Sustainable Materials

Chitin, the most abundant aminopolysaccharide, can be found in the exoskeleton of crustacean shells, a major waste product of the fishing industry. The water-soluble derivative of chitin, chitosan, acquired through a process of deacetylation affords derivatization and processability of this natural biopolymer. Traditionally, deacetylation processes utilizing harsh chemical conditions and high energy inputs limiting scalability and sustainable practices. Furthermore, these methods result in depolymerization, presenting low molecular weight fragments.

The existing global energy crisis demands potential materials for applications relating to renewable energy production, for instance, hydrogen fuel generation via water splitting. Transition metal phosphide (TMP) nanoparticles e.g., copper phosphide (Cu3-xP), nickel phosphide (Ni2P), etc. are well known water splitting catalysts. Our prior experiences with TMPs confirm the superior activity of bimetallic phosphides over their monometallic counterparts.

The sustainability of agricultural practices is increasingly critical amid environmental challenges. While effective, traditional soil-based agricultural methods often contribute to soil degradation and resource depletion. The earth’s topsoil has eroded by 50% during the last 150 years. In addition to this, soil has also been affected by agricultural practices.  These effects include compaction, loss of soil structure, nutrient degradation, and soil salinity [1].

Supercapacitors, celebrated for their high power density and rapid charge-discharge capabilities, represent a promising solution to meet the increasing demand for sustainable energy storage systems. This research adopts a sustainable approach to develop green supercapacitors by leveraging biomass-derived materials for both electrodes and electrolytes, thereby aligning with global efforts toward green energy technologies and the circular economy.

Diels-Alder (DA) reactions result in the formation of two carbon-carbon bonds of six-membered ring structures with high atom economy. The use of unsaturated organoboranes, which are widely available and exhibit low toxicity, enables the modulation of reactivity and selectivity in these reactions and also allow a variety of subsequent transformations the carbon-boron bond. These characteristics align these reactions with the principles of green chemistry.

Fluoropolymers, notably poly(vinylidene fluoride-co-hexafluoropropylene) (PH), are rendered to be an excellent choice for superior performance coatings attributed to their exceptional mechanical robustness, thermal resistance, and resistance to chemical attack. However, their low surface energy results in poor adhesion to metal substrates, limiting their application in critical corrosion-resistant systems. To address this challenge, PH was hydroxyl-modified (PHOH) to introduce active functional groups that enhance bonding capabilities.

Use of lignocellulosic biomass in continuous processes in biorefineries poses challenges due to its recalcitrant properties, feedstock variability, and materials handling of solids at large scale. Limitations include lignin derived inhibitors, and resistance to mixing due to rheological properties of lignocellulosic particulates at high solids loadings.

Infections associated with medical devices are a serious global issue, affecting millions of patients and increasing healthcare costs . These infections are primarily due to the formation of biofilms on the surfaces of devices such as catheters and implants, which act as protective barriers against antimicrobial treatments and compromise device functionality. Additionally, infections in indwelling devices contribute to environmental pollution due to the frequent need for replacements, further increasing the burden on healthcare system.

The development of sustainable and environmentally friendly materials is a key component of the green chemistry concept. In this context, cellulose tosylate (MCC-Tos) serves as a versatile precursor for the functionalization of cellulose. By substituting tosyl groups with alkyne groups, the potential of cellulose is enhanced, making it compatible with click chemistry reactions such as thiol-yne and copper-catalyzed alkyne-azide cycloaddition (CuAAC), which promotes greener processes.