Photocatalytic Lithography

Shaping nanomaterials by short electrical pulses

We report a new dry-state technique for non-contact patterning of nanostructured conducting materials, and demonstrate its use for carbon nanotube forests and freestanding sheets of carbon nanotubes, graphene, graphene sponge, and MXene. This method uses self-generated electron-emission pulses (∼20 ns) in air. On a substrate-tip separation scale of 10 to 20 nm, the few molecules of gas at atmospheric pressure enables electron-emission-based interaction between a sharp tungsten tip and elements of nanostructured materials. Using the advantages of field enhancement at sharp ends of nanostructured materials, the discharge voltage is reduced to 25-30 V, depending upon the materials density. This method causes largely non-oxidative sequential decomposition of nanostructure elements neighboring the tungsten tip. The main decomposition mechanism is thermal dissociation facilitated by Joule heating and electrostatic removal of debris. The non-contact-based patterning of nanomaterials can be as fast as 10 cm s^-1. The resulting precisely patterned structures (<200 nm) are largely free of foreign contaminants, thermal impact and sub-surface structural changes.

Bismuth as Smart Material and Its Application in the Ninth Principle of Sustainable Chemistry

This paper reports an overview of Green Chemistry and the concept of its twelve principles. This study focusses on the ninth principle of Green Chemistry, that is, catalysis. A report on catalysis, in line with its definition, background, classification, properties, and applications, is provided. The study also entails a green element called bismuth. Bismuth’s low toxicity and low cost have made researchers focus on its wide applications in catalysis. It exhibits smartness in all the catalytic activities with the highest catalytic performance among other metals.