The researchers revealed how long-distance pull may overcome energy barriers and bring together otherwise unreactive molecules, potentially paving the way for a new approach to organic molecule synthesis.
Pulse radiolysis experiments demonstrate how unpaired electrons at one end of a molecule can initiate chemistry at ‘distant’ locations.
Researchers at the Brookhaven National Laboratory of the U.S. Department of Energy (DOE) helped in measuring how unpaired electrons in atoms at one end of a molecule can drive chemical reactivity on the molecule’s opposite side. This discovery, done in partnership with Princeton University, is described in a paper that was recently published in the Journal of the American Chemical Society. It demonstrates how molecules containing these ‘free radicals’ might be used in a whole new class of reactions.
“Most reactions involving free radicals take place at the site of the unpaired electron,” explained Brookhaven Lab chemist Matthew Bird, one of the co-corresponding authors on the paper. The Princeton team had become experts in using free radicals for a range of synthetic applications, such as polymer upcycling. But they’ve wondered whether free radicals might influence reactivity on other parts of the molecule as well, by pulling electrons away from those more distant locations.
This research relied on the combined resources of a Princeton University-led DOE Energy Frontier Research Center (EFRC) focused on Bio-Inspired Light Escalated Chemistry (BioLEC). Co-authors included Matthew Bird (Brookhaven Lab), Robert Knowles (Princeton), and Nick Shin (Princeton graduate student). Credit: Brookhaven National Laboratory and Princeton University
“Our measurements show that these radicals can exert powerful ‘electron-withdrawing’ effects that make other parts of the molecule more reactive,” Bird said.
The Princeton team demonstrated how that long-distance pull can overcome energy barriers and bring together otherwise unreactive molecules, potentially leading to a new approach to organic molecule synthesis.
Combining capabilities
The research used the resources of a DOE Energy Frontier Research Center (EFRC) directed by Princeton that is focused in Bio-Inspired Light Escalated Chemistry (BioLEC). The collaboration brings together top synthetic chemists and organizations with cutting-edge spectroscopic techniques for analyzing reactions. Its funding was recently renewed for an additional four years.
Robert Knowles, who led Princeton’s role in this research, said, “This project is an example of how BioLEC’s combined expertise enabled the team to quantify an important physical property of these radical species, that in turn allowed us to design the resulting synthetic methodology.”
The Laser Electron Accelerator Facility (LEAF) generates intense high-energy electron pulses that allow scientists to add or subtract electrons from molecules to make chemically reactive species and monitor what happens as a reaction proceeds. Credit: Brookhaven National Laboratory
The Brookhaven team’s major contribution is a technique called pulse radiolysis—available only at Brookhaven and one other location in the U.S.
“We use the Laser Electron Accelerator Facility (LEAF)—part of the Accelerator Center for Energy Research (ACER) in Brookhaven’s Chemistry Division—to generate intense high-energy electron pulses,” Bird explained. “These pulses allow us to add or subtract electrons from molecules to make reactive species that might be difficult to make using other techniques, including short-lived reaction intermediates. With this technique, we can step into one part of a reaction and monitor what happens.”
For the current study, the team used pulse radiolysis to generate molecules with oxygen-centered radicals, and then measured the “electron-withdrawing” effects on the other side of the molecule. They measured the electron pull by tracking how much the oxygen at the opposite side attracts protons, positively charged ions sloshing around in solution. The stronger the pull from the radical, the more acidic the solution has to be for protons to bind to the molecule, Bird explained.
The Brookhaven team used pulse radiolysis to make a molecule with an oxygen-free radical (O•). The electron-withdrawing pull of the O• causes the positive proton, H+, to come off the opposite OH group. To measure the strength of that pull, the scientists gradually increased the concentration of H+s in the solution (making it more acidic), until an H+ bound to the molecule again causing a color change they could detect using spectroscopy. The high acidity at which this happened indicated a very strong electron-withdrawing pull. Credit: Brookhaven National Laboratory
The Brookhaven scientists found the acidity had to be high to enable proton capture, meaning the oxygen radical was a very strong electron-withdrawing group. That was good news for the Princeton team. They then demonstrated that it’s possible to exploit the “electron-withdrawing” effect of oxygen radicals by making parts of molecules that are generally inert more chemically reactive.
“The oxygen radical induces a transient ‘polarity reversal’ within the molecule—causing electrons that normally want to remain on that distant side to move toward the radical to make the ‘far’ side more reactive,” Bird explained.
These findings enabled a novel substitution reaction on phenol-based starting materials to make more complex phenol products.
“This is a great example of how our technique of pulse radiolysis can be applied to cutting-edge science problems,” said Bird. “We were delighted to host an excellent graduate student, Nick Shin, from the Knowles group for this collaboration. We look forward to more collaborative projects in this second phase of BioLEC and seeing what new problems we can explore using pulse radiolysis.”
Reference: “Radicals as Exceptional Electron-Withdrawing Groups: Nucleophilic Aromatic Substitution of Halophenols Via Homolysis-Enabled Electronic Activation” by Nick Y. Shin, Elaine Tsui, Adam Reinhold, Gregory D. Scholes, Matthew J. Bird and Robert R. Knowles, 17 November 2022, Journal of the American Chemical Society.
DOI: 10.1021/jacs.2c10296
Brookhaven Lab’s role in this work and the EFRC at Princeton were funded by the DOE Office of Science (BES). Princeton received additional funding for the synthesis work from the National Institutes of Health.
Source: SciTechDaily
