Term
| What is normally the resonance energy or the resonance stabilization energy and what is the exception to this? |
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Definition
The RE or RSE is usually the difference in enthalpy (heat within the system) between a strictly bonded resonance contributor and its resonance hybrid (where the bond is floating back and forth between possible bond sites). When 2 or more contributors have unequal E's the RE will be the difference between the most stable contributor and the hybrid (and the value is smaller) |
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Term
| What are the three rules regarding resonance contributors? |
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Definition
1. Only pi electrons and lone pairs move. 2. An sp3 C can't accept electrons since it has a full octet and it can't undergo hyperconjugation due to energy constraints. 3. Don't break sigma bonds |
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Term
| Is separation of charges a major contributor to resonance? |
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Definition
Separation of charges is not a good thing for resonance contribution but it can be improved under polar conditions |
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Term
| What will happen in regards to resonance contribution when one or more atoms in a compound has incorrect charge polarity? |
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Definition
It will barely contribute to resonance at all |
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Term
| Let's say that you have various resonance hybrids of propyl alkanes and attached to them on each end are oxygen atoms, nitrous groups or nothing at all while the resonance center is in the middle. What will be the order of stability in regards to these attachment groups? |
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Definition
Two oxygens will be the stabilest while no groups will be the least stable. Nitrous groups will be less stable than oxygen but they're better than nothing |
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Term
| What effect would a substituted group such as a nitro, ketone, CN and SO2R have on a benzene ring? |
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Definition
| They would make the ring electron deficient by initiating electron withdrawal (these groups possess an electron-deficient center at the point of withdrawal |
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Term
| Why is phenol (benzene with an OH group) a stronger acid than cyclohexanol? |
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Definition
When phenol is undergoing its various resonance stages it comes across one stage where there is a negative charge opposite of the double-bonded oxygen; this is a delocalized anion which results in a very strong acid |
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Term
| Why is protonated aniline (benzene with a :NH2 group) a stronger acid than protonated cyclohexylamine? |
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Definition
| The lone pair is delocalized because of initial proximity to a sp2 carbon |
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Term
| How does resonance affect regioselectivity? |
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Definition
If you're treating a substance with HX the H will bond pretty much as far away from the more complex end as possible (where it can bind) and the X will bind pretty much as close to the more complex end as possible to stabilize the resonance area |
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Term
| Which molecules are stabler: molecules with consecutive sp2 carbons or molecules with sp2-sp3 carbons? |
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Definition
Sp2 carbons in sequence are stabler than their sp2-sp3 counterparts |
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Term
| What happens when penta-1,4-diene has a double bond right in the middle of itself? |
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Definition
It is cross-conjugated and the third double bond can't stabilize the system through resonance. Since penta-1,4-diene has a specific heat of 30.4 and 4-(eth-2-ene)-propyl-1,3-diene has a specific heat of 28.9, 1.5 is atrributable to the hybridization change |
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Term
| Put isolated dienes, alkynes, conjugated dienes and allenes in order of stability |
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Definition
Allenes < alkynes < isolated dienes < conugated dienes |
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Term
| What are conjugated dienes? |
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Definition
Conjugated dienes are dienes which have 2 double bonds separated by a single bond. A good example of this is 1,3-butadiene |
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Term
| What is important to note about pi MO's and sigma MO's? |
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Definition
They can be separated. Although flawed this is conceptually useful |
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Term
| In regards to ethene MO's, what is pi and pi*? |
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Definition
Pi is p1+p2 when looking at a graph of the free energy (pi in this case is symmetric or S). Pi* is p1-p2 which turns out to be asymmetrical or A |
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Term
| Describe the basic reaction through which isolated dienes undergo |
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Definition
Isolated dienes undergo additions without influencing each other. If you were to treat them directly with HX they would react to the more reactive double bond |
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Term
| Describe the basic reactions that conjugated dienes can undergo |
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Definition
Conjugated dienes can undergo both 1,2 and 1,4 additions. The 1,2 adduct is considered the "normal addition" whereas the 1,4 adduct is considered the "conjugate addition" |
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Term
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Definition
| An adduct is an addition product (add + uct = adduct). This usually applies to some diene form when treated with HX but this is just an example |
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Term
| What does more of the less stable product mean in regards to conjugated dienes? |
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Definition
It means that the reaction was under kinetic control |
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Term
| What does more of the more stable product mean in regard to conjugated dienes? |
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Definition
It means that the reaction was subject to thermodynamic control |
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Term
| What is the kinetic product of penta-1,3-diene + hydrochloric acid in the absence of electronic and steric bias? |
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Definition
Let's say that you react penta-1,3-diene with HCl. The double bond from the 1 location will attack the H and bond to it. The Cl will likely bond at the 2 site but may travel to the 4 site. Since it's so much easier to remain at the 2 site the 1,2 product will be the major product |
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Term
| What is ion pairing in regards to dienes? |
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Definition
Ion pairing is a proximity effect in which ions will effectively pair with each other but in some cases they will choose somewhat random pairs. The proximity effect says that the ions are very likely to bond if close together |
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Term
| Can the 1,2 adduct be both the kinetic and thermodynamic product? |
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Definition
| Yes, it can be. This occurs when there is a more substituted double bond and when there is a less substitued X-associated carbon |
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Term
| Describe the Diels-Alder reaction |
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Definition
| The Diels-Alder reaction is a pericyclic 1,4 addition. The best example of this is the reaction that occurs between buta-1,3-diene and ethene. A bond from the 1 carbon will attach to one of the carbons in ethene, one of the bonds from ethene will switch to attach to the 4 carbon and the bond between the 3 and 4 carbon will flip to between the 2 and 3 carbons; this entire reaction will result in cyclohexene |
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Term
| What are the thermodynamics of the Diels-Alder reaction? (specifically buta-1,3-diene and ethene combining to form cyclohexene) |
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Definition
| 2 pi bonds turn into 2 sigma bonds. Since each pi bond has about 63 kcal/mol and each sigma bond has about 83 kcal/mol there is a net difference of about 40 kcal/mol |
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Term
| Describe the entrophy in a Diels-Alder reaction and describe what is important about this |
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Definition
The entropy (delta-S) of the DAR is negative so therefore the reverse reaction (called the retro-DAR) becomes feasible at high T |
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Term
| What are the 2 major principles regarding MO theory and the Diels-Alder transition states and what conclusion can be drawn from this? |
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Definition
1. Only interactions of filled and unfilled orbitals lead to net stabilization. 2. The stabilization is greater if the delta E (change in free energy) between the filled and unfilled orbitals is smaller. Therefore interaction between HOMOs and LUMOs is key |
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Term
| How do the orbitals in the dienophile and the diene need to be oriented in order to be stabilized? |
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Definition
| The orbitals need to be matched up in order to interact |
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Term
| Which is greater (and therefore is not the controlling component): delta E(HOMO diene - LUMO dienophile) or delta E(HOMO dienophile - LUMO diene)? |
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Definition
HOMO dienophile - LUMO diene is greater which means that the other way around is the controlling factor. It should be noted, though, that the delta E(HOMO diene - LUMO dienophile) for hydrocarbons is too large for a fast reaction and therefore will, in most cases, act as the rate determining step in a reaction |
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Term
| A smaller change in free energy would speed up a Diels-Alder reaction, but how can this be achieved? |
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Definition
Add some electron donating groups onto the diene or add some electron withdrawing groups onto the dienophile. Some common EDGs include OR, OSiR3 and NR2; some common EWGs include CN, CO2R, C(O)R and NO2 |
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Term
| What will be the major product that results from an unsymmetrical DAR when dealing with regioselectivity between EDGs and EWGs: a 1,2 adduct or a 1,3 adduct? |
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Definition
| The 1,2 adduct will be much more likely to form since the negative end of the open chain in the 1,3 adduct formation process does not lie on the actual EWG whereas in the formation of the 1,2 product the negative charge does lie on the EWG |
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Term
| What will be the major product that results from an unsymmetrical DAR when dealing with regioselectivity between EDGs and EWGs: a 1,3 adduct or a 1,4 adduct? |
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Definition
The 1,4 adduct will be the dominating product. The issue here, just like with the 1,2 vs. 1,3 adduct, is that in the 1,3 adduct the negative charge is off of the EWG whereas with the 1,4 adduct the negative charge is on the EWG. This property is crucial in determining the regioselectivity of the DAR product |
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Term
| What conclusion can be made in regards to the 1,3 adduct in regards to DARs with unsymmetrical reactants? |
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Definition
The 1,3 adduct is always disfavored for adducts such as the 1,2 and 1,4 |
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Term
| What will 2 sets of enantiomeric syn transition states give as products and what effect does addition have on the halide substituents? |
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Definition
The transition states in this case will all give the same meso product from z-alkene and addition will maintain the orientation of the halide substituents |
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Term
| What will the transition states result in when dealing with syn transition states and E-alkene in regards to DAR stereochemistry and what effect does addition have on the halide substituents? |
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Definition
| The different approaches are equivilent and will give a racemic product. Addition will maintain the orientation of the X substituents |
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Term
| What is important to note when a halide is added to buta-1,3-diene and is combined with something such as Z-dichloroethene in regards to its transition states and racemates? |
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Definition
The enantiomeric exo and endo syn transition states give separate diastereomeric racemates from Z-alkene. The result is an overall exo adduct and an overall endo adduct |
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