Haloalkanes And Haloarenes MCQs With Answers – Part 4 (Class 12 Chemistry)
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Haloalkanes and Haloarenes MCQs with Answers – Part 4 (Class 12 Chemistry)

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301. A student records the following observations after treating suitable haloalkanes with ethanolic \(\mathrm{AgNO_3}\).
SamplePrecipitate colourInferred halogen
PWhiteChlorine
QCreamBromine
RYellowIodine
The appropriate evaluation is:
ⓐ. only P and Q are correct
ⓑ. only Q and R are correct
ⓒ. all three are correct
ⓓ. only P and R are correct
302. Three colourless liquids are separately treated with ethanolic \(\mathrm{AgNO_3}\). Sample P gives an immediate cream precipitate, sample Q gives the same cream precipitate after several minutes, and sample R shows little change at room temperature. If all three are bromoalkanes, the most reasonable assignment is:
ⓐ. P is primary, Q is tertiary, and R is secondary
ⓑ. P is secondary, Q is primary, and R is tertiary
ⓒ. P, Q, and R must all have identical structures
ⓓ. P is tertiary, Q is secondary, and R is primary
303. Chlorobenzene and vinyl chloride usually fail to give a rapid silver chloride precipitate with ethanolic \(\mathrm{AgNO_3}\) because:
ⓐ. their \(\mathrm{C_{sp^2}-Cl}\) bonds resist ionisation
ⓑ. both substances contain no chlorine atoms
ⓒ. chloride ion forms a highly soluble silver chloride complex immediately
ⓓ. their carbon–chlorine bonds are weaker than those in tertiary alkyl chlorides
304. Two equimolar bromoalkanes eventually form the same amount of \(\mathrm{AgBr}\), but sample P reaches its final precipitate amount much sooner than sample Q. On a graph of precipitate amount against time, this means that:
ⓐ. P must have a lower final plateau than Q
ⓑ. P rises faster initially; both curves reach the same plateau
ⓒ. Q forms a different-coloured precipitate because it reacts more slowly
ⓓ. both curves must be horizontal from the start
305. Use the graph description below. A reaction-coordinate diagram has reactants and products separated by a single energy maximum, with no minimum between them. This profile is most consistent with:
ⓐ. a two-step reaction containing a carbocation intermediate
ⓑ. a radical chain containing initiation and propagation stages
ⓒ. an elimination reaction that passes through two isolated intermediates
ⓓ. a concerted \(\mathrm{S_N2}\) reaction with one transition state
306. In the transition state of an \(\mathrm{S_N2}\) reaction involving \(\mathrm{Nu^-}\) and \(\mathrm{R-X}\):
ⓐ. the carbon is bonded fully to both \(\mathrm{Nu}\) and \(\mathrm{X}\) as a stable compound
ⓑ. the carbon–halogen bond has broken completely before the carbon–nucleophile bond begins forming
ⓒ. the nucleophile remains unbonded until a carbocation has formed
ⓓ. the carbon–nucleophile and carbon–halogen bonds are both partial
307. A secondary haloalkane gives an unrearranged substitution product under conditions known to favour direct backside attack. The absence of a rearranged carbon skeleton supports:
ⓐ. a concerted \(\mathrm{S_N2}\) pathway
ⓑ. a free-carbocation \(\mathrm{S_N1}\) pathway
ⓒ. a radical-chain substitution
ⓓ. an electrophilic aromatic substitution
308. The following table compares proposed features of an \(\mathrm{S_N2}\) reaction.
RowFeatureProposed description
PNumber of elementary stepsOne
QIntermediateNo free carbocation
RDirection of attackOpposite the leaving group
SBond changesFormation and cleavage occur together
The appropriate evaluation is:
ⓐ. only P and Q are correct
ⓑ. only Q, R, and S are correct
ⓒ. all four are correct
ⓓ. only P, R, and S are correct
309. The ideal rate law for an \(\mathrm{S_N2}\) reaction between a haloalkane \(\mathrm{R-X}\) and a nucleophile \(\mathrm{Nu^-}\) is:
ⓐ. \(\mathrm{rate}=k[\mathrm{R-X}][\mathrm{Nu^-}]\)
ⓑ. \(\mathrm{rate}=k[\mathrm{R-X}]\)
ⓒ. \(\mathrm{rate}=k[\mathrm{Nu^-}]^2\)
ⓓ. \(\mathrm{rate}=k[\mathrm{R-X}]^2[\mathrm{Nu^-}]\)
310. For the rate law \(\mathrm{rate}=k[\mathrm{R-X}][\mathrm{Nu^-}]\), the standard unit of \(k\) when concentration is measured in \(\mathrm{mol\,L^{-1}}\) and time in seconds is ______.
ⓐ. \(\mathrm{s^{-1}}\)
ⓑ. \(\mathrm{mol\,L^{-1}\,s^{-1}}\)
ⓒ. \(\mathrm{L\,mol^{-1}\,s^{-1}}\)
ⓓ. \(\mathrm{L^2\,mol^{-2}\,s^{-1}}\)
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