what is difference between sn1 and sn2 mechanism also why needed please tell proper answer not for gaining points
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Answered by
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Characteristics of SN¹ reactions: -
1.Two step reaction.
2.Rate of reaction = K [R — L]
3.It is a first order reaction.
4.Carbocation intermediate is formed. rearrangement of carbocation is possible.
5.Rate is dependent on stability of carbocation. [3°>2°>1°]
3.Products formed will be both R- and S- form i.e. mirror image
Characteristics of SN² reactions: -
1.Single step reaction.
2.Rate of reaction = K [R — L] [Nu(:)]
3.It is a second order reaction.
4.Rate is dependent on concentration and strength of Nucleophile.
5.Transition state is formed which is sp² hybridized, planar structure. (Not sp³d as Carbon doesn't have d orbital.)
6Reaction is favored by low temperature. High temperature leads to E² reaction.
1.Two step reaction.
2.Rate of reaction = K [R — L]
3.It is a first order reaction.
4.Carbocation intermediate is formed. rearrangement of carbocation is possible.
5.Rate is dependent on stability of carbocation. [3°>2°>1°]
3.Products formed will be both R- and S- form i.e. mirror image
Characteristics of SN² reactions: -
1.Single step reaction.
2.Rate of reaction = K [R — L] [Nu(:)]
3.It is a second order reaction.
4.Rate is dependent on concentration and strength of Nucleophile.
5.Transition state is formed which is sp² hybridized, planar structure. (Not sp³d as Carbon doesn't have d orbital.)
6Reaction is favored by low temperature. High temperature leads to E² reaction.
Answered by
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( for mechanism of sn2 see attached file 1)
♦♦♦• Reaction is:
Stereospecific (Walden Inversion of configuration)
Concerted - all bonds form and break at same time
Bimolecular - rate depends on concentration of both nucleophile and substrate
♦♦♦• Substrate:
Best if primary (one substituent on carbon bearing leaving group)
works if secondary, fails if tertiary
♦♦♦• Nucleophile:
Best if more reactive (i.e. more anionic or more basic)
♦♦♦• Leaving Group: Best if more stable (i.e. can support negative charge well):
TsO- (very good) > I- > Br- > Cl- > F- (poor)
RF , ROH , ROR , RNH2
♦♦♦• Solvent:
Polar Aprotic (i.e. no OH) is best.
For example dimethylsulfoxide ( CH3 ( HCON(CH3)2 ), acetonitrile ( CH3
Protic solvents (e.g. H2 but can be used in some case are NEVER Substrates for SN2 reactions
Leaving Groups on double-bonded carbons are never replaced by SN2 reactions SOCH3 ), dimethylformamide CN ). O or ROH) deactivate nucleophile by hydrogen bonding
( for mechanism of sn1 see attached file 2)
♦♦♦• Reaction is:
Non-stereospecific (attack by nucleophile occurs from both sides)
Non-concerted - has carbocation intermediate
Unimolecular - rate depends on concentration of only the substrate
♦♦♦• Substrate:
Best if tertiary or conjugated (benzylic or allylic) carbocation can be formed as leaving group departs
never primary
♦♦♦• Nucleophile:
Best if more reactive (i.e. more anionic or more basic)
♦♦♦• Leaving Group: Same as SN2
best if more stable (i.e. can support negative charge well)
Examples: TsO- (very good) > I- > Br- > Cl- > F- (poor)
However, tertiary or allylic ROH or ROR' can be reactive under strongly acidic conditions to replace OH or OR
♦♦♦• Solvent:
Same as SN2
Polar Aprotic (i.e. no OH) is best
Examples: dimethylsulfoxide ( CH3 ( HCON(CH3)2 ), acetonitrile ( CH3
Protic solvents (e.g. H2
SOCH3 ), dimethylformamide CN ).
O or ROH) deactivate but can be used in some cases
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