Computer-designed molecule to clean up fluorocarbons?
The chemical bond between carbon and fluorine is
one of the strongest in nature, and has been both a blessing and a
curse in the complex history of fluorocarbons. Now, in a powerful
demonstration of the relatively new field of "computational chemistry,"
researchers at the National Institute of Standards and Technology
(NIST) and the Interdisciplinary Network of Emerging Science and
Technology group (INEST, sponsored by Philip Morris USA) have designed
- in a computer - a wholly theoretical molecule to pull the fluorine
out of fluorocarbons.
Postmortem: Computer modeling
rendition of the proposed carbon-fluorine bond-breaking macrocycle
after reaction with a molecule of methyl fluoride (CH3F).
Highlighted in the center of the macrocycle, the CH3 fragment has
attached to a nitrogen atom, separating it from the fluorine atom
which has been grabbed by a group of four hydrogen atoms. The
potentially toxic components of the fluorocarbon are immobilized
in the macrocycle until removed by a second reaction, an important
feature for possible filtering systems.
Image by NIST
At sea level, the strong C-F bond makes
fluorocarbons thermally and chemically stable. As a result,
fluorocarbons have been used in many commercial applications including
refrigerants, pesticides and non-stick coatings. In the upper
atmosphere, however, high-energy photons and highly reactive ozone
molecules can break apart fluorocarbons, with the well-known
consequence of a depleted ozone layer and increased ultraviolet
radiation at ground level. A determined chemist can break down
fluorocarbons at ground level with certain organometallic compounds,
but the reactions take a long time at very high temperatures. Other
known reagents are both highly toxic and inefficient, so chemists have
been searching for an economical and environmentally friendly method
to dispose of fluorocarbons.
Reasoning that the problem already may have been
solved by nature, the NIST/Philip Morris team looked to an enzyme
called fluoroacetate dehalogenase used by a South African bacterium,
Burkholderia sp. The enzyme enables the bacterium to pull the fluoride
ion out of sodium fluoroacetate (disrupting a poisonous compound) at
room temperature and without problematic metal ions. Enzymes are giant
molecules, evolved to survive and work in the complex environment of a
living organism; they can be difficult and expensive to adapt to an
industrial process. Instead, the research team applied basic quantum
mechanical theory of electron structures in molecules, together with
the example of a known molecule that binds to and extracts chlorine
ions, to calculate the make-up and geometry of the critical "active
site" in the enzyme that does the work. They then designed in software
a large ring-shaped molecule to hold those components in just the
right orientation to break the C-F bond in methyl fluoride, a simple
fluorocarbon.
Researchers at the University of Texas now are
synthesizing the new molecule to test its effectiveness. If it matches
theoretical predictions, it will be the first example of a simple
organic molecular system able to break C-F bonds without extreme
temperature and pressure conditions, and a demonstration of a novel
technique for designing man-made molecules that can mimic the
extraordinary selectivity and chemical activity of natural enzymes.
Notes lead researcher Carlos Gonzalez, "All of these useful things are
in nature, you just have to find them and make them more efficient."
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