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Study reveals breach of 'dancing' barrier governs crystal growth

Controlling crystal growth for innovations in medicine, engineering

Date:
November 12, 2019
Source:
University of Illinois at Chicago
Summary:
Researchers used computer-based simulations to analyze how atoms and molecules move in a solution and identified a general mechanism governing crystal growth that scientists can manipulate when developing new materials.
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FULL STORY

While crystals have been studied for centuries and are ubiquitous in daily life -- they are in our bones, the food we eat and the batteries we use -- scientists still don't fully understand how crystals grow or how to efficiently manufacture them. As a result, scientific efforts to improve a wide range of crystalline materials, from self-healing biomaterials to solar panels, have been limited.

Researchers at the University of Illinois at Chicago have unlocked part of this mystery. By using computer-based simulations to analyze how atoms and molecules move in a solution, the UIC team has identified a general mechanism governing crystal growth that scientists can manipulate when developing new materials.

Specifically, they found that when crystal-forming molecules are surrounded by a solvent, like water, the solvent molecules form a shield that they call a solvation shell. When this shield fluctuates, molecules can break free to form crystals. They also showed that temperature, solvent type and the number of solvent molecules all affect the shell's fluctuation.

Their findings are reported in the journalProceedings of the National Academy of Sciences.

"For the first time, we have shown what happens when a molecule leaves a solvent to form a crystal," said Meenesh Singh, senior author and assistant professor of chemical engineering at the UIC College of Engineering. "Under the right conditions, the shield 'dances' around and allows molecules to break free and integrate into the crystal surface. The fluctuations in the solvation shell are key molecular events that explain how crystals form -- knowledge of this mechanism has been missing since the inception of crystallization research."

Singh said understanding this mechanism will provide scientists with greater ability to direct molecules to form crystals for specific structure, shape and size. "This will allow us to make better materials for a wide class of products used in daily life," he said.

一些例子,他说,骨植入推广te biomineralization, better drug delivery systems, more stable lithium batteries, and improved semiconductors and agricultural chemicals.

"The molecular insight gained from this study will also help save money in various chemical industries by reducing the need for hit or miss techniques in thousands of trials," said UIC graduate student Anish Dighe, co-author of the paper. "With the help of this study, we can now design systems that can crystallize the desired solute molecule without so many trials."

This study is funded in part by the National Science Foundation (CBET-1706921).

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Story Source:

Materialsprovided byUniversity of Illinois at Chicago.Note: Content may be edited for style and length.


Journal Reference:

  1. Anish V. Dighe, Meenesh R. Singh.Solvent fluctuations in the solvation shell determine the activation barrier for crystal growth rates.Proceedings of the National Academy of Sciences, 2019; 201910691 DOI:10.1073/pnas.1910691116

Cite This Page:

University of Illinois at Chicago. "Study reveals breach of 'dancing' barrier governs crystal growth: Controlling crystal growth for innovations in medicine, engineering." ScienceDaily. ScienceDaily, 12 November 2019. .
University of Illinois at Chicago. (2019, November 12). Study reveals breach of 'dancing' barrier governs crystal growth: Controlling crystal growth for innovations in medicine, engineering.ScienceDaily. Retrieved July 10, 2023 from www.koonmotors.com/releases/2019/11/191112142924.htm
University of Illinois at Chicago. "Study reveals breach of 'dancing' barrier governs crystal growth: Controlling crystal growth for innovations in medicine, engineering." ScienceDaily. www.koonmotors.com/releases/2019/11/191112142924.htm (accessed July 10, 2023).

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