It would be rather nice to
actually produce and contain the suggested pressures. Here we are modeling them to learn of their
characteristics and of course there may always be error or a failure of theory. I am keen to know a lot about carbon under similar
pressures.
As interesting, I would love to
know something certain about the nature of the Earth’s core as I am also fairly
sure we get none of it transported up into the upper crustal zone.
The assumption even of the
massive pressures we expect may not hold up so well. Recall diamonds come from a mere eighty miles
down.
This is all important to our
understanding of Earth science and the actual structure of the planet, yet it
has all been built on a system of assumptions and extrapolations that appear
reasonable but remain untestable.
More recent thoughts on the
nature of gravity allows me a broader perspective and even the idea of a hollow
planet which appears preposterous may not be dismissed out of hand. All this again begs the question of ’what is
gravity?’
Oxygen molecule survives to enormously high pressures
by Staff Writers
Structures of solid oxygen under high pressure: At 1.9 TPa, oxygen
polymerizes and assumes a square spiral-like structure, which is
semi-conducting (top). With increasing pressure, the polymer exhibits metallic
properties (zig-zag chain-like phase, mid). Then, the structure changes into a
metallic layer phase (bottom). The coloured areas represent the charge density
in one layer of the structure. Image courtesy Jian Sun.
Using computer simulations, a RUB researcher has shown that the oxygen molecule (O2)
is stable up to pressures of 1.9 terapascal, which is about nineteen million times
higher than atmosphere pressure. Above that, it polymerizes, i.e. builds larger
molecules or structures.
"This is very surprising" says Dr. Jian Sun from the
Department of Theoretical Chemistry. "Other simple molecules like nitrogen
or hydrogen do not survive such high pressures."
In cooperation with colleagues from University
College London ,
the University of Cambridge , and the NationalResearch Council
of Canada
Weaker bonds, greater stability
The oxygen atoms in the O2 molecule are held together by a double covalent bond. Nitrogen (N2), on the other hand, possesses a triple bond. "You would think that the weaker double bond is easier to break than the triple bond and that oxygen would therefore polymerize at lower pressures than nitrogen" says Sun. "We found the opposite, which is astonishing at first sight."
However, in the condensed phase when pressure increases, the molecules
become closer to each other. The research team suggests that, under these
conditions, the electron lone pairs on different molecules repel one another
strongly, thus hindering the molecules from approaching each other.
Since oxygen has more lone pairs than nitrogen, the repulsive force
between these molecules is stronger, which makes polymerization more difficult.
However, the number of lone pairs cannot be the only determinant of the
polymerization pressure. "We believe that it is a combination of the
number of lone pairs and the strength of the bonds between the atoms",
says Sun.
The many structures of oxygen
At high pressures, gaseous molecules such as hydrogen, carbon monoxide,
or nitrogen polymerize into chains, layers, or framework structures. At the
same time they usually change from insulators to metals, i.e. they become more
conductive with increasing pressure.
The research team, however, showed that things are more complicated
with oxygen. Under standard conditions, the molecule has insulating properties.
If the pressure increases, oxygen metallises and becomes a superconductor.
With further pressure increase, its structure changes into a polymer
and it becomes semi-conducting. If the pressure rises even more, oxygen once
more assumes metallic properties, meaning that the conductivity goes up again.
The metallic polymer structure finally changes into a metallic layered
structure.
Inside planets
"The polymerization of small molecules under high pressure has attracted much attention because it helps to understand the fundamental physics and chemistry of geological and planetary processes" explains Sun. "For instance, the pressure at the centre of Jupiter is estimated to be about seven terapascal.
It was also found that polymerized molecules, like N2 and CO2, have
intriguing properties, such as high energy densities and super-hardness."
Dr. Jian Sun joined the RUB-research group of Prof. Dr. Dominik Marx as a Humboldt
Research Fellow in 2008 to work on
vibrational spectroscopy of aqueous solutions. In parallel to this joint work
in "Solvation Science" he developed independent research interests
into high pressure chemical physics as an Early Career Researcher.
J. Sun, M. Martinez-Canales, D.D. Klug, C.J. Pickard, R.J. Needs
(2012): Persistence and eventual demise of oxygen molecules at terapascal
pressures, Physical Review Letters, doi: 10.1103/PhysRevLett.108.045503
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