401. Study the following reaction descriptions.
| Case | Organic change | Best classification |
| P | \( \mathrm{CH_2=CH_2} \) becomes \( \mathrm{CH_3CH_3} \) | reduction |
| Q | \( \mathrm{CH_3CH_2OH} \) becomes \( \mathrm{CH_3CHO} \) | oxidation |
| R | \( \mathrm{CH_3Br} \) becomes \( \mathrm{CH_3OH} \) | substitution |
| S | \( \mathrm{CH_3CH_2OH} \) becomes \( \mathrm{CH_2=CH_2} \) | addition |
Which row contains the unsuitable classification?
ⓐ. S
ⓑ. P
ⓒ. Q
ⓓ. R
Correct Answer: S
Explanation: Row P is suitable because adding hydrogen across \( \mathrm{C=C} \) converts ethene into ethane, which is a reduction of the alkene. Row Q is suitable because ethanol is oxidised to ethanal by forming a carbonyl group. Row R is suitable because bromine is replaced by \( \mathrm{OH} \), so it is substitution. Row S is unsuitable because removal of water from ethanol to form ethene is elimination, not addition. The product pattern \( \mathrm{C-C \rightarrow C=C} \) with loss of a small molecule signals elimination.
402. Read the case below and answer the question.
A sequence begins with \( \mathrm{CH_3CH_2Br} \). In Step P, \( \mathrm{Br} \) is replaced by \( \mathrm{OH} \) to form \( \mathrm{CH_3CH_2OH} \). In Step Q, the alcohol is heated with a dehydrating agent and gives \( \mathrm{CH_2=CH_2} \). In Step R, \( \mathrm{H_2} \) is added to the alkene to form \( \mathrm{CH_3CH_3} \).
The reaction types in Step P, Step Q, and Step R are respectively:
ⓐ. addition, substitution, elimination
ⓑ. substitution, elimination, addition
ⓒ. elimination, addition, substitution
ⓓ. oxidation, rearrangement, substitution
Correct Answer: substitution, elimination, addition
Explanation: In Step P, bromine is replaced by \( \mathrm{OH} \), so the reaction is substitution. In Step Q, ethanol loses water and forms ethene, so the reaction is elimination. In Step R, hydrogen adds across the carbon-carbon double bond of ethene, so the reaction is addition. The same two-carbon skeleton appears throughout, but the reaction class changes according to what happens to bonds and groups. A sequence should be classified stepwise rather than by applying one label to the whole pathway.
403. A learner classifies \( \mathrm{CH_3CH_2Cl + KOH(aq) \rightarrow CH_3CH_2OH + KCl} \) as elimination because a salt is formed. What is the better judgement?
ⓐ. It is elimination because all reactions forming salts are eliminations
ⓑ. It is addition because \( \mathrm{KOH} \) is present
ⓒ. \( \mathrm{Cl} \) is replaced by \( \mathrm{OH} \)
ⓓ. It is rearrangement because potassium changes position
Correct Answer: \( \mathrm{Cl} \) is replaced by \( \mathrm{OH} \)
Explanation: Reaction type is decided by the change in the organic substrate. In this reaction, chloroethane becomes ethanol because \( \mathrm{Cl} \) is replaced by \( \mathrm{OH} \). The carbon skeleton remains a two-carbon saturated chain. Formation of \( \mathrm{KCl} \) is a by-product result and does not make the organic reaction elimination. Elimination would normally remove atoms from the organic molecule and form a multiple bond.
404. A hydrocarbon \( \mathrm{C_3H_6} \) adds \( \mathrm{Br_2} \) to give \( \mathrm{C_3H_6Br_2} \). If \(28.0\,\text{g}\) of the hydrocarbon reacts completely, what mass of \( \mathrm{Br_2} \) is required? Use \( \mathrm{C}=12 \), \( \mathrm{H}=1 \), and \( \mathrm{Br}=80 \).
ⓐ. \(106.7\,\text{g}\)
ⓑ. \(53.3\,\text{g}\)
ⓒ. \(80.0\,\text{g}\)
ⓓ. \(160.0\,\text{g}\)
Correct Answer: \(106.7\,\text{g}\)
Explanation: \( \textbf{Reaction idea:} \) One molecule of an alkene adds one molecule of \( \mathrm{Br_2} \) across one \( \mathrm{C=C} \) bond.
\( \textbf{Molar mass of hydrocarbon:} \)
\[
M(\mathrm{C_3H_6})=3(12)+6(1)=36+6=42\,\text{g mol}^{-1}
\]
\( \textbf{Moles of hydrocarbon used:} \)
\[
n(\mathrm{C_3H_6})=\frac{28.0}{42}=0.6667\,\text{mol}
\]
\( \textbf{Mole ratio:} \)
\[
1\,\text{mol }\mathrm{C_3H_6}:1\,\text{mol }\mathrm{Br_2}
\]
\( \textbf{Moles of \( \mathrm{Br_2} \) required:} \)
\[
n(\mathrm{Br_2})=0.6667\,\text{mol}
\]
\( \textbf{Molar mass of \( \mathrm{Br_2} \):} \)
\[
M(\mathrm{Br_2})=2(80)=160\,\text{g mol}^{-1}
\]
\( \textbf{Mass of \( \mathrm{Br_2} \):} \)
\[
m=0.6667\times160=106.7\,\text{g}
\]
\( \textbf{Final answer:} \) The required mass of \( \mathrm{Br_2} \) is \(106.7\,\text{g}\).
The calculation uses both reaction stoichiometry and molar masses, so the bromine mass is not obtained by simply comparing formula subscripts.
405. A sample of \( \mathrm{C_2H_5Br} \) undergoes complete substitution with \( \mathrm{OH^-} \) to form \( \mathrm{C_2H_5OH} \). If \(10.9\,\text{g}\) of \( \mathrm{C_2H_5Br} \) is used, what mass of ethanol is formed assuming complete conversion? Use \( \mathrm{C}=12 \), \( \mathrm{H}=1 \), \( \mathrm{O}=16 \), and \( \mathrm{Br}=80 \).
ⓐ. \(2.3\,\text{g}\)
ⓑ. \(9.2\,\text{g}\)
ⓒ. \(4.6\,\text{g}\)
ⓓ. \(10.9\,\text{g}\)
Correct Answer: \(4.6\,\text{g}\)
Explanation: \( \textbf{Organic change:} \) \( \mathrm{C_2H_5Br} \) changes to \( \mathrm{C_2H_5OH} \) by substitution.
\( \textbf{Mole relation:} \) One mole of \( \mathrm{C_2H_5Br} \) gives one mole of \( \mathrm{C_2H_5OH} \).
\( \textbf{Molar mass of \( \mathrm{C_2H_5Br} \):} \)
\[
2(12)+5(1)+80=24+5+80=109\,\text{g mol}^{-1}
\]
\( \textbf{Moles of \( \mathrm{C_2H_5Br} \):} \)
\[
n=\frac{10.9}{109}=0.100\,\text{mol}
\]
\( \textbf{Moles of ethanol formed:} \)
\[
n(\mathrm{C_2H_5OH})=0.100\,\text{mol}
\]
\( \textbf{Molar mass of ethanol:} \)
\[
M(\mathrm{C_2H_6O})=2(12)+6(1)+16=46\,\text{g mol}^{-1}
\]
\( \textbf{Mass of ethanol formed:} \)
\[
m=0.100\times46=4.6\,\text{g}
\]
\( \textbf{Final answer:} \) The mass of ethanol formed is \(4.6\,\text{g}\).
The product mass is lower because the heavy bromine atom is replaced by the lighter \( \mathrm{OH} \) group.
406. During purification by sublimation, the suitable condition is that:
ⓐ. both components must be liquids with identical boiling points
ⓑ. the impurity must react chemically with the main compound
ⓒ. the compound must be insoluble in every solvent
ⓓ. solid-vapour-solid change of one component
Correct Answer: solid-vapour-solid change of one component
Explanation: Sublimation is used for solids that can pass directly from solid state to vapour state on heating. The vapour is then cooled and deposited as a solid. This technique is useful when the desired solid sublimes but the impurity does not, or when the impurity sublimes differently. It is a physical separation method and should not depend on chemical reaction with the impurity. The method is not suitable merely because a sample is solid; the subliming behaviour is the deciding feature.
407. A mixture contains \( \mathrm{naphthalene} \) and common salt. The most suitable purification method for separating \( \mathrm{naphthalene} \) is:
ⓐ. simple distillation
ⓑ. sublimation
ⓒ. steam distillation
ⓓ. chromatography only
Correct Answer: sublimation
Explanation: \( \mathrm{Naphthalene} \) is a sublimable organic solid. Common salt does not sublime under ordinary sublimation conditions. On heating the mixture, \( \mathrm{naphthalene} \) can change into vapour and then deposit as solid on a cooler surface. The salt remains behind as non-sublimed residue. This makes sublimation more appropriate than distillation, which is mainly used for liquid mixtures or volatile liquids.
408. Crystallisation purifies an organic solid mainly because:
ⓐ. every impurity must crystallise before the main compound
ⓑ. the compound is converted into vapour without melting
ⓒ. hot-solvent dissolution and cooling crystallisation
ⓓ. the solvent must react with the impurity to form a gas
Correct Answer: hot-solvent dissolution and cooling crystallisation
Explanation: Crystallisation depends on different solubilities of the compound and impurities in a chosen solvent. The impure solid is usually dissolved in a minimum amount of hot solvent. On cooling, the desired compound crystallises out more purely, while many impurities remain in solution. The solvent should not normally react with the compound being purified. This method is especially useful for solids whose solubility changes appreciably with temperature.
409. A solid organic compound is very soluble in hot ethanol but only sparingly soluble in cold ethanol. Most coloured impurities remain dissolved even after cooling. The best purification method is:
ⓐ. crystallisation from ethanol
ⓑ. fractional distillation
ⓒ. steam distillation
ⓓ. differential extraction with water only
Correct Answer: crystallisation from ethanol
Explanation: The given solubility pattern is ideal for crystallisation. The organic compound dissolves well in hot ethanol, so a hot saturated solution can be prepared. On cooling, the compound becomes much less soluble and separates as crystals. Since the coloured impurities remain in the mother liquor, they are removed when the crystals are filtered. Fractional distillation and steam distillation are not the first choice for purifying a non-volatile solid described through solvent solubility.
410. A crystallisation experiment starts with \(12.0\,\text{g}\) of impure solid containing \(80.0\%\) desired compound by mass. After recrystallisation, \(8.4\,\text{g}\) of pure crystals is obtained. What is the percentage recovery of the desired compound?
ⓐ. \(70.0\%\)
ⓑ. \(87.5\%\)
ⓒ. \(75.0\%\)
ⓓ. \(96.0\%\)
Correct Answer: \(87.5\%\)
Explanation: \( \textbf{Mass of impure sample:} \) \(12.0\,\text{g}\).
\( \textbf{Purity of desired compound in original sample:} \) \(80.0\%\).
\( \textbf{Actual desired compound initially present:} \)
\[
\frac{80.0}{100}\times12.0=9.60\,\text{g}
\]
\( \textbf{Mass of pure crystals recovered:} \) \(8.4\,\text{g}\).
\( \textbf{Percentage recovery relation:} \)
\[
\%\text{ recovery}=\frac{\text{mass recovered}}{\text{mass originally present}}\times100
\]
\( \textbf{Substitution:} \)
\[
\%\text{ recovery}=\frac{8.4}{9.60}\times100
\]
\( \textbf{Calculation:} \)
\[
\%\text{ recovery}=87.5\%
\]
\( \textbf{Final answer:} \) The percentage recovery is \(87.5\%\).
The denominator is the amount of desired compound originally present, not the total impure sample mass.
411. Simple distillation is most suitable when:
ⓐ. two liquids have nearly identical boiling points
ⓑ. a solid directly changes to vapour without becoming liquid
ⓒ. a coloured spot must move on an adsorbent
ⓓ. volatile liquid from non-volatile impurities
Correct Answer: volatile liquid from non-volatile impurities
Explanation: Simple distillation separates substances based on difference in volatility. It is useful when a volatile liquid can vaporise and then condense away from non-volatile impurities. It can also work when two liquids have a large difference in boiling points. If boiling points are very close, fractional distillation is more suitable because repeated vapour-condensation cycles are needed. Distillation is therefore a boiling-point-based purification method.
412. Fractional distillation is preferred over simple distillation for a mixture of two miscible liquids when:
ⓐ. their boiling points are close
ⓑ. one component is a sublimable solid
ⓒ. both components are completely non-volatile
ⓓ. the mixture contains only insoluble salts
Correct Answer: their boiling points are close
Explanation: Fractional distillation is used for separating miscible liquids with relatively close boiling points. The fractionating column provides repeated vaporisation and condensation steps. This improves separation because the vapour becomes richer in the more volatile component as it rises through the column. Simple distillation is less effective when boiling points are close. The choice between simple and fractional distillation depends on volatility difference, not on colour or chemical family alone.
413. Study the distillation choices below.
| Mixture or sample | Suggested method |
| P. Liquid with non-volatile impurity | simple distillation |
| Q. Two miscible liquids with close boiling points | fractional distillation |
| R. Sublimable solid mixed with non-sublimable impurity | sublimation |
| S. Two miscible liquids with close boiling points | simple distillation only |
Which row contains the unsuitable suggestion?
ⓐ. P
ⓑ. Q
ⓒ. R
ⓓ. S
Correct Answer: S
Explanation: Row P is suitable because a volatile liquid can be separated from non-volatile impurities by simple distillation. Row Q is suitable because close-boiling miscible liquids require fractional distillation for better separation. Row R is suitable because sublimation works when one solid sublimes and the impurity does not. Row S is unsuitable because close boiling points are exactly the situation where simple distillation alone is usually inefficient. The fractionating column is used to improve separation between liquids of similar volatility.
414. A mixture contains two miscible liquids, P and Q. P boils at \(78^\circ\text{C}\), while Q boils at \(82^\circ\text{C}\). Both are stable at their boiling points. Which method is most suitable?
ⓐ. sublimation
ⓑ. crystallisation
ⓒ. steam distillation
ⓓ. fractional distillation
Correct Answer: fractional distillation
Explanation: The two liquids are miscible, so they cannot be separated by simple layer separation. Their boiling points differ by only \(4^\circ\text{C}\), which is a small difference. Fractional distillation is designed for such close-boiling liquid mixtures. The fractionating column allows repeated condensation and vaporisation, improving enrichment of the lower-boiling component. Simple distillation would give poor separation because both liquids would tend to vaporise over a similar temperature range.
415. A distillation curve is drawn for a pure liquid. The temperature remains nearly constant while most of the liquid distils. What does the horizontal region most strongly indicate?
ⓐ. continuous increase in molecular formula
ⓑ. boiling at the component's boiling point
ⓒ. formation of a new functional group during heating
ⓓ. sublimation of a solid impurity
Correct Answer: boiling at the component's boiling point
Explanation: During distillation of a pure liquid, the temperature remains nearly constant at the boiling point while liquid and vapour coexist. A horizontal region on the temperature-time graph indicates that the distilling vapour has a nearly constant composition. In a mixture, the temperature may change as composition changes during distillation. The graph does not by itself show formation of a new functional group. The plateau is linked to phase change at a characteristic boiling point.
416. Steam distillation is especially useful for separating an organic compound that is:
ⓐ. completely non-volatile and strongly ionic
ⓑ. a salt that dissolves only in hot water
ⓒ. a solid that must sublime under dry heating
ⓓ. steam-volatile and water-immiscible
Correct Answer: steam-volatile and water-immiscible
Explanation: Steam distillation is used for substances that are volatile in steam and are usually immiscible with water. The method allows distillation at a temperature lower than the normal boiling point of the organic compound. This is useful for compounds that may decompose if heated strongly. The organic compound co-distils with steam and can later be separated from the water layer if immiscible. The method is not meant for completely non-volatile salts or ordinary crystallisation of solids.
417. A mixture contains an organic liquid that is immiscible with water and has appreciable vapour pressure in steam. It decomposes if heated near its normal boiling point. The best purification method is:
ⓐ. steam distillation
ⓑ. fractional crystallisation
ⓒ. sublimation under dry conditions
ⓓ. simple filtration only
Correct Answer: steam distillation
Explanation: The liquid is immiscible with water and volatile in steam, so it can be carried over with steam. Since it decomposes near its normal boiling point, ordinary distillation may damage it. Steam distillation allows separation at a lower temperature because the mixture boils when the sum of vapour pressures reaches atmospheric pressure. This protects heat-sensitive compounds. Filtration would not separate a liquid mixture based on volatility.
418. A steam-distillation setup contains an organic liquid immiscible with water. At the distillation temperature, the vapour pressures are \(P_{\text{water}}=88\,\text{kPa}\) and \(P_{\text{organic}}=13\,\text{kPa}\). If atmospheric pressure is \(101\,\text{kPa}\), what conclusion is correct?
ⓐ. the mixture cannot boil until the organic vapour pressure alone becomes \(101\,\text{kPa}\)
ⓑ. the mixture can boil because \(P_{\text{water}}+P_{\text{organic}}=101\,\text{kPa}\)
ⓒ. only the liquid with higher molar mass can distil
ⓓ. steam distillation is impossible unless both liquids are miscible
Correct Answer: the mixture can boil because \(P_{\text{water}}+P_{\text{organic}}=101\,\text{kPa}\)
Explanation: \( \textbf{Condition for steam distillation:} \) For immiscible liquids, the total vapour pressure is the sum of the individual vapour pressures.
\( \textbf{Given vapour pressure of water:} \)
\[
P_{\text{water}}=88\,\text{kPa}
\]
\( \textbf{Given vapour pressure of organic liquid:} \)
\[
P_{\text{organic}}=13\,\text{kPa}
\]
\( \textbf{Total vapour pressure:} \)
\[
P_{\text{total}}=88+13=101\,\text{kPa}
\]
\( \textbf{Atmospheric pressure:} \)
\[
P_{\text{atm}}=101\,\text{kPa}
\]
\( \textbf{Boiling condition:} \) A liquid mixture boils when its total vapour pressure equals atmospheric pressure.
\( \textbf{Final answer:} \) The mixture can boil under these conditions.
The organic liquid need not reach \(101\,\text{kPa}\) vapour pressure by itself because water contributes to the total vapour pressure.
419. Differential extraction is based on the idea that a solute distributes itself between two:
ⓐ. identical portions of the same solvent only
ⓑ. gases with no liquid phase present
ⓒ. different solubilities in immiscible solvents
ⓓ. solids with no solvent involved
Correct Answer: different solubilities in immiscible solvents
Explanation: Differential extraction uses two immiscible solvents, such as water and an organic solvent. The solute is more soluble in one solvent than the other, so it preferentially moves into that layer. The two layers can then be separated using a separating funnel. Repeated extraction can improve recovery of the solute. The method depends on distribution between two liquid phases, not on boiling point or sublimation.
420. An organic compound is dissolved in water but is much more soluble in ether. Ether and water are immiscible. The best method to recover the organic compound is:
ⓐ. fractional distillation of dry solid
ⓑ. sublimation of the aqueous solution
ⓒ. separating-funnel extraction with ether
ⓓ. crystallisation without changing solvent
Correct Answer: separating-funnel extraction with ether
Explanation: Since the organic compound is more soluble in ether than in water, it will preferentially move into the ether layer. Ether and water are immiscible, so two separate layers form. A separating funnel can be used to separate the ether layer from the aqueous layer. The ether can then be evaporated to recover the organic compound. This is an application of differential extraction based on solubility difference between immiscible solvents.