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Of the four nucleophiles used in this problem, acetate is both the weakest nucleophile and the weakest base.
With 1° halides such as B, C & I substitution by an S_N2 mechanism is likely. The rate of substitution for B will be enhanced by its benzylic character, and for I will be reduced due to substituents at the μ carbon.
The 3° halides G & J will not undergo a S_N2 reaction with a nucleophile as weak as acetate. Since acetate is not a strong base, if an an E2 elimination takes place it will be slow. Ethanol is a polar solvent, but not normally sufficient to permit S_N1 or E1 reactions.
The 2° halides A, F & H are all different. A is an allylic halide so both S_N2 and S_N1 reactions will be enhanced. In ethanol the former mode of reaction should predominate. F is a very hindered halide, due to the dimethyl substitution at each β carbon atom. It is unlikely to react at all. H is an unexceptional 2° halide, and may give slow substitution by the S_N2 path. The necessary axial orientation of the nucleophile in that case would be a negative factor. Acetate is probably too weak a base to cause an E2 elimination.
The vinyl and aryl halides D & E do not undergo substitution or elimination reactions with the reagents used here.

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Of the four nucleophiles used in this problem, methanethiolate is the strongest nucleophile, and at best a modest base (pK_a = 7.3).
With 1° halides such as B, C & I substitution by an S_N2 mechanism should be rapid, especially for benzyl bromide and methyl iodide.
The 3° halides G & J are unlikely to give a S_N2 reaction even with a strong nucleophile like thiolate. Thiolate is not a strong base, but it could induce a slow E2 elimination reaction. Ethanol is a polar solvent, but not normally sufficient to permit S_N1 or E1 reactions.
The 2° halides A & H should give S_N2 substitution with this strong nucleophile. The remaining compound F is severely hindered, and could only undergo substitution very slowly. It cannot give elimination products without rearranging.
The vinyl and aryl halides D & E do not undergo substitution or elimination reactions with the reagents used here.

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Of the four nucleophiles used in this problem, cyanide is relatively good nucleophile, and a moderate base (pK_a = 9.1).
With 1° halides such as B, C & I substitution by an S_N2 mechanism should be favored, especially for benzyl bromide and methyl iodide. The rate of substitution for I will be reduced due to substituents at the β-carbon, but substitution should still be the predominate course.
The 3° halides G & J are unlikely to give a S_N2 reaction, but cyanide is a sufficiently strong base to cause E2 elimination reactions.
The 2° halides A, F & H are all different. A is an allylic halide so both S_N2 and S_N1 reactions will be enhanced. Cyanide is a fairly strong nucleophile, so the former path should be favored. H will not have this allylic enhancement, so a mixture of substitution (S_N2) and elimination (E2) is expected. The remaining compound F is severely hindered, and could only undergo substitution very slowly. It cannot give elimination products without rearranging.
The vinyl and aryl halides D & E do not undergo substitution or elimination reactions with the reagents used here.

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Of the four nucleophiles used in this problem, hydroxide is a relatively good nucleophile, and the strongest base (pK_a = 15.7). This should lead to more E2 elimination reactions than in the other cases.
With 1° halides such as B, C & I substitution by an S_N2 mechanism should be favored, especially for benzyl bromide and methyl iodide, which cannot give elimination products. The rate of substitution for I will be reduced due to substituents at the β-carbon, and the strongly basic hydroxide anion should produce a mixture of substitution and elimination products.
The 3° halides G & J will not give a S_N2 reaction with hydroxide, but this strong base will instead cause rapid E2 elimination reactions.
2° Alkyl halides generally give E2 reactions with this strong base, assuming there are β-hydrogens. This is the case for A & H; however, A is an allylic halide and will show enhanced S_N2 activity. Consequently a mixture of elimination and substitution products may result. Compound F has no β-hydrogens and is severely hindered. Substitution would be very slow if at all. Consequently, no reaction is expected, unless a skeletal rearrangement occurs.
The vinyl and aryl halides D & E do not undergo substitution or elimination reactions with the reagents used here.

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