduction and acoustic engineering applications.

Production Techniques:

  • Supercritical Drying: The most common method for producing aerogels involves supercritical drying, where the solvent in the gel is replaced with gas under supercritical conditions, preserving the solid structure of the gel and preventing the collapse of the porous network.
  • Sol-Gel Process: Aerogels can be synthesized through the sol-gel process, which involves the conversion of a liquid "sol" into a solid "gel," followed by the removal of the liquid component to obtain the aerogel structure.

Applications:

  • Insulation: Aerogels find extensive use in thermal insulation for buildings, pipelines, and various industrial applications, contributing to energy efficiency and reduced heat loss.
  • Environmental Remediation: Their high porosity and large surface area make them useful in environmental applications, such as water purification, air filtration, and as adsorbents for pollutants and toxins.
  • Electronics and Aerospace: Aerogels are employed in electronics for their electrical and thermal properties and in aerospace for lightweight components, thermal protection, and insulation in space missions.
  • Challenges and Future Prospects:
    • Cost and Scalability: Despite their exceptional properties, challenges related to the cost of production and scalability hinder the widespread adoption of aerogels in various industries.
    • Functionalization: Further research is focused on functionalizing aerogels to enhance their properties for specific applications, such as in biomedical, energy storage, and catalytic processes.

Conclusion

The development of this graphene-modified silica aerogel represents a significant stride in sustainable water purification technology, holding promise for addressing water pollution challenges in both India and worldwide.

PRACTICE QUESTION

Q. Discuss the significance of aerogels in addressing contemporary environmental challenges, emphasizing their unique properties and potential applications in the context of sustainable water treatment and pollution mitigation. (250 Words)