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Chemists
forge a new form of iron
June 1,
2006
by Terry
Devitt
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A
rendering of the molecular structure of a new species of
iron, iron VI. The new form of iron has just two electrons in
its outermost shell, making it a potentially valuable new
catalyst for industry and biomedicine. An international team
of chemists recently discovered the new form of iron and are
publishing a paper describing the element in the June 1, 2006
online edition of Science, called Science Express. The lead
author of the study is John F. Berry, an Alexander von
Humboldt postdoctoral fellow at Germany’s Max-Planck
Institute for Bioinorganic Chemistry in Mülheim who
recently was named an assistant professor of chemistry at
UW-Madison.
Photo
by: courtesy
Max-Planck Institute for Bioinorganic Chemistry
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An international team of
chemists has discovered a new and unexpected form of iron, a
finding that adds to the fundamental understanding of an element
that is among the most abundant on Earth and that, in nature, is
an essential catalyst for life.
"We have synthesized
something totally new that nobody has imagined could exist, and
something which adds greatly to our understanding of fundamental
iron chemistry," says John F. Berry, an Alexander von
Humboldt postdoctoral fellow at Germany's Max-Planck Institute
for Bioinorganic Chemistry in Mulheim. Berry, recently named an
assistant professor of chemistry at the University of
Wisconsin-Madison, is the lead author of a paper describing the
new species of iron in this week's (June 1) online edition of
Science, Science Express.
In addition to its role in the
manufacture of thousands of everyday objects, iron, in its
various manifestations, is widely known and used for its reactive
properties. It occurs in nature in different ionized forms and is
essential for the health and well being of virtually all kinds of
life. Blood, for instance, is red because of the presence of iron
II ions in hemoglobin.
The form that the metal takes
is dependent on the number of electrons in the iron atom's
outermost shell, known as valence electrons (there are eight in
an ordinary iron atom). Iron can occur in different ionized forms
determined by the number of valence electrons, which are
essential for forming chemical bonds with other atoms.
"The valence electrons of
an ion are those mainly responsible for how the ion reacts,"
Berry explains.
The new species of iron found
by Berry and his colleagues is designated iron VI, which means
the atom has just two valence electrons and is highly reactive as
it seeks to regain iron's eight-electron stable configuration by
grabbing electrons from atoms of other elements. The new form is
so reactive it can only be studied at low temperatures, in this
case minus 40 degrees F.
Iron VI is a designation that
describes an oxidation state. In chemistry, oxidation state is a
bookkeeping device to keep track of the number of valence
electrons an atom has in its outermost shell when bonded to atoms
of other elements. Ionized forms of iron, the most common being
iron II and iron III, have varying numbers of electrons as they
add or shed electrons when combined with atoms of other elements.
"Iron VI is a very rare
oxidation state," explains UW-Madison chemistry professor
Bassam Shakhashiri. "Synthesizing it and characterizing it
are important to understanding different transition metals and
their catalytic properties. This is a major contribution to
understanding metals in different forms and different oxidation
states."
Identifying a new species of
iron is important, Shakhashiri adds, not only because it promises
new insight into the chemistry of a common and already
economically important element, but also because it opens a door
to the future development of novel compounds for use in industry
and biomedicine.
Of note is the fact the new
iron compound includes nitrogen, whereas the only other known
iron VI species, known as ferrate, carries oxygen.
"We hope that this complex
will have practical advantages over other iron compounds, and we
might expect that it does based on its structure," Berry
says. "Whereas the ferrate ion easily transfers an oxygen
atom to organic substrates, we might expect that our complex may
transfer a nitrogen atom instead. This sort of reactivity is
becoming more important in organic synthesis since it allows new
synthetic pathways to nitrogen-containing organic molecules which
are very important and have widespread utility."
The discovery of the new iron
compound, Berry says, was the unexpected consequence of studying
an iron IV compound. "During the course of our studies, we
found that it was very light sensitive and changed color from
cherry red to bright yellow when it was irradiated at 77 K (minus
321 F). We were really quite surprised when we found the first
evidence that we had formed an iron VI ion."
With the new compound in hand,
the next steps will be to explore how it reacts with other
chemicals and how it might be put to use. "Now that we have
made it, we can use our imagination to discover the reactivity of
the compound, the reasons for its stability, synthetic routes to
other compounds like this one, and practical uses for this new
chemistry," says Berry.
In addition to Berry, authors
of the new Science report include Karl Wieghardt, Eckhard Bill,
Eberhard Bothe, Bernd Mienert and Frank Neese of the Max-Planck
Institute for Bioinorganic Chemistry in Mulheim; and Serena
DeBeer George of the Stanford Synchrotron Radiation Laboratory.
Source
/ Credit: University of Wisconsin, Madison
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