Technology 3 min read

Researchers Create the new Periodic Table of Nanomaterials

Although promising, nanomaterials still provide plenty of challenges. Now, researchers may have found the key to creating them on a large scale. | Image By HaHanna | Shutterstock

Although promising, nanomaterials still provide plenty of challenges. Now, researchers may have found the key to creating them on a large scale. | Image By HaHanna | Shutterstock

A new simulation technique allows scientists to pick the appropriate molecular precursors to synthesize nanomaterials from the bottom up.

One of the most popular fields of research in nanotechnology is the manufacture of new materials or nanomaterials by toying around with the structure of matter at the molecular and atomic level.

To produce nanomaterials, material scientists have to follow one of two options: either the top-down or bottom-up fabrication processes.

For the substructive top-down method, researchers start with a bulk mass of a material and keep breaking it down until they get to the atomic level. For example, if you keep chopping down a block of carbon, you end up with graphene.

Read More: New Nanomaterials IPL Process Would Revolutionize Thin-film Manufacturing

Machine Learning Technique for Bottom-up Fabrication of Nanomaterials

The bottom-up approach is to build nanostructures using building blocks in the form of molecular precursors.

Synthesizing nanoparticles from the bottom up is more advantageous in that it gives scientists more control over the final product’s shape and size and lends itself more to scaling up.

However, one of the major challenges with the bottom-up approach is that scientists can’t know for sure how molecules would interact and which of them would be best for their target nanoparticle.

Now, a team of materials scientists from two universities in Japan has developed a new technique that takes a lot of the guesswork out of the bottom-up fabrication process of nanoparticles.

The Machine Learning-based method, devised by Daniel Packwood (Kyoto University’s iCeMs) and Taro Hitosugi (Tokyo Institute of Technology), takes into account the chemical properties of molecular precursors and their interaction to show how the target nanostructure would end up.

By categorizing different molecules according to the structure they’d form, the modal allows scientists, via diagrams (dendrograms), to see how molecules would assemble into their target nanomaterial before they get to fabricate it from scratch.

To test their simulation technique, researchers worked on graphene nanoribbons and investigated how different molecules and the temperatures would affect the end product and which would yield the best results.

Hitosugi and Packwood think of their technique’s dendrograms as a periodic table for nanomaterials that categorizes molecules based on the way they would self-assemble into nano-sized structures.

Although a step in the right direction, there is still work to be done. In their research paper published in Nature Communications, the authors wrote:

“However, in order to truly prove that the dendrograms or other informatics-based approaches can be as valuable to materials science as the periodic table, we must incorporate them in a real bottom-up nanomaterial fabrication experiment. We are currently pursuing this direction in our laboratories,’’

Do you think nanomaterials will ever be easy enough to fabricate that they’ll become a household object?

First AI Web Content Optimization Platform Just for Writers

Found this article interesting?

Let Zayan Guedim know how much you appreciate this article by clicking the heart icon and by sharing this article on social media.

Profile Image

Zayan Guedim

Trilingual poet, investigative journalist, and novelist. Zed loves tackling the big existential questions and all-things quantum.

Comments (0)
Most Recent most recent
share Scroll to top

Link Copied Successfully

Sign in

Sign in to access your personalized homepage, follow authors and topics you love, and clap for stories that matter to you.

Sign in with Google Sign in with Facebook

By using our site you agree to our privacy policy.