Challenging a central dogma of chemistry: Energy flow in chemical
reactions
Date:
July 30, 2020
Source:
Institute for Basic Science
Summary:
Researchers have discovered that common chemical reactions
accelerate Brownian diffusion by sending long-range ripples into
the surrounding solvent.
FULL STORY ========================================================================== Steve Granick, Director of the IBS Center for Soft and Living Matter
and Dr.
Huan Wang, Senior Research Fellow, report together with 5
interdisciplinary colleagues in the July 31 issue of the journal Science
that common chemical reactions accelerate Brownian diffusion by sending long-range ripples into the surrounding solvent.
==========================================================================
The findings violate a central dogma of chemistry, that molecular
diffusion and chemical reaction are unrelated. To observe that
molecules are energized by chemical reaction is "new and unknown,"
said Granick. "When one substance transforms to another by breaking and
forming bonds, this actually makes the molecules move more rapidly. It's
as if the chemical reactions stir themselves naturally." "Currently,
Nature does an excellent job of producing molecular machines but in the
natural world scientists have not understood well enough how to design
this property," said Wang. "Beyond curiosity to understand the world,
we hope that practically this can become useful in guiding thinking
about transducing chemical energy for molecular motion in liquids,
for nanorobotics, precision medicine and greener material synthesis."
The unexpected ripples generated by chemical reactions, especially when catalyzed (accelerated by substances not themselves consumed), propagate
long- range. For chemists and physicists, this work challenges the
textbook view that molecular motion and chemical reaction are decoupled,
and that reactions affect only the nearby vicinity. For engineers,
this work shows a powerful new approach to design nanomotors at the
truly molecular level.
Screening 15 organic chemical reactions, the researchers study chemical reactions that are workhorses with wide application within the organic chemical, pharmaceutical and materials industries. For example, "click" reactions assist the assembly of libraries of biomedical compounds for screening and the "Grubbs" reaction used for plastic manufacture. Their economic impact is major. Estimates indicate that a majority of all
products manufactured require catalysis somewhere in their production
sequence.
Wang remarked with enthusiasm: "Now, we're like a baby taking her first
steps and there's so much exciting opportunity to grow this baby."
In designing their study, the researchers were bio-inspired by noticing
that motion can be powered by enzymes and other molecular motors that
are prevalent in living systems. Pioneering earlier work by Dr. Ah-Young
Jee in the same research center showed this. But there was no consensus
among scientists if these reports could be correctly extended outside
biology. Analyzing the problem, the researchers made a high-risk,
high-payoff argument. They hypothesized that the phenomenon would form
an approach to understand molecular machines in the real world.
Testing their hypothesis, the team developed new analytical techniques.
Professor Tsvi Tlusty, a theorist, predicted that catalysts in reaction gradients should migrate "uphill" in the direction of lesser diffusivity.
Professor Yoon-Kyoung Cho, a microfluidics expert, designed a tailor-made microfluidics chip to test this idea. Dr. Ruoyu Dong, a Research Fellow, performed numerical computer simulations. "Our interdisciplinary team
responded incredibly quickly to the research opportunities thanks to the research freedom of the Korean Institute for Basic Science," said Granick.
The team presents guidelines showing that the magnitude of diffusion
increase in different systems depends on the energy release rate. These guidelines can be useful practically to estimate the effect in as-yet
untested reactions.
Beyond this, the study is very useful for expanding understanding of
active materials, a collective term that traditionally refers to things
like cells and microorganisms.
Granick concluded: "The field of active materials, quite new and growing
fast, is enriched by this discovery that chemical reactions behave as nanoswimmers made of individual molecules that stir up the reaction
soup. The concept of active materials has shown its value in challenging
a central dogma of chemistry." These findings were published in the
July 31, 2020 issue of Science magazine.
The study was performed at the IBS Center for Soft and Living Matter by
authors Huan Wang, Myeonggon Park, Ruoyu Dong, Junyoung Kim, Yoon-Kyoung
Cho, Tsvi Tlusty, and Steve Granick.
========================================================================== Story Source: Materials provided by Institute_for_Basic_Science. Note:
Content may be edited for style and length.
========================================================================== Journal Reference:
1. Huan Wang, Myeonggon Park, Ruoyu Dong, Junyoung Kim, Yoon-Kyoung
Cho,
Tsvi Tlusty, Steve Granick. Boosted molecular mobility during common
chemical reactions. Science, 2020 DOI: 10.1126/science.aba8425 ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2020/07/200730141259.htm
--- up 2 weeks, 1 day, 1 hour, 54 minutes
* Origin: -=> Castle Rock BBS <=- Now Husky HPT Powered! (1337:3/111)