An attosecond is 10-18s. The chemistry that takes place on this timescale is called electron dynamics. For example, it is the time taken for an electron to traverse the 1s orbit in a hydrogen atom. And chemists are starting to manipulate electrons (and hence chemistry) on this timescale; for example a recent article (DOI: 10.1021/ja206193t) describes how to control the electrons in benzene using attosecond laser pulses.
Posts Tagged ‘Tutorial material’
Atropisomerism in Taxol. An apparently simple bond rotation?
Tuesday, November 1st, 2011My previous post introduced the interesting guts of taxol. Two different isomers can exist, and these are called atropisomers; one has the carbonyl group pointing up, the other down. The barrier to their interconversion in this case is generated by a rotation about the two single bonds connecting the carbonyl group to the rest of the molecule. Introductory chemistry tells us that the barrier for rotation about such single bonds is low (i.e. fast at room temperature). But is that true here?
The SN1 Mechanism for a third time. Exploration of the intrinsic reaction coordinate.
Tuesday, October 25th, 2011As the title hints, I have been here before. The SN1 solvolysis mechanism of t-butyl chloride was central to the flourishing of physical organic chemistry from the 1920s onwards, and it appears early on in most introductory lecture courses and text books. There we teach that it is a two-stage mechanism. Firstly the C-Cl bond heterolyses to form a stable tertiary carbocation intermediate, which in a second stage reacts with nucleophile (water) to form e.g. t-butanol. This is contrasted with the SN2 mechanism, where these two stages are conflated into a single concerted process, involving no intermediates. Here I explore an intrinsic reaction coordinate for the hydrolysis of t-butyl chloride which attempts to tease out whether this simple picture is realistic.
The perception of stereochemistry. A challenging case.
Tuesday, October 18th, 2011Most representational chemistry generated on a computer requires the viewer to achieve a remarkably subtle transformation in their mind from two to three dimensions (we are not quite yet in the era of the 3D iPad!). The Cahn-Ingold-Prelog convention was a masterwork (which won the Nobel prize). It is shown in action for the molecule on the left below. The CIP notation was actually generated by Chemdraw, and required a fair sprinkling of wedged and hashed bonds to (try to) remove stereoambiguity and generate the labels (try it for yourself). As part of a lecture course on pericyclic reactions, I tell the students that the reaction involves a [1,3] sigmatropic migration of the red carbon and that this migration proceeds with inversion of configuration at this migrating carbon (as the selection rules require). Perceiving what the correct CIP product label should be (with inferred stereochemical labels, resolving ? into either R or S) is IMHO one of the most difficult conceptual experiences in all of organic chemistry. I have over the years struggled to find a way of revealing this in lecture notes (these struggles with the “lecture notes” will be the topic of a future post here). However, I think I may have finally cracked it; my solution is set out below!
Mechanism of the reduction of a carboxylic acid by borane: revisited and revised.
Sunday, October 16th, 2011I asked a while back whether blogs could be considered a serious form of scholarly scientific communication (and so has Peter Murray-Rust more recently). A case for doing so might be my post of about a year ago, addressing why borane reduces a carboxylic acid, but not its ester, where I suggested a possible mechanism. Well, colleagues have raised some interesting questions, both on the blog itself and more silently by email to me. As a result, I have tried to address some of these questions, and accordingly my original scheme needs some revision! This sort of iterative process of getting to the truth with the help of the community (a kind of crowd-sourced chemistry) is where I feel blogs do have a genuine role to play.
The reduction of a carboxylic acid by borane
Bonds.
Thursday, October 13th, 2011Bonds are a good example of something all chemists think they can recognise when they see them. But they are also remarkably dependent on context. We are running a molecular modelling course at the moment, and I found myself explaining to someone how very context-sensitive they can be. I thought it might be useful to collect my thoughts here. (more…)
cis-Butene: a reaction coordinate dissected and methyl flags.
Wednesday, October 12th, 2011In two previous posts, I have looked at why cis-butene adopts conformation (a) rather than (b). I suggested it boiled down to electronic interactions between the methyl groups and the central alkene resulting in the formation of a H…H “topological” bond, rather than attraction between the H…H region to form a weak chemical “bond“. Here I take a look at what happens when that central C=C bond is gradually removed.
Are close H…H contacts bonds? The dénouement!
Monday, October 10th, 2011I wrote earlier about the strangely close contact between two hydrogen atoms in cis-butene. The topology of the electron density showed characteristics of a bond, but is it a consensual union? The two hydrogens approach closer than their van der Waals radii would suggest is normal, so something is happening, but that something need not be what chemists might choose to call a “bond“. An NCI (non-covalent analysis) hinted that any stability due to the electron topologic characteristics of a bond (the BCP) might be more than offset by the repulsive nature of the adjacent ring critical point (RCP). Here I offer an alternative explanation for why the two hydrogens approach so closely.
Steve Jobs and chemistry: a personal recollection.
Sunday, October 9th, 2011Steve Jobs death on October 5th 2011 was followed by a remarkable number of tributes and reflections on the impact the company he founded has had on the world. Many of these tributes summarise the effect as a visionary disruption. Here I describe from my own perspective some of the disruptions to chemistry I experienced (for another commentary, see here).
Hunt the charge: the Cheshire cat of chemistry
Thursday, September 29th, 2011Charges in chemistry, like the grin on Lewis Carroll’s cat, can be mysterious creatures. Take for example the following structure, reported by Paul Lickiss and co-workers (DOI: 10.1039/b513203g).