Will the following reaction give a racemic mixture or not?
According to me, it should give. But my teacher disagrees, but I cannot understand the reasons he gave. Shouldn't there be equal approaches from above and below the molecules?
I am confused when he says that the adjacent 3° Carbon can change its configuration too.
Update
Original question:-
Solution provided:-
IUPAC advises against using the term racemic mixture because of its ambiguity.
racemic mixture (obsolete) The term is confusing since it has been used as a synonym for both racemate and racemic conglomerate. Usage strongly discouraged.
The term that applies in this case is racemate.
racemate An equimolar mixture of a pair of enantiomers. It does not exhibit optical activity.
There are three qualitatively different initial conditions to consider.
1. A racemate of (3S)-methylpentan-2-one and (3R)-methylpentan-2-one, nucleophile is not $\ce{OH-}$
Both enantiomers behave similarly, each yielding a stereocenter at the carboxylic carbon.
Verdict: not optically active but contains two pairs of equimolar enantiomers: $\mathrm{a), d)}$ and $\mathrm{b), c)}$. Even three if you count the reagents. Is a racemate if one relaxes the single pair criterium.
2. A racemate of (3S)-methylpentan-2-one and (3R)-methylpentan-2-one, nucleophile is $\ce{OH-}$
Verdict: not optically active, equimolarity is ensured, a pair of enantiomers. Is a racemate.
3. Either (3S)-methylpentan-2-one or (3R)-methylpentan-2-one, nucleophile is / is not $\ce{OH-}$
Verdict: optically active, does not contain enantiomers. Not a racemate.
In this reactant one stereogenic carbon is already present and its configuration will not change during reaction. When Nu- attack on carbonyl carbon two products are formed due to top side and bottom attack but these two products are Diastereomers.
When you add to the planar carbonyl group, attack from both sides of the plane is equally probable. If there are no other carbons bearing four different groups in the molecule (chiral centres), a pair of enantiomers will be formed in equal amounts (racemate). Keep in mind that diastereomers and enantiomers apply to relationships between pairs of molecules. If you create two pairs of enantiomers, then the molecules in each pair will be diastereomers of the other pair. So you also create two pairs of diastereomers.
Now, there is already a chiral centre in your molecule - but its configuration is not given. Without knowing that, the question cannot be answered properly. The molecules could be either all R or all S; assuming it is R addition of the nucleophile will give (R,S) and (R,R) in equal amounts. These are diastereomers because the mirror image of (R,S) is (S,R) and the mirror image of (R,R) is (S,S). The same applies if all your molecules would have an S chiral centre before addition. The molecules that are formed are not mirror images.
If your molecule would be present as 50% R and 50% S beforehand (racemate), addition will create equal amounts of (R,R), (R,S), (S,R) and (S,S). Now, you have two pairs of enantiomers: (R,R)/(S,S) and (R,S)/(S,R). Every stereoisomer in the mixture has one mirror image (together they are enantiomers) and 2 others that are diastereomers. I'd also like to add that enantiomers are definitely not diastereomers. In fact, that's how IUPAC defines diastereomers: they are stereoisomers that are not enantiomers. This mixture is not a racemate because there are four stereoisomers. According to IUPAC, a racemate is a pair of enantiomers present in equal amounts.
If the nucleophile is hydroxide, then addition will not create an additional chiral centre. So then it would depend on whether you had a single stereoisomer to start with or a mixture, whatever stereochemistry you started with will be retained since no bonds to the chiral centre are formed or broken.
Out the two sites, one site is adjacent to the Me group So attack to that site is hindered because of Steric Reason. Only one site is available for attack. Therefore, enantiomers are not formed in equal ratio.
