The reactions of haloalkanes may be divided into the following categories:
1. Nucleophilic substitution
2. Elimination reactions
3. Reaction with metals.
Those organic compounds in which an sp3 hybridized carbon is bonded to an electronegative atom or group can undergo two types of reaction e.g. substitution reactions in which the electronegative atom or group is replaced by another atom or group. The second is the elimination reaction in which the electronegative atom or group is eliminated along with hydrogen from an adjacent carbon. The electronegative atom or group which is substituted or eliminated is known as leaving group.
Because of more electronegativity of the halogen atom, it has a partial negative charge and partial positive cha develops on the carbon atom.
X = F, Cl, Br, I
Due to this polar carbon - halogen bond alkyl halides shows nucleophilic substitution and elimination reaction.
There are two important mechanisms for the substitution reaction:
The mechanism of SN2 reaction
transition state
A number of factors affect the relative rate of SN2 reaction, the most important factors are:
1. Effect of the structure of the substrate:
Order of reactivity in SN2 reaction : - CH3 > 1º > 2º >> 3º (unreactive)
the important factor behind this order of reactivity is a steric effect. Very large and bulky groups can often hinder the formation of the required transition state and crowding raises the energy of the transition state and slows down the reaction.
Relative rates of reactions of an alkyl halide in SN2 reaction
Substituent | Compound | Relative rate |
Methyl | CH3X | 30 |
1° | CH3CH2X | 1 |
2° | (CH3)2CHX | 0.02 |
Neopentyl | (CH3)3CCH2X | 0.00001 |
3° | (CH3)3CX | ~0 |
2. Concentration and reactivity of the nucleophile
According to the kinetics of SN2 increasing the concentration of the nucleophile increases the rate of an SN2 reaction. The nature of nucleophile strongly affects the rate of an SN2 reaction. A stronger nucleophile is much more effective than a weaker one. For example, we know that a negatively charged nucleophile is more reactive than its conjugate acid e.g. HO- > H2O, RO- > ROH.
Steric effects on nucleophilicity
3. The effect of the solvent: In polar protic solvent large nucleophiles are good, and the halide ions show the following order: I- > Br- > Cl- > F- (in polar protic solvent)
This effect is related to the strength of the interaction between nucleophile and solvent molecules of polar protic solvent forms a hydrogen bond to nucleophiles in the following manner. Because small nucleophile is solvated more by the polar protic solvent thus its nucleophilicity decreases and the rate of SN2 decreases
Relative nucleophilicity in a polar protic solvent:
SH+ > CN- > I- > OH- > N3- > Br- > ACO- > Cl- > F- > H2O
So, polar protic solvents are not useful for the rate of SN2, if the nucleophile is anionic. But polar aprotic solvent does not have any active hydrogen atom so they can not forms an H bond with nucleophiles. Polar aprotic solvent has a crowded positive centre, so they do not solvate the anion appreciably therefore the rate of SN2 reactions increased when they are carried out in a polar aprotic solvent.
Examples of a polar aprotic solvent.
In DMSO, the relative order of reactivity of halide ions is: F- > Cl- > Br- > I-
4. The nature of the leaving group: The best-leaving groups are those that become the most stable ion after they leave because leaving group generally leave as a negative ion, so those leaving groups are good, which stabilise negative charge most effectively and weak base do this best, so weaker bases are good leaving groups. A good leaving group always stabilize the transition state and lowers its free energy of activation and thereby increases the rate of the reaction.
Order of leaving ability of halide ion: I- > Br- > Cl- > F-
Other leaving groups are
Strongly basic ions rarely act as leaving group:
Examples of SN2 reactions of alkyl halide →
Nucleophile | Product | Class of Product | |
R - | Alkyl halide | ||
R - | Alcohol | ||
R - | Ether | ||
R - | Thiol(mercaptan) | ||
R - | Thioether (sulphide) | ||
R - | Amine | ||
R - | Azide | ||
R - | Alkyne | ||
R - | Nitrile | ||
R - COO - R | Ester | ||
[R - PPh3]+ | Posphonium salt |
Question 1: Complete the following reactions with mechanism
(a)
Sol.
(b) ?
Sol. (p-Nitroanisole)
(c) Ph - CH2Cl
Sol. CH3-CH2-O! is present in excess and it is stronger nucleophile than Ph - O! so the product is Ph-CH2 - OEt
(d) CH3 - C ≡ CH X Y
Sol.
(e) Ph3 → Salt
Sol.
Question 2: When the concentration of alkyl halide is tripled and the concentration of OH- ion is reduced to half, the rate of SN2 reaction increases by :
(A) 3 times (B) 2 times (C) 1.5 times (D) 6 times
Ans: c
Mechanism of recemization (SN1):
|
| SN1 | SN2 |
(i) | Effect of the nucleophile | Nucleophile strength is not important | A stronger nucleophile is required |
(ii) | Effect of the substrate | 3° > 2° > 1° > CH3X | CH3X > 1° >2° |
(iii) | Effect of solvent | Good ionizing solvent required | It goes faster in a less polar solvent if Nud is present |
(iv) | Kinetics | Rate = k [R-X] | Rate = k[R-X] [Nu°] |
(v) | Stereochemistry | Racemisation | Walden inversion |
(vi) | Rearrangement | common | Impossible |
Question 3: Predict the compound in each pair that will undergo solvolysis (in aqueous ethanol) more rapidly.
Sol. (a) II > I (b) II > I (c) I > II (d) II > I (e) II > I
Question 4: Give the solvolysis products expected when each compound is heated in ethanol
(a)
(b)
(c)
(d)
Sol. (a)
(b)
(c)
(d)
Question 5: The rate of SN1 reaction is fastest with
Ans. (A)
Mechanism:
R - Cl + O = S = O (g)
Note : (1) In SNi retention of the configuration takes place.
Note : (2) In presence of pyridine above reaction follow the SN2 reaction mechanism.
An increase in the rate of SN reaction due to attack of internal nucleophile is called SNNGP is also known as Anchimeric assistance.
For SNNGP
During NGP:
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1. What is a nucleophilic substitution reaction? |
2. What is the difference between SN1 and SN2 reactions? |
3. What is the role of neighboring group participation (NGP) in nucleophilic substitution reactions? |
4. Can you provide an example of a nucleophilic substitution reaction? |
5. What factors influence the mechanism of nucleophilic substitution reactions? |
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