‘Artificial Chemist’ Combines AI, Robotics to Conduct Autonomous R&D
Researchers from North Carolina State University and the University at Buffalo have developed a technology called “Artificial Chemist,” which incorporates artificial intelligence (AI) and an automated system for performing chemical reactions to accelerate R&D and manufacturing of commercially desirable materials.
In proof-of-concept experiments, the researchers demonstrated that Artificial Chemist can identify and produce the best possible quantum dots for any color in 15 minutes or less. Quantum dots are colloidal semiconductor nanocrystals, which are used in applications such as LED displays.
However, the researchers are quick to note that Artificial Chemist can identify the best material to meet any suite of measurable properties – not just quantum dots.
“Artificial Chemist is a truly autonomous system that can intelligently navigate through the chemical universe,” says Milad Abolhasani, corresponding author of a paper on the work and an assistant professor of chemical and biomolecular engineering at NC State. “Currently, Artificial Chemist is designed for solution-processed materials – meaning it works for materials that can be made using liquid chemical precursors. Solution-processed materials include high-value materials such as quantum dots, metal/metal oxide nanoparticles, metal organic frameworks (MOFs), and so on.
“The Artificial Chemist is similar to a self-driving car, but a self-driving car at least has a finite number of routes to choose from in order to reach its pre-selected destination. With Artificial Chemist, you give it a set of desired parameters, which are the properties you want the final material to have. Artificial Chemist has to figure out everything else, such as what the chemical precursors will be and what the synthetic route will be, while minimizing the consumption of those chemical precursors.
“The end result is a fully autonomous materials development technology that not only helps you find the ideal solution-processed material more quickly than any techniques currently in use, but it does so using tiny amounts of chemical precursors. That significantly reduces waste and makes the materials development process much less expensive.”
The Artificial Chemist has both a “body” for performing experiments and sensing the experimental results, and a “brain” for recording that data and using it to determine what the next experiment will be.
For their proof-of-concept testing, Artificial Chemist’s body incorporated the automated Nanocrystal Factory and NanoRobo flow synthesis platforms developed in Abolhasani’s lab. The Artificial Chemist platform has demonstrated that it can run 500 quantum dot synthesis experiments per day, though Abolhasani estimates it could run as many as 1,000.
The Artificial Chemist’s brain is an AI program that characterizes the materials being synthesized by the body and uses that data to make autonomous decisions about what the next set of experimental conditions will be. It bases its decisions on what it determines will most efficiently move it toward the best material composition with the desired properties and performance metrics.
“We tried to mimic the process that humans use when making decisions, but more efficiently,” Abolhasani says.
For example, Artificial Chemist allows “knowledge transfer,” meaning that it stores data generated from every request it receives, expediting the process of identifying the next candidate material it is tasked with. In other words, Artificial Chemist gets smarter and faster over time at identifying the right material.
For their proof of concept, the researchers tested nine different policies for how the AI uses data to decide what the next experiment will be. They then ran a series of requests, each time asking Artificial Chemist to identify a quantum dot material that was the best fit for three different output parameters.
“We found a policy that, even without prior knowledge, could identify the best quantum dot possible within 25 experiments, or about one-and-a-half hours,” Abolhasani says. “But once Artificial Chemist had prior knowledge – meaning that it had already handled one or more target material requests – it could identify the optimal material for new properties in 10 to 15 minutes.
“We found that Artificial Chemist could also rapidly identify the boundaries of materials properties for a given set of starting chemical precursors, so that chemists and materials scientists do not need to waste their time on exploring different synthesis conditions.
“I believe autonomous materials R&D enabled by Artificial Chemist can re-shape the future of materials development and manufacturing,” Abolhasani says. “I’m now looking for partners to help us transfer the technique from the lab to the industrial sector.”
The paper, “Artificial Chemist: An Autonomous Quantum Dot Synthesis Bot,” is published in the journal Advanced Materials. First author of the paper is Robert W. Epps, a Ph.D. student at NC State. The paper was co-authored by NC State undergraduate Michael S. Bowen, NC State Ph.D. students Amanda A. Volk, Kameel Abdel-Latif and Suyong Han; Kristofer Reyes, an assistant professor at the University at Buffalo; and Aram Amassian, an associate professor of materials science and engineering at NC State.
The work was done with support from a UNC Research Opportunities Initiative grant and from the National Science Foundation, under grant number 1902702.
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Note to Editors: The study abstract follows.
“Artificial Chemist: An Autonomous Quantum Dot Synthesis Bot”
Authors: Robert W. Epps, Michael S. Bowen, Amanda A. Volk, Kameel Abdel-Latif, Suyong Han, Aram Amassian and Milad Abolhasani, North Carolina State University; and Kristofer G. Reyes, University at Buffalo
Published: June 4, Advanced Materials
DOI: 10.1002/adma.202001626
Abstract: The optimal synthesis of advanced nanomaterials with numerous reaction parameters, stages, and routes, poses one of the most complex challenges of modern colloidal science, and current strategies often fail to meet the demands of these combinatorially large systems. In response, we present an Artificial Chemist: the integration of machine learning-based experiment selection and high-efficiency autonomous flow chemistry. With the self-driving Artificial Chemist, we autonomously synthesize made-to-measure inorganic perovskite quantum dots (QDs) in flow, and simultaneously tune for their quantum yield and composition polydispersity at target bandgaps, spanning 1.9 eV to 2.9 eV. Utilizing the Artificial Chemist, eleven precision tailored QD synthesis compositions are obtained without any prior knowledge, within 30 h, using less than 210 mL of total starting QD solutions, and without user selection of experiments. Using the knowledge generated from these studies, we then pre-train the Artificial Chemist to use a new batch of precursors and further accelerate the synthetic path discovery of QD compositions, by at least two-fold. The knowledge transfer strategy further enhances the optoelectronic properties of the in-flow synthesized QDs (within the same resources as the no prior knowledge experiments) and mitigates the issues of batch-to-batch precursor variability, resulting in QDs averaging within 1 meV from their target bandgap.
This post was originally published in NC State News.