The professor has been awarded the DOE Award for Printable Electronics, according to 3DPrinting.com.

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University of Arizona professor, Adam Printz, has recently been granted a substantial sum of money by the Department of Energy Office of Science Early Career Research Program. This grant, amounting to $875,000, is in recognition of his contributions to the field of printable electronics. While this accomplishment deserves celebration, it is essential to understand the significance of Professor Printz’s work in order to fully appreciate the potential impact it can have on various industries.

Printable electronics, as the name suggests, involves the creation of electronic devices on flexible substrates. This innovation opens up a world of possibilities, including rollable TVs and solar-coated buildings. However, despite its immense potential, the challenge lies in mass production. This is where Professor Printz’s research comes into play.

His work focuses on a unique printing technique known as restricted area printing by ink drawing (RAPID). Unlike conventional methods, RAPID confines ink between two plates, thereby controlling solvent evaporation for high-quality film printing. However, the fundamental principles of this process are not yet fully understood.

To unravel this mystery, the project comprises three main research areas. The first involves investigating how the ratio of surface area to bulk affects crystal nucleation – essentially, altering the ink volume while keeping the surface area constant should provide insights into the role of volume in crystallization.

The second research area aims to comprehend crystal growth patterns in thin films. By understanding how different growth modes occur, it may be possible to gain precise control over film properties.

Lastly, the project seeks to explore the interplay between substrate surface energy and chemistry, as these factors greatly influence crystal nucleation rates.

According to Professor Printz, much of the current work in this field is optimization driven, meaning it involves trial and error to determine the ideal temperature and print speed. However, by gaining a deep understanding of the underlying principles and mechanisms of these processes, it will be possible to predict outcomes under different conditions. This knowledge will ultimately provide the control necessary to produce high-quality electronic devices consistently.

Professor Printz’s ultimate goal is to unravel the intricacies of printable electronics. With this comprehensive understanding, researchers will be able to exert precise control over the printing process, leading to the creation of superior electronic devices.

The significance of this research goes beyond the immediate applications in rollable TVs and solar-coated buildings. Printable electronics have the potential to revolutionize numerous industries, from healthcare to automotive, by enabling the production of flexible and lightweight electronic components.

In conclusion, Professor Adam Printz’s research in printable electronics has been rightfully recognized through a substantial grant. By delving into the fundamental principles of the printing process, he aims to provide the knowledge and control necessary to bring this technology to its full potential. The future of electronic devices is on the cusp of a significant transformation, thanks to the work of individuals like Professor Printz.

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