Home > Press > Chemists synthesize ‘flat’ silicon compounds: The molecules generated at the University of Bonn are very stable despite their unusual spatial shape
3D representation of one of the new molecules. Silicate ions in tetrahedral arrangement can be seen in the spherical soap bubbles for comparison.
CREDIT © Jens Rump / University of Bonn |
Abstract:
Chemists at the University of Bonn (Germany) have synthesized extremely unusual compounds. Their central building block is a silicon atom. Different from usual, however, is the arrangement of the four bonding partners of the atom, which are not in the form of a tetrahedron around it, but flat like a trapezoid. This arrangement is usually energetically extremely unfavorable, yet the molecules are very stable. Their properties are completely unknown so far; researchers now want to explore them. The results will be published in the Journal of the American Chemical Society, but are already available online.
Chemists synthesize ‘flat’ silicon compounds: The molecules generated at the University of Bonn are very stable despite their unusual spatial shape
Bonn, Germany | Posted on December 25th, 2020
Like its relative carbon, silicon generally forms four bonds with other atoms. When it does, the result is usually a tetrahedron. The silicon atom is located in the center, its bonding partners (the so-called ligands) at the tetrahedral corners. This arrangement is most favorable energetically. It therefore arises quasi automatically, just as a soap bubble is usually spherical.
Researchers led by Prof. Dr. Alexander C. Filippou of the Institute for Inorganic Chemistry at the University of Bonn have now constructed silicon-containing molecules that are as unusual as a cube-shaped soap bubble. In these, the four ligands do not form a tetrahedron, but a distorted square, a trapezoid. They lie in one plane together with the silicon. “Despite this, the compounds are so stable that they can be filled into bottles and stored for weeks without any problems,” explains Dr. Priyabrata Ghana, a former doctoral student who has since moved to RWTH Aachen University.
Molecular exotics are unusually stable
The researchers themselves were surprised by this unusual stability. They discovered the reason by modeling the molecules on the computer. The ligands also form bonds with each other. In the process, they form a solid framework. This appears to be so strong that it completely prevents the trapezoidal arrangement from “snapping” into a tetrahedron. “Our computer calculations indicate that there is no structure for the molecules that would be more energetically favorable than the planar trapezoidal shape,” emphasizes Jens Rump, a doctoral student at the Institute for Inorganic Chemistry.
The researchers grew crystals of the substances and then blasted them with X-rays. The X-ray light is scattered by the atoms and changes its direction. These deviations can therefore be used to calculate the spatial structure of the molecules in the crystal. Together with spectroscopic measurements, this method confirmed that ligands and silicon are indeed in the same plane in the new molecules.
Although the synthesis of the exotic compounds must be carried out under inert gas, it is otherwise comparatively simple. Producing the starting materials, on the other hand, is complex; one of them was first synthesized only just over ten years ago and has already been the source for the synthesis of several novel classes of silicon compounds.
The influence of the unusual structure on the properties of silicon, an important element for the electronics industry, is completely unclear at the moment. At any rate, for a long time it was considered completely impossible to produce such compounds.
####
For more information, please click here
Contacts:
Jens Rump (University of Bonn)
49-228-735-805
@unibonn
Copyright © University of Bonn
If you have a comment, please Contact us.
Issuers of news releases, not 7th Wave, Inc. or Nanotechnology Now, are solely responsible for the accuracy of the content.
News and information
Experiment takes ‘snapshots’ of light, stops light, uses light to change properties of matter December 25th, 2020
Scientists suggested a method to improve performance of methanol fuel cells December 25th, 2020
Understanding nanoparticle entry mechanism into tumors December 25th, 2020
Chemistry
Chemists describe a new form of ice December 25th, 2020
Possible Futures
Atomic-scale nanowires can now be produced at scale: Scalable synthesis of transition metal chalcogenide nanowires for next-gen electronics December 25th, 2020
New imaging method views soil carbon at near-atomic scales December 25th, 2020
Understanding nanoparticle entry mechanism into tumors December 25th, 2020
Chip Technology
Atomic-scale nanowires can now be produced at scale: Scalable synthesis of transition metal chalcogenide nanowires for next-gen electronics December 25th, 2020
New topological properties found in “old” material of Cobalt disulfide: For one thing, it’s not a true half-metal December 18th, 2020
Stevens creates entangled photons 100 times more efficiently than previously possible: Ultra-bright photon source brings scalable quantum photonics within reach December 17th, 2020
Discoveries
Experiment takes ‘snapshots’ of light, stops light, uses light to change properties of matter December 25th, 2020
New imaging method views soil carbon at near-atomic scales December 25th, 2020
Understanding nanoparticle entry mechanism into tumors December 25th, 2020
Announcements
Atomic-scale nanowires can now be produced at scale: Scalable synthesis of transition metal chalcogenide nanowires for next-gen electronics December 25th, 2020
New imaging method views soil carbon at near-atomic scales December 25th, 2020
Understanding nanoparticle entry mechanism into tumors December 25th, 2020
Interviews/Book Reviews/Essays/Reports/Podcasts/Journals/White papers/Posters
Scientists suggested a method to improve performance of methanol fuel cells December 25th, 2020
Chemists describe a new form of ice December 25th, 2020
Atomic-scale nanowires can now be produced at scale: Scalable synthesis of transition metal chalcogenide nanowires for next-gen electronics December 25th, 2020
New imaging method views soil carbon at near-atomic scales December 25th, 2020