Hydrocarbons MCQs With Answers – Part 5 (Class 11 Chemistry)
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Hydrocarbons MCQs with Answers – Part 5 (Class 11 Chemistry)

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401. The reason phenyl derivatives with electron-releasing groups often give ortho and para substitution is that these positions
ⓐ. are stabilised by electron donation
ⓑ. contain no carbon atoms
ⓒ. are outside the benzene ring
ⓓ. are converted into terminal alkynes
402. Para substitution can be favoured over ortho substitution in some reactions of toluene because the para position has
ⓐ. no connection to the benzene ring
ⓑ. a terminal \( \mathrm{-C\equiv C-H} \) group
ⓒ. stronger ionic bonding than the ortho position
ⓓ. less crowding with the methyl group
403. A student says, “If a group is deactivating, it must always be meta-directing.” The best correction is that
ⓐ. all deactivating groups remove the benzene ring
ⓑ. halogens are deactivating but usually ortho-para directing
ⓒ. deactivating groups always convert benzene into alkanes
ⓓ. the word deactivating means no substitution can ever occur
404. The statement that correctly distinguishes activation and directing effect is
ⓐ. activation concerns molecular mass; directing effect concerns boiling point
ⓑ. activation concerns reaction rate; directing effect concerns substitution position
ⓒ. activation applies only to alkanes; directing effect applies only to alkynes
ⓓ. activation means addition; directing effect means combustion
405. A benzene ring has a \( \mathrm{-CH_3} \) group at position \(1\). During further nitration, the products formed mainly have \( \mathrm{-NO_2} \) at positions
ⓐ. \(2\) and \(4\)
ⓑ. \(3\) only
ⓒ. \(1\) and \(2\)
ⓓ. \(5\) only
406. A benzene ring already contains \( \mathrm{-NO_2} \) at position \(1\). If it undergoes chlorination under electrophilic substitution conditions, the major product is expected to have chlorine mainly at
ⓐ. position \(2\)
ⓑ. position \(4\)
ⓒ. position \(1\)
ⓓ. position \(3\)
407. A substituted benzene has an electron-releasing group already attached. The most reasonable prediction for its reaction with an electrophile is that it will usually
ⓐ. slower than benzene and mainly meta-directing
ⓑ. faster than benzene and mainly ortho/para-directing
ⓒ. only addition across the ring
ⓓ. permanent loss of aromaticity after the first step
408. Use the arrangement described below for a disubstituted benzene prediction. Case 1: A methyl group is already at position \(1\). Case 2: A bulky electrophile attacks the ring. Both ortho and para positions are electronically favoured. The para product may be favoured more strongly because
ⓐ. the para position gives less steric crowding with the methyl group
ⓑ. the para position is not part of the benzene ring
ⓒ. the methyl group becomes a meta director when the electrophile is bulky
ⓓ. the benzene ring changes into an alkyne before substitution
409. A table compares two substituted benzenes undergoing nitration.
Starting compoundGroup already presentExpected main orientation
P. Toluene\( \mathrm{-CH_3} \)ortho and para
Q. Nitrobenzene\( \mathrm{-NO_2} \)meta
R. Chlorobenzene\( \mathrm{-Cl} \)ortho and para, slower than benzene
S. Nitrobenzene\( \mathrm{-NO_2} \)strongly activated ortho and para
The row that needs correction is
ⓐ. P
ⓑ. Q
ⓒ. R
ⓓ. S
410. Consider the following statements about halogens on benzene. I. Halogens withdraw electron density by inductive effect. II. Halogens can donate electron density by resonance to ortho and para positions. III. Halogens are strongly activating meta directors.
ⓐ. I and III only
ⓑ. II and III only
ⓒ. I and II only
ⓓ. I, II, and III
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