Toward overcoming solubility issues in organic chemistry

Toward overcoming solubility issues in organic chemistry
Insoluble reactants are hardly reactive in solution, but may react in solvent-free systems using ball milling to drive chemical reactions in the solid state. Credit: Tamae Seo, et al. Journal of the American Chemical Society. March 30, 2021

Scientists from Hokkaido University have developed a rapid, efficient protocol for cross-coupling reactions, vastly expanding the pool of chemicals that can be used for the synthesis of useful organic compounds.

Chemical reactions are a vital process in the of products for a diversity of purposes. For the most part, these reactions are carried out in the liquid phase, by dissolving the reactants in a solvent. However, there are a significant number of chemicals that are partially or completely insoluble, and thus have not been used for synthesis. The starting materials required for the synthesis of many cutting-edge organic materials—such as organic semiconductors and luminescent materials—are often poorly soluble, leading to problems in solution-based synthesis. Therefore, the development of a solvent-independent synthetic approach to overcome these long-standing solubility issues in organic synthesis is highly desired to synthesize new valuable organic molecules.

In recent years, synthetic techniques using ball milling have been used to carry out solvent-free reactions in the . It has been proposed that the use of ball milling would potentially overcome the aforementioned solubility issues in synthetic chemistry, but a systematic study for such purpose has never been carried out.

A team of four scientists from Hokkaido University's Institute for Chemical Reaction Design and Discovery (WPI-ICReDD), led by Associate Professor Koji Kubota and Professor Hajime Ito, have developed a rapid, efficient, solvent-free protocol for Suzuki−Miyaura cross-coupling reaction of insoluble aryl halides. The protocol was published in the Journal of the American Chemical Society.

Toward overcoming solubility issues in organic chemistry
When pigment violet 23, one of the mostly-insoluble aryl halides, was subjected to the reaction with an aryl boron nucleophile at 120 °C in a ball mill in the presence of the palladium-based catalytic system, it was converted to a product 3u that was strongly photoluminescent when dissolved in dichloromethane. Credit: Tamae Seo, et al. Journal of the American Chemical Society. March 30, 2021

Aryl halides are popular starting materials for the synthesis of organic functional molecules, primarily by the palladium-catalyzed Suzuki-Miyaura cross-coupling reaction—for which Hokkaido University's Professor Emeritus Akira Suzuki shared the 2010 Nobel Prize in Chemistry. Although the have been employed for the synthesis of a wide range of valuable molecules, insoluble aryl halides are not suitable substrates because Suzuki-Miyaura cross-coupling reactions have primarily been carried out in solution.

Given this limitation, the scientists focused on the development of an efficient solid-state Suzuki-Miyaura cross-coupling of a number of extremely unreactive insoluble aryl halides. The key equipment consisted of a ball mill, for mixing the reactants; a heat gun, to increase the temperature at which the reactions took place; and the use of a catalytic system composed of palladium acetate (the catalyst), SPhos (a high-performance ligand for Suzuki−Miyaura cross-coupling reactions) and 1,5-cyclooctadiene (dispersant and stabilizer).

The capstone of this study was the application of the solvent-free solid-state reaction to mostly-insoluble aryl halides. These reactants did not yield any products in conventional solution-based reactions. The solid-state reactions using the high-temperature ball milling, however, gave the desired products. Importantly, the team discovered a new strong photoluminescence material prepared from insoluble pigment violet 23.

"The high-temperature ball-milling technique and our catalytic system are essential for these reactions of insoluble aryl halides, and the protocol we have developed expands the diversity of organic molecules derived from insoluble starting materials," says Koji Kubota.


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More information: Tamae Seo et al. Tackling Solubility Issues in Organic Synthesis: Solid-State Cross-Coupling of Insoluble Aryl Halides, Journal of the American Chemical Society (2021). DOI: 10.1021/jacs.1c00906
Citation: Toward overcoming solubility issues in organic chemistry (2021, May 18) retrieved 21 June 2021 from https://phys.org/news/2021-05-solubility-issues-chemistry.html
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