Amines MCQs With Answers – Part 2 (Class 12 Chemistry)
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Amines MCQs with Answers – Part 2 (Class 12 Chemistry)

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111. Three isomeric amines P, Q, and R have the formula \(\mathrm{C_3H_9N}\). P has two \(\mathrm{N-H}\) bonds, Q has one \(\mathrm{N-H}\) bond, and R has none. Their most likely decreasing boiling-point order is:
ⓐ. P \(>\) Q \(>\) R
ⓑ. R \(>\) Q \(>\) P
ⓒ. Q \(>\) P \(>\) R
ⓓ. R \(>\) P \(>\) Q
112. Consider the following statements about water solubility of neutral amines. Statement I: Primary, secondary, and tertiary amines can accept hydrogen bonds from water. Statement II: Solubility generally decreases as the hydrophobic carbon portion becomes larger. Statement III: A tertiary amine must contain an \(\mathrm{N-H}\) bond to dissolve in water. Select the applicable combination.
ⓐ. I only
ⓑ. II and III only
ⓒ. I and III only
ⓓ. I and II only
113. A graph shows water solubility on the vertical axis and carbon-chain length on the horizontal axis for a homologous series of straight-chain primary amines. The most reasonable overall trend is:
ⓐ. solubility remains constant because every member contains \(\mathrm{NH_2}\)
ⓑ. solubility decreases as the carbon chain becomes longer
ⓒ. solubility rises because each additional carbon forms another hydrogen bond
ⓓ. solubility first becomes zero and then rises sharply
114. Methylamine is much more soluble in water than aniline mainly because:
ⓐ. aniline has no nitrogen lone pair
ⓑ. methylamine is an ionic compound in its pure state
ⓒ. aniline has a much larger hydrophobic phenyl group
ⓓ. aniline contains no polar carbon–nitrogen bond
115. Conversion of a tertiary amine \(\mathrm{R_3N}\) into the more water-soluble ionic form is represented by:
ⓐ. \(\mathrm{R_3N+H^+\rightarrow R_3NH^+}\)
ⓑ. \(\mathrm{R_3N+OH^-\rightarrow R_3NOH^-}\)
ⓒ. \(\mathrm{R_3N\rightarrow R_2NH+R}\)
ⓓ. \(\mathrm{R_3N+H_2O\rightarrow R_3N=O+H_2}\)
116. An organic solution contains a neutral amine mixed with a neutral hydrocarbon. Shaking the solution with dilute hydrochloric acid transfers the amine mainly into the aqueous layer because:
ⓐ. the hydrocarbon reacts to form a soluble chloride salt
ⓑ. hydrochloric acid removes the carbon chain from the amine
ⓒ. the amine loses nitrogen and becomes an alcohol
ⓓ. protonation converts the amine into a water-soluble salt
117. After an amine has been transferred into an aqueous layer as \(\mathrm{RNH_3^+Cl^-}\), treatment with excess sodium hydroxide followed by extraction with an organic solvent will mainly:
ⓐ. convert the amine salt into an amide
ⓑ. keep the ammonium ion permanently in the aqueous layer
ⓒ. oxidise the carbon chain to a carboxylic acid
ⓓ. liberate the neutral amine into the organic layer
118. The broad physical-state trend across an increasing homologous series of alkylamines is:
ⓐ. solids at low mass, liquids at intermediate mass, and gases at high mass
ⓑ. gases at low mass, liquids at intermediate mass, and solids at high mass
ⓒ. liquids at low mass, gases at intermediate mass, and solids at high mass
ⓓ. gases at low mass, solids at intermediate mass, and liquids at high mass
119. A freshly purified aromatic amine is colourless but gradually becomes darker on standing in air. The most reasonable explanation is:
ⓐ. the amine is converted completely into elemental carbon
ⓑ. nitrogen evaporates while the aromatic ring remains
ⓒ. exposure to air may produce coloured oxidation products
ⓓ. all aromatic amines are naturally black solids
120. A colourless, volatile compound has a strong fish-like odour and dissolves in dilute hydrochloric acid to give a clear aqueous solution. The combined observations are most consistent with:
ⓐ. a non-polar hydrocarbon that does not react with acids
ⓑ. a lower amine that forms a water-soluble ammonium salt
ⓒ. a high-molar-mass amide that is permanently ionic
ⓓ. an aromatic hydrocarbon undergoing complete oxidation
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