Quantum Mechanics/Wave Mechanics in Chemistry Beginners Thread

<b>Conjugation</b>

Conjugation occurs when there are three or more sp² or sp hybridized atoms adjacent to each other. Another way of looking at it is that there must be three adjacent atoms which each contain at least one unhybridized p-orbital. These adjacent p-orbitals tend to overlap as shown by the following diagram:



This overlap of p-orbitals allows the pi electrons in the compound to be delocalized and spread across the p-orbitals of all of the conjugated atoms, rather than being confined to a single atom. Thus, conjugated systems are extremely stable and also exhibit certain special properties. One example of this is benzene, despite being an alkene, it very rarely behaves like one due to the even spread of electrons throughout the molecule. Unlike the Kekule structure suggests, all of benzene's bonds are equivalent, not alternating double and single bonds; hence the unexpected behavior. This unusual behavior is present for most aromatic systems, all of which are conjugated systems.

Conjugated systems also lead to interesting behavior in regards to light absorption. As I believe you know from one of blogfast's lectures(I hope that it's been explained) atoms can absorb light by promoting electrons to higher, otherwise unused, orbitals. These electrons, which are temporarily in this higher energy state, are called <b>excited</b> electrons. These excited electrons will then eventually drop back down to their original lower energy state due to the preferential increase in entropy. The energy which was absorbed thus needs to be released, and this is done through emitting heat, lower wavelengths of light(such molecules are called fluorescent dyes), or another form of energy. In conjugated systems, the delocalization of the electrons allows them to be promoted to an excited state by light of a lower energy. Since wavelength is inversely related to energy, conjugated compounds will absorb light of a higher wavelength than unconjugated compounds. In some highly conjugated compounds, this wavelength becomes so large it reaches the visible spectrum; thus forming one class of organic dyes.

A molecule can have more than one conjugated system, consider the following example: undeca-1,3,5,8,10-pentaene.



It contains two conjugated systems, one of which has four adjacent carbons with p-orbitals, the other contains six adjacent carbons with p-orbitals. When determining the wavelength of light which a conjugated compound will absorb, it is based upon the number of adjacent conjugated atoms present in the largest conjugated system, not the total number of conjugated atoms. Thus a compound such as triphenylmethane, with three smaller isolated conjugated systems, will absorb light of a lower frequency than anthracene, which contains one large conjugated system.

This concept can be used to explain both the acid-base and variable coloration of phenolphthalein.

Firstly, let's look at the structure of phenolphthalein in neutral or mildly acidic solution. There are three acidic protons, the two on the hydroxyl groups, and the carboxylic acid(they may or may not be shown as free protons depending on the resonance structure, but they're all there). In a basic environment, one proton is going to be removed first preferentially, which will be the carboxylic acid. Though both the deprotonated hydroxyl and carboxylate can delocalize electrons into the aromatic ring, the carboxylate can also delocalize electrons onto the carbonyl, making that proton the most acidic.

The second deprotonation is where it becomes interesting however. When a proton is removed from one of the hydroxyls, there are two resonance structures of this di-deprotonated phenolphthalein molecule; both of which are highly conjugated as shown below, connecting all three aromatic rings. This large number of adjacent conjugated atoms thus lower the energy required to promote electrons enough that phenolphthalein becomes highly colored in basic solution. Due to the high stability of the conjugated structure, the second proton is quite acidic as well and both deprotonations are complete at a pH of around 8.2



On the other hand, phenolphthalein is also strongly colored at very low pH's, below 0. This is due to the structure of the protonated form of phenolphthalein, shown below. This structure is also quite highly conjugated, though slightly less so; hence the color being a slightly smaller wavelength. The key here is that a carbocation is sp² hybridized, thus it contributes to a conjugated system as well.



As always, let me know if you have any questions.

Blogfast, please feel free to correct me or expand on any points which I may have missed.

[Edited on 12-4-2015 by gdflp]

Quote: Originally posted by gdflp

<b>Conjugation</b> Conjugation occurs when there are three or more sp<sup>2</sup> or sp hybridized atoms adjacent to each other. Another way of looking at it is that there must be three adjacent atoms which each contain at least one unhybridized p-orbital. These adjacent p-orbitals tend to overlap as shown by the following diagram:

Quote: Originally posted by blogfast25

Quote: Originally posted by gdflp   <b>Conjugation</b> Conjugation occurs when there are three or more sp<sup>2</sup> or sp hybridized atoms adjacent to each other. Another way of looking at it is that there must be three adjacent atoms which each contain at least one unhybridized p-orbital. These adjacent p-orbitals tend to overlap as shown by the following diagram: gdflp, is there perchance a diagram missing?

Quote: Originally posted by Pok

Wouldn't the "Beginnings" forum be a better place for this thread? People interested in the "Chemistry in General" forum are not necessarily interested in this thread.

Quote: Originally posted by gdflp

Now, considering the shift in the subject matter, it could fit in <b>Organic Chemistry</b> just as well, but there's no reason to move it.

Quote: Originally posted by Darkstar

@aga I hope you've been paying attention this semester, because I've written your final exam! The test is 25 questions plus an extra credit question. Just say the word when you're ready and I'll post it.

Quote: Originally posted by Pok

Wouldn't the "Beginnings" forum be a better place for this thread? People interested in the "Chemistry in General" forum are not necessarily interested in this thread.

Quote: Originally posted by gdflp

Conjugation occurs when there are three or more sp<sup>2</sup> or sp hybridized atoms adjacent to each other. Another way of looking at it is that there must be three adjacent atoms which each contain at least one unhybridized p-orbital. These adjacent p-orbitals tend to overlap

Quote: Originally posted by blogfast25

I'm not sure how people who are interested in general chemistry cannot be interested in this thread, pok. Chemistry is quantum chemistry, period.

Quote: Originally posted by Pok

Yes. And chemistry is physics. But I personally am not interested in physical chemistry and this thread deals with theoretical aspects. The "Chemistry in General" forum deals with practical aspects, not theoretical considerations. That's the difference. @gdflp: If you have a questions-answer thread this is something like a "seminar" and thus indeed belongs to the beginnings. Since there is no "theoretical/physical chemistry" forum another option would be the "Miscellaneous" forum.

Quote: Originally posted by Pok

... I personally am not interested in physical chemistry and this thread deals with theoretical aspects. The "Chemistry in General" forum deals with practical aspects, not theoretical considerations. That's the difference.

Quote: Originally posted by Pok

The "Chemistry in General" forum deals with practical aspects, not theoretical considerations. That's the difference.

Says who? You?

Now please go bore someone else with your pigeon holing.

There's was always going to be some *diot having to bring up the 'correct placement' of the thread. Sadly, it was you.

Quote: Originally posted by Pok

I have to scroll down every time due to the long list of "sticky" topics and this topic here to find the new and interesting topics.

Quote: Originally posted by blogfast25

this forum, whatever the section, drowns in duplicates, 'kewls', crap and general flotsam and jetsam.

How DARE you !?!?

Not ALL of my posts are utter garbage

Quote: Originally posted by aga

In a molecule like Benzene, if the electrons are truly swapping places continuously, surely that would create some magnetic field effect, albeit tiny. Is this something that is measurable ?

Quote: Originally posted by gdflp

however, a current is produced, called the <b>aromatic ring current</b>. This current has an effect on certain things, most notably in NMR(Nuclear Magnetic Resonance) spectra.

Quote: Originally posted by aga

I have Sodium Benzoate and some Huge Nd magnets. Suggestions for a Practical reaction that generally goes One route, and might go another under such circumstances ? Perhaps a large magnetic field plus electrolysis.

Erm... have you seen the magnets on these NMR gismoz:

https://en.wikipedia.org/wiki/Nuclear_magnetic_resonance_spe...

Quote: Originally posted by blogfast25

Erm... have you seen the magnets on these NMR gismoz:

Quote: Originally posted by IrC

This last page has me wondering two things. One is does this mean those gas magnet inventions may actually have some basis in theory for the claimed ability to increase combustion efficiency (ring currents).

Quote: Originally posted by aga

Quote: Originally posted by blogfast25   Erm... have you seen the magnets on these NMR gismoz: Inefficiency is not impressive.

Quote: Originally posted by blogfast25

The magnetic fields needed to do NMR are far, far higher than your neomags can deliver

Well, according to the SE the magnetic dipole moment for a hydrogen atom in the eigenstate (n,l,m) is quantised and given by the following equations:


$$\mu_L=-g_L\frac{\mu_B}{\hbar}\langle \Psi_{n,l,m}|L|\Psi_{n,l,m} \rangle=-\mu_B\sqrt{l(l+1)}.$$

$$(\mu_L)_z=-\mu_B m.$$

$$n=0,1,2,3,...$$

$$l=0,1,..., n-1$$

$$m=-l,-l+1,...,0,...,+l-1,+l$$

$$\mu_B=\frac{e\hbar}{2m_e}=9.274 \times 10^{-24}\:\mathrm{JT^{-1}}$$

(μ_B_z is the z component and μ_B the Bohr magneton.

To this then has to be vector-added the intrinsic spin magnetic dipole moment of an electron (spin 'up', spin 'down', remember?).

So we're talking pretty small numbers here.

[Edited on 5-12-2015 by blogfast25]

Quote: Originally posted by IrC

"I don't really get your question. 'Splain?" I have read many articles on those devices sold to apply a strong local magnetic field to gas going into an engine, both pro and con. Some of the pro articles did quite a bit of testing MPG over the same track both with and without the device installed. Since it sounds as if what is being said was molecules with ring currents can be affected by magnetic fields, it makes me wonder if similar to a catalyst altering the activation energy level, or some type of molecular rearrangement may be induced by the field which improves the combustion process. Up to this point I had always considered the magnet on the fuel line to be more or less snake oil. This ring current discussion where magnetic fields may cause some change sparked my memory of looking into those devices decades ago. Is it possible the oil may not all be snakes or could some process little understood and yet to be researched fully actually be involved? In other words should I buy snake traps or N52 magnets?

And here's a suggestion for an 'aga research project' in OC...

Firstly, you could just do some off-the-shelf synths: that's safe but a bit boring.

Or you (we) could do something a bit more off the beaten track with potential usefulness.

Here's the proposal.

Preparation of some saturated tertiary alcohols from α-pinene:

α-pinene is a fairly OTC material (natural turpentine contains quite a lot of it) with a skeletal structure that is found in many natural derivatives (the result of evolutionary biology, no doubt).

Below are two α-pinene derivatives (4 and 6) that would be very well worth testing as catalysts in the KOH/Mg reduction reaction (see pok's sticky thread).



Preparing them from α-pinene seems doable but definitely not run-of-the-mill and with no guarantee of success.

The project would involve:

* Literature research (precursor and intermediates properties, recipes etc)
* Reactions
* Separations
* Characterisation of intermediates and end-products
* Reaction mechanism hypotheses

Needless to say: it'd keep you/us busy for a while!

aga, don't feel bamboozled into anything and make a free choice.

If you're interested, rest assured there will be plenty of assistance from the community.

Any questions?

PS: ultimate blackmail argument: 'you'd be giving something back to the community!'

[Edited on 5-12-2015 by blogfast25]

Quote: Originally posted by aga

Cor blimey guv'ner !

Quote: Originally posted by gdflp

will need a hydrogen cylinder and equipment which you trust to be under at least several atm of hydrogen pressure, not a great situation if the glass fails.

Quote: Originally posted by aga

@bloggers: is the 2-(4-methylcyclohexyl)propan-2-ol (item #4) a <i>desired</i> product in this sequence, or is it a possible by-product that should be minimised ?

Quote: Originally posted by aga

I do not have formic acid. There are plenty of ants hereabouts, however i will not collect and distill them. I suppose it could be purchased though.

Quote: Originally posted by aga

OK. It's going a bit crazy, so needs some parameters. There is a lot of glassware, a single stage vac pump, some reagents (IOC + a few OC) on hand. Locally available materials include plumbing supplies, so steel tubing/fittings are fine. Translate Ammonium Formate into Spanish, please, then try to find it. It could be Ant Powder, Artichoke Booster, or Alfalfa Stimulant (it is that random). 200 euros is about the limit for a single experiment at my level of learning.

You don't hang about much...

Quote: Originally posted by aga

Can't. If i delay even 1 day, the postage time to Spain is so long that i forget what the item was intended for.

Quote: Originally posted by aga

Quote: Originally posted by Darkstar   @aga I hope you've been paying attention this semester, because I've written your final exam! The test is 25 questions plus an extra credit question. Just say the word when you're ready and I'll post it. Please ! Can't say i'm 'ready' per-se, however fire away.

Don't worry, the exam is actually extremely easy for the most part. There is one question in particular (it's one of the first five) that might be a little tricky, though. The exam consists of 25 questions and two optional extra credit questions (added a second one). For questions 1-20 and the second extra credit problem, you can write the answers in the body of your reply post (just type "red" or "blue," "nucleophile" or "electrophile" etc); for questions 21-25 and the first extra credit problem, you will need to use either ChemSketch or MS Paint-in-the-ass.

While the exam shouldn't take very long to complete, please feel free to do it at your own pace. There's no need to rush. All I ask is that you try to do as much of it as you can without looking up the answers, particularly the last five questions. These questions are more or less the "real" test, so to speak. The last mechanism (question 25) is one that blogfast recently covered, by the way. Also, don't get too hung up on the extra credit problems if you're having trouble figuring them out, especially the first one. I did give a ton of hints for the second one, though, so it'll probably be the easier one to figure out. (I practically gave you the answers!)

Anyway, here's the test. I took the liberty of typing your name in the blank for you:



[Edited on 12-6-2015 by Darkstar]

Smashing, Darkstar. Will be taking that test myself. Forever young!

This was totally stolen from your example on page 15 of this thread, just with a phenyl ring and an extra wiggly bit on the ethanol.


[Edited on 6-12-2015 by aga]

Not sure about this one at all.

Quote: Originally posted by aga

Yes, it was over-vacuum that caused the filter to pop. Similar to Nile Red's result, this is a beige powder, so also contaminated and not pure phenolpthalein. I suspect that the workup could be improved in that process. [Edited on 7-12-2015 by aga]

@aga:

That was faster than anticipated. I will grade your test when I get home from skewl. It looks like you did fairly well for the most part; however, there do seem to be a few areas that you're still struggling with judging by the last three mechanism questions (questions 24, 25 and the first extra credit problem. though to be fair, the latter did involve a ring closure via intramolecular substitution, something we haven't actually covered yet, which is why it was extra credit).

Anyway, when I get home later I'll post the correct answers along with explanations for the ones that you missed. But overall you did very well!

Since I already have it saved on my desktop, here's the answer to the first extra credit problem, by the way:

Quote: Originally posted by aga

aga's OC Final Exam Answers Questions 1-5 (2 points each) 1. Red ✔ 2. Blue ✔ 3. Red ✔ 4. Red ✔ 5. <strike>Blue</strike> ✘ (-2 points) Questions 6-10 (2 points each) 6. Nucleophile ✔ 7. <strike>Electrophile</strike> ✘ (-2 points) 8. Electrophile ✔ 9. Nucleophile ✔ 10. Electrophile ✔ Questions 11-15 (2 points each) 11. Electrophilic ✔ 12. Nucleophilic ✔ 13. Electrophilic ✔ 14. Nucleophilic ✔ 15. Electrophilic ✔ Questions 16-20 (2 points each) 16. B. Phenyl ✔ 17. E. Hydroxyl ✔ 18. D. Ether ✔ 19. C. Amine ✔ 20. A. Carboxyl ✔ Questions 21-22 (7.5 points each) 21. 1-Butanol ✔ 2-Butanol ✔ Isobutanol ✔ Tert-butanol ✔ 22. Structure 1 ✔ Structure 2 ✔ Structure 3 ✔ <strike>Structure 4</strike> ✘ (missing, -2 points) Questions 23-25 (15 points each) 23. Fischer Esterification: Correct Products ✔ Correct Mechanism ✔ (cheater!) 24. Base-Catalyzed Ester Hydrolysis: Correct Products ✔ Correct Mechanism ✘ (missing bond cleavage in first step and partially incorrect arrow-pushing in second step, -5 points) 25. SN2 Reaction: Correct Products ✔ (will accept) Correct Mechanism ✘ (incorrect nucleophilic attacks and incorrect formation of primary carbocation and amide anion, -9 points) Extra Credit Questions (10 points each) Extra Credit 1. Rearrangement: ✘ (incorrect nucleophilic attacks and incorrect formation of primary carbocation and amide anion, -10 points) Extra Credit 2. ✔ (too much to list--will give partial credit. a detailed explanation will follow soon. -5 points) Total Missed (out of 100) = 20 Points Extra Credit Earned = 5 Points Final Score = 85/100 = 85%

Quote: Originally posted by aga

Thanks to both of you for your Priceless efforts - long may it continue !

I wouldn't worry about it too much. You seem to mostly be having trouble with drawing mechanisms, and you are by no means out of the woods in that regard There are some general patterns which you get more comfortable with though practice. And remember, organic chemistry is not easy; an 85% is a good grade!

An Elimination Reaction:

Here are two reactions with quite similar reagents but very different outcomes.



Which is a nucleophilic substitution we should be familiar with by now. It's achieved by treating the ethyl chloride with mild NaOH solution.

Now look at this one:



Here 2-bromopropane is refluxed with strong KOH. The equilibrium is pulled rightwards due to propene being a gas, which escapes from the reactive mix (Le Chatelier principle).

[Edited on 8-12-2015 by blogfast25]

Quote: Originally posted by gdflp

You seem to mostly be having trouble with drawing mechanisms, and you are by no means out of the woods in that regard

Quote: Originally posted by gdflp

85% is a good grade!

Here are some images that I have prepared. I originally intended to post these along with detailed explanations for what is shown, but try to make sense of them as much as you can for now. Ask blogfast or gdflp for help if there's anything you're still not clear on.

Ammonia's lone pair and geometry (trigonal pyramid):



Hydrogen bonding greatly increases the acidity of salicylic acid's carboxyl proton (question 3):



More on resonance stabilization and its effect on proton acidity (question 4):



All possible resonance structures of the phenoxide anion (was only looking for the first four, though):



General mechanism for the Fischer esterification (question 23):



Answer to question 24:



Answers to question 25 (S_N2 reaction) that I would have accepted:



Answer to the first extra credit question (rearrangement via intramolecular substitution):



In-depth look at the N-chloroacetamide molecule from the second extra credit question:







[Edited on 12-10-2015 by Darkstar]

Aromatic substitutions:



Substitutions on arenes require both an electrophilic (Lewis acid) and a nucleophilic (Lewis base) species.

Shown in the general case, the electrophile X⁺ draws in one of the three resonant π MOs. The nucleophile Nu^- then snatches a proton from the ring, thus restoring the π MO.

Perhaps the best known aromatic substitution know is the nitration of benzene with concentrated nitric acid (2.) Concentrated (near 100 w%) nitric acid has the property of auto-dissociating, acc. the equation shown, thus being able to supply both the electrophile and the nucleophile. Here the reaction is shown with some resonance structures.

Case 3 we have already touched on much higher up, a Friedel-Crafts arene alkylation.

Here only the preliminary step of the formation of the Lewis base, the primary butyl carbocation is shown by reaction of chlorobutane with AlCl₃.

After the electrophilic attack on the arene on one of the three resonant π MOs, a proton is then extracted from the ring by the tetrachloroaluminate and HCl evolves.

Multiple substitutions:

In each case the π ring is fully restored, making the substituted arene itself the potential subject of further substitutions on the 3 and 5 carbons, see below e.g. the structure of trinitro benzene:



[Edited on 10-12-2015 by blogfast25]

Quote: Originally posted by aga

Looking at the orbitals (which i think is confusing me a lot) N starts with 1s<sup>2</sup>2s<sup>2</sup>2p<sup>3</sup> (please say if that notation is correct or not). Hybridised is it this :- 1s<sup>2</sup>2s<sup>1</sup>2p<sup>3</sup>3p<sup>1</sup> giving the valence orbitals 2p<sup>3</sup> and then a 3p<sup>1</sup> as that extra 'lone pair' (even though it is just one electron) ?

Forget about the 1s², they're inner electrons, not valence.

Re. the remaining 2s²2p³, that's 5 electrons in 4 AOs. These hybridise to four 2sp³-type hybrid AOs, one of which contains an electron pair, the three others contain only one unpaired electron. The four sp³ AOs point to the corners of a tetrahedron (like CH₄.

The three half-filled sp³ can now σ-bond to whatever has a half-filled AO (H, C, X etc). So we end up with a structure like the one top right in Darkstar's last post.

The one unbonded filled sp³ AO is now available for dative bonding: sharing with an electropile or D-block metal metal atom (complex formation).

That's what makes ammonia (or substituted ammonia like amines) a Lewis base (and Bronsted-Lowry bases).

[Edited on 10-12-2015 by blogfast25]

Quote: Originally posted by aga

I think this is where the problem was : the 2s and 2p energy diagrams were confused with orbitals somehow, despite there being only three 2p boxes ... The p orbitals can contain up to 6 electrons in one of 6 'lobes'. N hybridisation in NH3 is from the 2s<sup>2</sup> 2p<sup>3</sup> ground state to a 2s<sup>1</sup> 2p<sup>4</sup> state, giving 4 outer orbitals, 1 for each hydrogen atom and one with a lone (single) electron in it looking for a nucleus to snaffle. This one, single, solitary electron is bewildering called a 'Lone Pair'. Hopefully this is correct. If not, please stamp it flat immediately.

You do seem to have a liiittle trouble counting the fingers on your hand!

4 hybrid orbitals. A total of 5 electrons. "Mirror, mirror on the wall: how do we fit that in, all?"

Simples: three hybrids AO contain only 1 electron, one hybrid AO contains 2 electrons. Hence, in the latter case we call it a lone (unbonded) electron pair. And 3 + 2 = 5 (in Roman numerals: III + II = V, )

I think you're still grappling with dative bonding, so I'm gonna put up something to kill those gremlins. Watch this space!

[Edited on 11-12-2015 by blogfast25]

Refresher on dative bonding:

I'll take, merely as an example, the case of the adduct formed by the interaction of the Lewis base (nucleophile) ammonia and the Lewis acid (electrophile), here a secondary propyl carbocation. (This is the second step in the reaction mechanism for the substitution of the halogen of isopropyl halide by ammonia - formation of amine(s)). Not to scale:



On the positively charged carbon atom there's an AO that is empty (zero electrons). That 'space' is filled up by ammonia 'donating' its lone electron pair, which now becomes shared between the C and N nuclei. The latter is of course the definition of a simple σ bond.

The positive charge of course doesn't disappear: it merely relocates to the N atom because it has 'lost' half of an electron pair, i.e. one electron (thus 0 - (-1) = +1).

The resulting ion is called isopropyl ammonium cation.

[Edited on 11-12-2015 by blogfast25]

Quote: Originally posted by aga

So how do you predict the hybridised configuration ?