Posts Tagged ‘chemical bonding’
Thursday, April 25th, 2019
Previously, I explored (computationally) the normal vibrational modes of Co(II)-tetraphenylporphyrin (CoTPP) as a “flattened” species on copper or gold surfaces for comparison with those recently imaged[cite]10.1038/s41586-019-1059-9[/cite]. The initial intent was to estimate the “flattening” energy. There are six electronic possibilities for this molecule on a metal surface. Respectively positively, or negatively charged and a neutral species, each in either a low or a high-spin electronic state. I reported five of these earlier, finding each had quite high barriers for “flattening” the molecule. For the final 6th possibility, the triplet anion, the SCF (self-consistent-field) had failed to converge, but for which I can now report converged results.†
(more…)
Tags:019-1059-9, 10.1038, Biomolecules, Chelating agents, chemical bonding, Chemical compounds, Chemistry, Coordination chemistry, Coordination complex, Copper, copper metal surface, Cu–CO, E-type, energy, free energy, higher energy, impossible free energy, Inorganic chemistry, Jahn–Teller effect, lowest energy electronic state, Metabolism, metal, metal surface, modest planarisation energy, Molecule, Natural sciences, Physical sciences, planarisation, Porphyrin, reasonable energy, Resonance, Solid-state chemistry, sufficient energy, Teller, Tetraphenylporphyrin
Posted in Interesting chemistry | 1 Comment »
Thursday, April 18th, 2019
The topic of this post originates from a recent article which is attracting much attention.[cite]10.1038/s41586-019-1059-9[/cite] The technique uses confined light to both increase the spatial resolution by around three orders of magnitude and also to amplify the signal from individual molecules to the point it can be recorded. To me, Figure 3 in this article summarises it nicely (caption: visualization of vibrational normal modes). Here I intend to show selected modes as animated and rotatable 3D models with the help of their calculation using density functional theory (a mode of presentation that the confinement of Figure 3 to the pages of a conventional journal article does not enable).
(more…)
Tags:anionic metal surface, Cambridge, chemical bonding, Chemistry, dihedral, energy, flat metal surface, metal, Natural sciences, Neutral Quartet, Physical sciences, Raman scattering, Raman spectroscopy, Resonance, spectroscopy, steric repulsion energy
Posted in Interesting chemistry | No Comments »
Sunday, March 24th, 2019
There is a predilection amongst chemists for collecting records; one common theme is the length of particular bonds, either the shortest or the longest. A particularly baffling type of bond is that between the very electronegative F atom and an acid hydrogen atom such as that in OH. Thus short C-N…HO hydrogen bonds are extremely common, as are C-O…HO.‡ But F atoms in C-F bonds are largely thought to be inert to hydrogen bonding, as indicated by the use of fluorine in many pharmaceuticals as inert isosteres.[cite]10.1039/B610213C[/cite] Here I do an up-to-date search of the CSD crystal structure database, which is now on the verge of accumulating 1 million entries, to see if any strong C-F…HO hydrogen bonding may have been recently discovered.
(more…)
Tags:Chemical bond, chemical bonding, Chemical elements, Chemistry, Fluorine, Hydrogen, Hydrogen bond, Intermolecular forces, Natural sciences, perturbation energy, pharmaceuticals, Physical sciences, Refrigerants, search parameters, search query, Supramolecular chemistry
Posted in crystal_structure_mining | No Comments »
Sunday, March 4th, 2018
A bond index (BI) approximately measures the totals of the bond orders at any given atom in a molecule. Here I ponder what the maximum values might be for elements with filled valence shells.
(more…)
Tags:Atom, Chemical bond, chemical bonding, chemical properties, Chemistry, metal bond indices, Molecule, Nature, Quantum chemistry, Residential REITs, Resonance, Tennessine, Valence, Valence electron
Posted in Interesting chemistry | No Comments »
Saturday, February 24th, 2018
Another post inspired by a comment on an earlier one; I had been discussing compounds of the type I.In (n=4,6) as possible candidates for hypervalency. The comment suggests the below as a similar analogue, deriving from observations made in 1989.[cite]10.1016/S0040-4039(00)99132-9[/cite]
(more…)
Tags:C, chemical bonding, Chemistry, free energy, Hypervalent molecule, Matter, Molecular geometry, Nature, Nitrogen
Posted in Hypervalency | 3 Comments »
Friday, February 16th, 2018
Last year, this article[cite]10.1038/nchem.2716[/cite] attracted a lot of attention as the first example of molecular helium in the form of Na2He. In fact, the helium in this species has a calculated‡ bond index of only 0.15 and it is better classified as a sodium electride with the ionisation induced by pressure and the presence of helium atoms. The helium is neither valent, nor indeed hypervalent (the meanings are in fact equivalent for this element). In a separate blog posted in 2013, I noted a cobalt carbonyl complex containing a hexacoordinate hydrogen in the form of hydride, H–. A comment appended to this blog insightfully asked about the isoelectronic complex containing He instead of H–. Here, rather belatedly, I respond to this comment!
(more…)
Tags:chemical bonding, Chemical elements, chemical shift, Chemistry, helium, Hydride, Hydrogen, Hypervalent molecule, Matter, Metal hydrides, Reducing agents, Transition metal hydride
Posted in Hypervalency | 4 Comments »
Saturday, January 13th, 2018
I discussed the molecule the molecule CH3F2- a while back. It was a very rare computed example of a system where the added two electrons populate the higher valence shells known as Rydberg orbitals as an alternative to populating the C-F antibonding σ-orbital to produce CH3– and F–. The net result was the creation of a weak C-F “hyperbond”, in which the C-F region has an inner conventional bond, with an outer “sheath” encircling the first bond. But this system very easily dissociates to CH3– and F– and is hardly a viable candidate for experimental detection. In an effort to “tune” this effect to see if a better candidate for such detection might be found, I tried CMe3F2-. Here is its story.
(more…)
Tags:Antibonding molecular orbital, candidate for experimental detection, chemical bonding, chemical shift, Chemistry, metal, Molecular orbital, Nature
Posted in Hypervalency | 2 Comments »
Tuesday, December 26th, 2017
Recollect the suggestion that diazomethane has hypervalent character[cite]10.1039/C5SC02076J[/cite]. When I looked into this, I came to the conclusion that it probably was mildly hypervalent, but on carbon and not nitrogen. Here I try some variations with substituents to see what light if any this casts.
(more…)
Tags:chemical bonding, Chemistry, diazo, Diazo compounds, Diazomethane, diazomethane-like systems, Functional groups, Hypervalent molecule, Molecular geometry, Organic chemistry, Recollects
Posted in Hypervalency | 8 Comments »
Tuesday, November 28th, 2017
I started this story by looking at octet expansion and hypervalence in non-polar hypercoordinate species such as S(-CH3)6, then moved on to S(=CH2)3. Finally now its the turn of S(≡CH)2.‡
(more…)
Tags:1-Decyne, CH2, chemical bonding, free energy, G. N. Lewis, Lewis structure, Music, Octet
Posted in Historical, Hypervalency | 3 Comments »