SmartDope: The “Self-Driving Lab” That Unlocks Quantum Dot Secrets in Hours – Instead of Years

Synthesizing “Best in Class” Materials in Hours

Researchers have developed SmartDope, an autonomous system capable of rapidly identifying the best materials for electronic and photonic devices, addressing a longstanding challenge in quantum dot synthesis. SmartDope operates as a self-driving lab, conducting experiments in a continuous flow reactor and utilizing machine learning to optimize quantum dot production. In just one day, it surpassed the previous quantum yield record, showcasing the potential of self-driving labs for accelerating material science. Credit: Milad Abolhasani, NC State University

SmartDope, an autonomous system, accelerates material synthesis for electronic devices, achieving a quantum yield record within a day, demonstrating its potential to revolutionize material science.

It can take years of focused laboratory work to determine how to make the highest quality materials for use in electronic and photonic devices. Researchers have now developed an autonomous system that can identify how to synthesize “best-in-class” materials for specific applications in hours or days.

Addressing the Challenge of Doped Quantum Dots

The new system, called SmartDope, was developed to address a longstanding challenge regarding enhancing properties of materials called perovskite quantum dots via “doping.”

“These doped quantum dots are semiconductor nanocrystals that you have introduced specific impurities to in a targeted way, which alters their optical and physicochemical properties,” explains Milad Abolhasani, corresponding author of a paper on SmartDope and an associate professor of chemical engineering at <span class="glossaryLink" aria-describedby="tt" data-cmtooltip="

North Carolina State University

Founded in 1887 and part of the University of North Carolina system, North Carolina State University (also referred to as NCSU, NC State, or just State) is a public land-grant research university in Raleigh, North Carolina. NC State offers a wide range of academic programs and disciplines, including the humanities, social sciences, natural sciences, engineering, business, and education. It is known for its strong programs in engineering, science, and technology and is a leader in research and innovation. It forms one of the corners of the Research Triangle together with Duke University in Durham and The University of North Carolina at Chapel Hill. 

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“These particular quantum dots are of interest because they hold promise for next generation photovoltaic devices and other photonic and optoelectronic devices,” Abolhasani says. “For example, they could be used to improve the efficiency of solar cells, because they can absorb wavelengths of UV light that solar cells don’t absorb efficiently and convert them into wavelengths of light that solar cells are very efficient at converting into electricity.”

However, while these materials are very promising, there’s been a challenge in developing ways to synthesize quantum dots of the highest possible quality in order to maximize their efficiency at converting UV light into the desired wavelengths of light.

“We had a simple question,” Abolhasani says. “What’s the best possible doped quantum dot for this application? But answering that question using conventional techniques could take 10 years. So, we developed an autonomous lab that allows us to answer that question in hours.”

The Self-Driving Lab

The SmartDope system is a “self-driving” lab. To begin, the researchers tell SmartDope which precursor chemicals to work with and give it a designated goal. The goal in this study was to find the doped perovskite quantum dot with the highest “quantum yield,” or the highest ratio of photons the quantum dot emits (as infrared or visible wavelengths of light) relative to the photons it absorbs (via UV light).

Once it has received that initial information, SmartDope begins running experiments autonomously. The experiments are conducted in a continuous flow reactor that uses extremely small amounts of chemicals to conduct quantum dot synthesis experiments rapidly as the precursors flow through the system and react with each other. For each experiment, SmartDope manipulates a suite of variables, such as: the relative amounts of each precursor material; the temperature at which it mixes those precursors; and the amount of reaction time given whenever new precursors are added. SmartDope also characterizes the optical properties of the quantum dots produced by each experiment automatically as they leave the flow reactor.

“As SmartDope collects data on each of its experiments, it uses <span class="glossaryLink" aria-describedby="tt" data-cmtooltip="

machine learning

Machine learning is a subset of artificial intelligence (AI) that deals with the development of algorithms and statistical models that enable computers to learn from data and make predictions or decisions without being explicitly programmed to do so. Machine learning is used to identify patterns in data, classify data into different categories, or make predictions about future events. It can be categorized into three main types of learning: supervised, unsupervised and reinforcement learning.

” data-gt-translate-attributes=”[{"attribute":"data-cmtooltip", "format":"html"}]”>machine learning to update its understanding of the doped quantum dot synthesis chemistry and inform which experiment to run next, with the goal of making the best quantum dot possible,” Abolhasani says. “The process of automated quantum dot synthesis in a flow reactor, characterization, updating the machine learning model, and next-experiment selection is called closed-loop operation.”

Results and Conclusion

So, how well does SmartDope work?

“The previous record for quantum yield in this class of doped quantum dots was 130% – meaning the quantum dot emitted 1.3 photons for every <span class="glossaryLink" aria-describedby="tt" data-cmtooltip="

photon

A photon is a particle of light. It is the basic unit of light and other electromagnetic radiation, and is responsible for the electromagnetic force, one of the four fundamental forces of nature. Photons have no mass, but they do have energy and momentum. They travel at the speed of light in a vacuum, and can have different wavelengths, which correspond to different colors of light. Photons can also have different energies, which correspond to different frequencies of light.

” data-gt-translate-attributes=”[{"attribute":"data-cmtooltip", "format":"html"}]”>photon it absorbed,” Abolhasani says. “Within one day of running SmartDope, we identified a route for synthesizing doped quantum dots that produced a quantum yield of 158%. That’s a significant advance, which would take years to find using traditional experimental techniques. We found a best-in-class solution for this material in one day.

“This work showcases the power of self-driving labs using flow reactors to rapidly find solutions in chemical and material sciences,” Abolhasani says. “We’re currently working on some exciting ways to move this work forward and are also open to working with industry partners.”

The paper is published open access in the journal Advanced Energy Materials.

Reference: “Smart Dope: A Self-Driving Fluidic Lab for Accelerated Development of Doped Perovskite Quantum Dots” by Fazel Bateni, Sina Sadeghi, Negin Orouji, Jeffrey A. Bennett, Venkat S. Punati, Christine Stark, Junyu Wang, Michael C. Rosko, Ou Chen, Felix N. Castellano, Kristofer G. Reyes and Milad Abolhasani, 12 November 2023, Advanced Energy Materials.
DOI: 10.1002/aenm.202302303

The co-first authors of the paper are Fazel Bateni and Sina Sadeghi, Ph.D. students at NC State. The paper was co-authored by Negin Orouji and Michael Rosko, Ph.D. students at NC State; Jeffrey Bennett, a postdoctoral researcher at NC State; Venkat Punati, a master’s student at NC State; Christine Stark, an undergraduate at NC State; Felix Castellano, Goodnight Innovation Distinguished Chair in Chemistry at NC State; Junyu Wang and Ou Chen of Brown University; and Kristofer Reyes of the <span class="glossaryLink" aria-describedby="tt" data-cmtooltip="

University at Buffalo

Founded in 1846, the State University of New York at Buffalo is the largest campus in the State University of New York system and New York’s leading public center for graduate and professional education. It is a public research university with campuses in Buffalo and Amherst, New York, United States. It is commonly referred to as the University at Buffalo (UB) or SUNY Buffalo, and was formerly known as the University of Buffalo.

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The work was done with support from the National Science Foundation under grant number 1940959; the UNC Research Opportunities Initiative; and the Dreyfus Program for Machine Learning in the Chemical Sciences and Engineering, under award number ML-21-064.