Two different species obeying the octet rule

  • Thread starter Thread starter fisipavia
  • Start date Start date
Click For Summary

Discussion Overview

The discussion revolves around the stability of different chemical species that obey the octet rule, particularly in the context of organic chemistry. Participants explore factors influencing stability, such as resonance structures and the nature of carbocations, while addressing specific examples of molecular structures.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested
  • Homework-related

Main Points Raised

  • One participant expresses difficulty in determining the stability of different species, noting that while they can assess resonance conformers, they struggle with comparing distinct species.
  • Another participant suggests that the stability of CH3C(O-)HCH=CH2 is less than that of CH3C(O-)=CHCH3 due to the presence of resonance structures in the latter, which allows for stabilization through pi bonding.
  • A different participant introduces the concept of carbocation stability, explaining that tertiary carbocations are more stable than secondary ones, and suggests that the first compound may convert to a more stable form through intramolecular shifts.
  • Additional related concepts such as "enolates," "allylic anion," and "allylic cation" are mentioned as potentially relevant to the discussion.

Areas of Agreement / Disagreement

Participants present differing views on the factors influencing stability, particularly regarding resonance and carbocation types. The discussion does not reach a consensus on the best approach to determine stability among the species in question.

Contextual Notes

Participants reference specific molecular structures and resonance forms, but the discussion lacks clarity on certain assumptions and definitions related to stability and reactivity.

Who May Find This Useful

Students and individuals interested in organic chemistry, particularly those seeking to understand the factors affecting molecular stability and resonance in chemical species.

fisipavia
Messages
11
Reaction score
0
I began taking Organic Chemistry one week ago, so my question should be very easy for most of you.
I am having a lot of problems determining which specie, of a group of given species, is more stable. I can determine it for resonance conformers; for example I know that one conformer with a separation of charges is less stable that one with no separation of charges. I also know that the lone pairs must be in the most electronegative atom...etc. However I am having problems when I am asked to determine which of two or three species (not resonance conformers) is more stable.
I read my book and I didn't find any kind of rule for comparing the stability of two different species obeying the octet rule and with no separation of charges. I would reeeaaaallly appreciate if someone could explain me what I must consider.
One example of the problems that I cannot do is the following:


CH3C(O-)HCH=CH2 --> (the O has formal charge -1, I didn't know how
to write it here)

VS.

CH3C(O-)=CHCH3

The most stable is the second one, but why?
 
Chemistry news on Phys.org
CH3-CO(-)=CHCH3 is more stable because of the resonance structure CH3-CO-C(-)HCH3 in which the lone pair of the oxygen forms a pi bond with the carbonyl carbon while the adjacent pi bond is thrown onto the carbon.

With the other structure there is no resonance structure because their can't be any pi bond formed from the oxygen's lone pair. If this were to happen the carbonyl carbon would have 5 bonds, which is illegal and can be punishable by death.
 
Let's try to answer this question

Hello,

I think you should look in the term "most stable carbocation" in your books. Tertiary carbocations do not possesses hydrogen at all, whereas secondary carbocations have one, and primary ones have two on them.

With these basics, let me answer your question. Please view the attachments first. In the first attachment, you will find the first resonance hybrid. The compound on the left is not an enol; so is highly reactive, especially through its vinylic terminal. The one on the right has a secondary carbocation, which is weaker than tertiary carbocation. So if you can write an isomer consisting a tertiary carbocation, then you may conclude that this one is more stable. You may even suggest that the first compound will try to convert itself to the second with intramolecular shifts.

When you look at the second attachment, there seems to be an enol tautomer of a ketone; the ketone is written in its "neutral" form. If you want to write its anianic form, you should take an alfa hydrogen from the ketonic carbon.

To sum up, it can be explained by the relevant stabilization effects of tertiary carbocations versus secondary ones.

Regards
chem_tr
 
Other related things you may find in your textbook:

"enolates" (or just "enols")
"allylic anion"
"allylic cation"
 

Similar threads

Is Dragos rule evidence of hybridization theory's failure?
  • · Replies 9 ·
Replies
9
Views
4K
How to determine the movement of electrons between atoms
  • · Replies 6 ·
Replies
6
Views
3K
Is the octet rule, important to the atom?
  • · Replies 5 ·
Replies
5
Views
6K
Aromaticity of 1-methyl-1H-pyridin-2-one?
  • · Replies 8 ·
Replies
8
Views
8K
Why Do Resonance Structures for ClO- and ClO4- Differ in Formal Charges?
  • · Replies 3 ·
Replies
3
Views
13K
Thoughts on Excerpt from My Chem Prof's Textbook?
  • · Replies 8 ·
Replies
8
Views
5K
Polymerization of acrylamide with K Persulfate without Bis
  • · Replies 9 ·
Replies
9
Views
6K
Transition Elements: Octet Rule, Lewis Dot Diagrams, Stability
  • · Replies 4 ·
Replies
4
Views
18K
Chemistry How do we know ##BF_3## has Lewis structure but ##Al_2S_3## does not?
  • · Replies 1 ·
Replies
1
Views
3K
Time dependant Potential Energy in ion trap
  • · Replies 1 ·
Replies
1
Views
2K