Nimrit Palan, Mumbai University
A recent finding regarding nanoclusters has the potential to unlock the maximum capabilities of catalysis in chemistry, paving the way for new ways of making and using particles that are both atom-efficient and energy-resilient.
What are nanoclusters?
Metal nanoclusters are made up of a small number of atoms, usually in the tens. They are generally less than 2 nm in size and can be made up of a single or numerous components. When compared to their bulk rivals, they have appealing digital, optical, and chemical compositions. The strength of nanoclusters is determined by the number of particles in the nanocluster, the number of valence electrons, and the presence of enclosing biomaterials.
History
Atomic nanoclusters have existed since ancient times. It has been proposed that the formation of stable nanoclusters such as Buckminsterfullerene (C60) took place during the origin of the world. The first studies to form nanoclusters date back to the 1950s and 1960s.
During this time, supersonic expansion generated them from strenuous molecular beams at low temperatures. The development of the laser evaporation technique enabled the creation of nanoclusters of the overwhelming bulk of the periodic table of elements.
How do they affect Precious metals
Scientists have recently developed a new type of catalyst that is predicted to result in novel, self-sustaining means of production and use of molecules while also ensuring the protection of precious metal supplies. One of the most effective methods to increase the active surface area accessible for catalysis is the use of metals in the form of nanoclusters.
When the dimensions of nanoclusters break through the nanometre scale, there is indeed a major change in the properties of the metal, resulting in a new occurrence that is not possible at the macroscopic level.
As they have unique optical, electrical, magnetic, and excitability properties, nanoclusters have the potential to be used in a wide range of applications. They are biologically active, ultrasmall, and emit bright light, making them ideal for fluorescent bio-imaging or cellular labeling.
Also read: Application of Embryonic stem cells in drug discovery
Reference:
- Cano, I., Weilhard, A., Martin, C., Pinto, J., Lodge, R. W., Santos, A. R., Rance, G. A., Åhlgren, E. H., Jónsson, E., Yuan, J., Li, Z. Y., Licence, P., Khlobystov, A. N., & Alves Fernandes, J. (2021). Blurring the boundary between homogenous and heterogeneous catalysis using palladium nanoclusters with dynamic surfaces. Nature Communications, 12(1), 4965. https://doi.org/10.1038/s41467-021-25263-6
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Author Info:
Nimrit Palan is a Biotech researcher with graduation in BSc. Biotechnology from the University of Mumbai. She is currently pursuing a Master’s degree in Biotechnology Part 1.
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