Diamonds need voltage

January 21, 2021

Diamond, like graphite, is a special form of carbon. Its cubic crystal structure and its strong chemical bonds give it its unique hardness. For thousands of years, it has also been sought after as both a tool and as a thing of beauty. Only in the 1950s did it become possible to produce diamonds artificially for the first time.

Most natural diamonds form in the Earth's mantle at depths of at least 150 kilometres, where temperatures in excess of 1500 degrees Celsius and enormously high pressures of several gigapascals prevail - more than 10.000 times that of a well-inflated bicycle tyre. There are different theories for the exact mechanisms that are responsible for their formation. The starting material is carbonate-rich melts, i.e. compounds of magnesium, calcium or silicon which are rich in both oxygen and carbon.

A new pathway for the formation of diamonds

Because electro-chemical processes take place in the Earth's mantle and the melts and liquids that exist there can have a high electrical conductivity, researchers led by Yuri Palyanov of the V. S. Sobolev Institute of Geology and Mineralogy SB of the Russian Academy of Sciences Novosibirsk developed a model for the formation of diamonds in which highly localised electrical fields play a central role. According to this concept, applying less than even one volt - a voltage lower than that provided by most household batteries - provides electrons that trigger a chemical transformation process. These available electrons make it possible for certain carbon-oxygen compounds of the carbonates to become CO2 through a series of chemical reactions, ultimately leading to pure carbon in the form of diamond.

To test their theory, the Russian research team developed a sophisticated experimental facility: A millimetre-sized platinum capsule was surrounded by a heating system which in turn was placed in a high-pressure apparatus needed to produce immense pressures of up to 7.5 gigapascals. Tiny, carefully constructed electrodes led into the capsule, which had been filled with carbonate or carbonate-silicate powders. Numerous experiments were run at temperatures between 1300 and 1600°C, some of which lasted for as long as 40 hours.

Diamonds only grow with voltage

The experiments conducted in Novosibirsk showed, as predicted, that tiny diamonds grow in the vicinity of the negative electrode over the course of several hours, but this happened only when a small voltage was applied; half a volt was already enough. With a diameter reaching a maximum of 200 micrometres, i.e. one fifth of a millimetre, the newly created crystals were smaller than a typical grain of sand. Furthermore, as expected, the other pure-carbon mineral graphite was found to form in experiments conducted at lower pressures. Further proof of the new mechanism came when the researcher reversed the voltage polarity - diamonds then grew on the other electrode, exactly as expected. Without any voltage being suppled from outside the capsule neither graphite nor diamonds formed. In the vicinity of the diamonds, other minerals that are associated with the Earth's deep mantle were also found.

"The experimental facilities in Novosibirsk are absolutely impressive," says Michael Wiedenbeck, head of the SIMS laboratory at the GFZ, which is part of Potsdam's Modular Earth Science Infrastructure (MESI). He has been cooperating with the Russian researchers for more than ten years; he along with SIMS laboratory engineer Frédéric Couffignal, analysed diamonds produced by their Russian colleagues. In order to determine whether Yuri Palyanov's theory on diamond formation is completely correct, the isotopic composition of the diamonds had to be characterised very precisely.

Precision analysis "made in Potsdam"

The Potsdam researchers used secondary ion mass spectrometry (SIMS) for this purpose. The Potsdam instrument is a highly specialized mass spectrometer, providing geoscientists from all over the world with high precision data from extremely small samples. "With this technology we can determine the composition of tiny areas on sub-millimetre samples with great precision," says Wiedenbeck. Thus, less than one billionth of a gram from a laboratory produced diamond needed to be removed using a very precisely targeted ion beam. Electrically charged atoms were then injected into a six metre long apparatus which separated each the billions of particles based on their individual mass. This technology makes it possible to separate chemical elements, and in particular it is possible to distinguish their lighter or heavier variants known as isotopes. "In this way we have shown that the ratio between the carbon isotopes 13C to 12C behaves exactly according the model developed by our colleagues in Novosibirsk. With this, we have contributed to the final piece of the puzzle, so to speak, to confirm this theory," says Wiedenbeck. However, it must be noted that this new method is not suitable for the mass production of large artificial diamonds.

"Our results clearly show that electric fields should be considered as an important additional factor that influences the crystallisation of diamonds. This observation may prove to be quite significant for understanding carbon isotope ratios shifts within the global carbon cycle," Yuri Polyanov sums up.

Fig. 1:
Diamond produced under high pressure and additional voltage. (Photo: Yuliya Bataleva)

Fig. 2:
Less high pressures but - again - additional voltage leed to the formation of Graphite. (Photo: Yuliya Bataleva)

Fig. 3:
Multi-anvil high-pressure apparatus of the split-sphere type (BARS) was developed in the V.S. Sobolev Institute of Geology and Mineralogy, Siberian Branch of Russian Academy of Sciences. (Photo: Alexander Khokhryakov)

Fig. 4:
The Secondary Ion Mass Spectrometre (SIMS) at GFZ German Research Centre for Geosciences. (Photo: Michael Wiedenbeck)

GFZ GeoForschungsZentrum Potsdam, Helmholtz Centre

Related Carbon Articles from Brightsurf:

The biggest trees capture the most carbon: Large trees dominate carbon storage in forests
A recent study examining carbon storage in Pacific Northwest forests demonstrated that although large-diameter trees (21 inches) only comprised 3% of total stems, they accounted for 42% of the total aboveground carbon storage.

Carbon storage from the lab
Researchers at the University of Freiburg established the world's largest collection of moss species for the peat industry and science

Carbon-carbon covalent bonds far more flexible than presumed
A Hokkaido University research group has successfully demonstrated that carbon-carbon (C-C) covalent bonds expand and contract flexibly in response to light and heat.

Metal wires of carbon complete toolbox for carbon-based computers
Carbon-based computers have the potential to be a lot faster and much more energy efficient than silicon-based computers, but 2D graphene and carbon nanotubes have proved challenging to turn into the elements needed to construct transistor circuits.

Cascades with carbon dioxide
Carbon dioxide (CO(2)) is not just an undesirable greenhouse gas, it is also an interesting source of raw materials that are valuable and can be recycled sustainably.

Two-dimensional carbon networks
Lithium-ion batteries usually contain graphitic carbons as anode materials. Scientists have investigated the carbonic nanoweb graphdiyne as a novel two-dimensional carbon network for its suitability in battery applications.

Can wood construction transform cities from carbon source to carbon vault?
A new study by researchers and architects at Yale and the Potsdam Institute for Climate Impact Research predicts that a transition to timber-based wood products in the construction of new housing, buildings, and infrastructure would not only offset enormous amounts of carbon emissions related to concrete and steel production -- it could turn the world's cities into a vast carbon sink.

Investigation of oceanic 'black carbon' uncovers mystery in global carbon cycle
An unexpected finding published today in Nature Communications challenges a long-held assumption about the origin of oceanic black coal, and introduces a tantalizing new mystery: If oceanic black carbon is significantly different from the black carbon found in rivers, where did it come from?

First fully rechargeable carbon dioxide battery with carbon neutrality
Researchers at the University of Illinois at Chicago are the first to show that lithium-carbon dioxide batteries can be designed to operate in a fully rechargeable manner, and they have successfully tested a lithium-carbon dioxide battery prototype running up to 500 consecutive cycles of charge/recharge processes.

How and when was carbon distributed in the Earth?
A magma ocean existing during the core formation is thought to have been highly depleted in carbon due to its high-siderophile (iron loving) behavior.

Read More: Carbon News and Carbon Current Events is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to