Important Questions for Class 11 Chemistry Chapter 11 - The p-Block Elements.

Class 11 chemistry important questions with answers are provided here for Chapter 11 – The p-Block Elements. These important questions are based on the CBSE board curriculum and correspond to the most recent Class 12 chemistry syllabus. By practising these Class 12 important questions, students will be able to quickly review all of the ideas covered in the chapter and prepare for the Class 12 Annual examinations as well as other entrance exams such as NEET and JEE.

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Class 11 The p-Block Elements Important Questions with Answers

Short Answer Type Questions

Q1. Draw the structures of BCI₃.NH₃ and AlCl₃ (dimer).

Answer:

The valence shell of the core B atom in BCl₃ comprises six electrons. As a result, it is an electron-deficient molecule that requires two additional electrons to complete its octet. Hence, BCl3 is  a Lewis acid. On the other hand, NH₃ contains a lone pair of electrons that it can easily transfer. As a result, NH₃ is a Lewis base. As demonstrated below, the Lewis acid (BCl₃) and Lewis base (NH₃) interact to produce an adduct:

The valence shell of AlCl₃ comprises six electrons. As a result, it is an electron-deficient molecule that requires two additional electrons to complete its octet. On the other hand, chlorine possesses three lone pairs of electrons. As a result, the central Al atom of one molecule absorbs a lone pair of electrons from the Cl atom of the other molecule to complete its octet, resulting in a dimeric structure as seen below:

Q2. Explain the nature of boric acid as a Lewis acid in water.

Answer:

Boric acid is a weak monobasic acid that takes electrons from a hydroxyl ion to operate as a Lewis acid. Boric acid takes OH^– and forms the hydroxyl ion as a result.

Q3. Draw the structure of boric acid showing hydrogen bonding. Which species is present in

water? What is the hybridisation of boron in this species?

Answer:

In its solid state, orthoboric acid H₃BO₃ has a layer structure made up of B(OH)₃ units that form hexagonal H-bonding rings as shown below.

Q4. Explain why the following compounds behave as Lewis acids.

(i) BCl₃

(ii) AlCl₃

Answer:

Being electron deficient due to incomplete octet of central metal atom, BCl₃ and AlCl₃ behave as Lewis acids.

Q5. Give reasons for the following:

(i) CCI₄ is immiscible in water, whereas SiCl₄ is easily hydrolysed.

(ii) Carbon has a strong tendency for catenation compared to silicon.

Answer:

(i) CCl₄ is insoluble in water because water is polar and CCl₄ is non-polar. The carbon atom has no vacant orbitals to absorb the electrons given off by oxygen in the water. SiCl₄ is easily hydrolysed because Si has an empty d orbital to accommodate the electrons from the oxygen atom in water.

(ii) As atomic size increases, the bond dissociation energy drops dramatically. Because the atomic size of carbon (77 pm) is substantially smaller than that of silicon (118 pm), the dissociation energy of carbon-carbon bonds is much higher (348 kJ mol^-1) than that of silicon-silicon bonds (297 kJ mol^-1). The huge energy differential between the Carbon-Carbon and Silicon-Silicon bond energies indicates that carbon has a greater potential for catenation than silicon.

Q6. Explain the following :

o (i) CO₂ is a gas whereas SiO₂ is solid.

o (ii) Silicon forms SiF₆^2- ion whereas the corresponding fluoro compound of carbon is not known.

Answer:

(i) Carbon creates strong double bonds with two oxygen atoms due to its tiny size and good π-overlap with other small atoms, resulting in distinct CO2 molecules.

Because of its huge size, the silicon atom has poor π-overlap with other atoms. It forms four single bonds directed towards the four apices of a tetrahedron with its four valence electrons (sp³-hybridisation). Each oxygen atom is bonded to two silicon atoms, resulting in a massive three-dimensional structure that is extremely stable. As a result, CO₂ is a gas, while SiO₂ is solid.

(ii) Because all of the 3d orbitals in silicon are in the valence shell, the octet expands to form an sp³d² hybridisation. The valence shell of carbon, on the other hand, lacks d-orbitals. Only sp³ hybridisation is possible. As a result, carbon is unable to form the CF₆^2- anion.

Q7. The +1 oxidation state in group 13 and +2 oxidation state in group 14 becomes more and

more stable with increasing atomic number. Explain.

Answer:

The tendency of valence shell s-electrons to engage in bond formation declines as we proceed down the group in groups 13 and 14. The intermediate d- and f-electrons are ineffectual at sheltering the valence shell’s s-electrons. The inert pair effect is what we call it.

As a result, s-electrons in group 13 and 14’s valence shells are unable to participate in bonding. As a result, the +1 and +2 oxidation states in groups 13 and 14 become more stable as the atomic number increases.

Q8. Carbon and silicon both belong to the group 14, but inspite of the stoichiometric similarity,

the dioxides, (i.e., carbon dioxide and silicon dioxide), differ in their structures. Comment.

Answer:

Carbon, being the first member of group 14, has a strong propensity to create stable p-p multiple bonds with other front row elements like nitrogen and oxygen. Both oxygen atoms are connected to the carbon atom by double bonds in CO₂.

Due to its huge atomic size, silicon, on the other hand, is hesitant to create p-p multiple bonding. Single covalent bonds bind oxygen atoms to silicon atoms in SiO₂, resulting in a three-dimensional network.

Q9. If a trivalent atom replaces a few silicon atoms in three-dimensional network of silicon

dioxide, what would be the type of charge on the overall structure?

Answer:

In SiO₂, the tetrahedral atoms are responsible for the three-dimensional structure of the Si atoms. These atoms are replaced by trivalent atoms, which have a free valence electron, resulting in one negative charge in the structure. As a result, the entire compound has a negative charge.

Q10. When BCl₃ is treated with water, it hydrolyses and forms [B[OH]₄]^– only whereas AlCl₃ in

acidified aqueous solution forms [AI (H₂O)₆]³⁺ ion. Explain what is the hybridisation of

boron and aluminum in these species.

Answer:

BCl₃ + 3H₂O → B(OH)₃ + 3HCl

B(OH)₃ + H₂O → [B(OH)₄]^– + H⁺

B(OH)₃ accepts an electron pair (as OH^–) due to its incomplete octet, resulting in [B(OH)₄]^–. Boron has one 2s orbital and three 2p orbitals in this ion. As a result, hybridisation of B in [B(OH)₄]^– is sp³.

Hence, the hybridisation of Al is sp³d².

Q11. Aluminium dissolves in mineral acids and aqueous alkalies and thus shows amphoteric

character. A piece of aluminium foil is treated with dilute hydrochloric acid or dilute sodium hydroxide solution in a test tube and on bringing a burning matchstick near the mouth of the test tube, a pop sound indicates the evolution of hydrogen gas. In the same activity when performed with concentrated nitric acid, the reaction doesn’t proceed. Explain the reason.

Answer:

Because aluminium is amphoteric, it dissolves in acids and alkalis, releasing H₂ gas, which burns with a pop.

2Al + 6HCl → 2AlCl₃ + 3H₂

2Al + NaOH + 2H₂O → 2NaAlO₂ + 3H₂

When Al interacts with concentrated HNO₃, a thin coating of Al₂O₃ forms on the metal’s surface, preventing further reaction. This layer is referred to as the protective layer.

2Al + 6HNO₃ → Al₂O₃ + 6NO₂ + 3H₂O

Concentrated nitric acid does not react with aluminium. When aluminium combines with nitric acid, a protective layer of “Aluminium Oxide” is generated since “nitric acid” is an oxidising agent. Nitric acid cannot react with the “inner aluminium metal” due to the protective layer of “Aluminium oxide.”

Q12. Explain the following :

o (i) Gallium has higher ionisation enthalpy than aluminium.

o (ii) Boron does not exist as B³⁺ ion.

• (iii) Aluminium forms [AIF₆]^3- ion but boron does not form [BF₆]^3- ion.

• (iv) PbX₂ is more stable than PbX₄.

o (v) Pb⁴⁺ acts as an oxidising agent but Sn²⁺ acts as a reducing agent.

o (vi) Electron gain enthalpy of chlorine is more negative as compared to fluorine.

o (vii) TI(NO₃)₃ acts as an oxidising agent.

o (viii) Carbon shows catenation property but lead does not.

o (ix) BF₃ does not hydrolyse.

o (x) Why does the element silicon, not form a graphite like structure whereas carbon

does.

Answer:

(i) Due to the inability of d- and f- electrons, which have a screening effect, to compensate for the rise in nuclear charge, the Ionisation enthalpy value of Ga is larger than that of Al.

(ii) The valence shell of Boron contains three electrons. Boron does not lose all of its valence electrons to create B3+ ions due to its small size and high sum of the first three ionisation enthalpies, ΔiH1 + ΔiH2 + ΔiH3.

(iii) Because aluminium contains a d-orbital in its valence shell, it has created (AlF₆)^3-, whereas boron does not have a d-orbital in its valence electron. As a result, the maximum boron covalence cannot be greater than 4. As a result, while Aluminum can produce [AlF₆]^3-, Boron cannot form [BF₆]^3-.

(iv) The +2 oxidation state of Pb is more stable than the +4 oxidation state due to the inert pair effect. As a result, PbX₂, which has a +2 oxidation state, is more stable than PbX₄, which has a +4 oxidation state.

(v) Due to the inert pair effect, Pb⁴⁺ gains two electrons and becomes Pb²⁺, which is more stable. By shedding electrons, Sn²⁺ is less stable than Sn⁴⁺. As a result, Pb⁴⁺ is an oxidising agent, whereas Sn²⁺ is a reducing agent.

(vi) In comparison to chlorine, fluorine has a lower negative electron gain enthalpy. It’s because fluorine atoms are so small. As a result, substantial interelectronic repulsions exist in fluorine’s relatively small 2p orbitals, resulting in less attraction for the incoming electron.

(vii) Tl’s +3 oxidation state is less stable than its +1 oxidation state because of a significant inert pair effect. Because Tl(NO₃)₃ has a +3 oxidation state, it may easily gain two electrons and become TlNO₃, which has a +1 oxidation state. Tl(NO₃)₃, as a result, works as an oxidising agent.

(viii) Carbon atoms have a natural tendency to build chains and rings by forming covalent bonds with one another. Catenation is the term for this characteristic. This is due to the fact that C﹣C bonds are extremely strong. As the size of the group grows larger, electronegativity diminishes, and the tendency to demonstrate catenation reduces. Bond enthalpy values clearly demonstrate this.

(ix) BF₃ does not entirely hydrolyse like the other boron halides. Instead, it forms boric acid and fluoroboric acid when it hydrolyses incompletely. This is due to the H₃BO₃ reaction that occurs when the HF is first produced.

(x) Carbon is sp³ hybridised in graphite. Because of its small size and maximum electronegativity in group 14, carbon has a tendency to form numerous pπ−pπ bonds. Silicon cannot form numerous bonds due to its huge size and low electronegativity. As a result, silicon is unable to form a graphite-like structure.

Q13. Identify the compounds A, X and Z in the following reactions :

Answer:

The solution is:

Q14. Complete the following chemical equations:

Answer:

The solution is :

4BF₃ + 3LiAlH₄ → B₂H₆ + 3LiF + 3AlF₃

2B₂H₆ + 6H₂O → 2H₃BO₃ + 6H₂

3B₂H₆ + 3O₂ → B₂O₃ + 3H₂O ………. Under heat.

Long Answer Type Questions

Q1. Describe the general trends in the following properties of the elements in Groups 13 and

14.

(i) Atomic size

(ii) Ionisation enthalpy

(iii) Metallic character

(iv) Oxidation states

(v) Nature of halides

Answer:

(i) Group 13 has a larger atomic size because the atomic size grows as you go down a group, therefore an extra shell with electrons is added, resulting in a poor shielding effect.

The presence of the shielding effect is high because the d and f orbitals are completely occupied in Group14, which has a covalent radius and a small radius.

(ii) The group has no effect on the ionisation enthalpy, which decreases as the size of the group grows. Because the nuclear charge is complemented by the screening effect, Group 13 has unpredictable ionisation enthalpy.

Because of the low shielding effect, Group 14 has a high ionisation enthalpy, which then decreases.

(iii) Except for Boron, all elements in group 13 are non-metallic, and the low metallic character is due to the shielding effect.

Sn and Pb are metals in Group 14, and the metallic nature grows as the group progresses, therefore carbon is categorised as a non-metal and the rest are metalloids.

(iv) Group 13: has +3 and +1 oxidation states. The stability of +1 increases while that of +3 decreases down the group.
Group 14: has +4 and +2 oxidation states. The stability of +2 increases while that of +4 decreases down the group.

(v) Group 13 : All form trihalides of type MX3(Write ”3” as subscript) . The stability decreases from Boron to thallium .
Group 14: All form tetrahalides of type MX4 (Write ”4” as subscript). The stability decreases down the group. Ge, Sn and Pb also form dihalides of type MX2( write ”2” as subscript). The stability increases down the group.

Q2. Account for the following observations:

(i) AlCl₃ is a Lewis acid

(ii) Though fluorine is more electronegative than chlorine yet BF₃ is a weaker Lewis acid

than BCl₃

(iii) PbO₂ is a stronger oxidising agent than SnO₂

(iv) The +1 oxidation state of thallium is more stable than its +3 state.

Answer:

(i) Because the Al atoms in AlCl3 have only six electrons in their valence shell, they can only take a pair of octets. As a result, it functions as a Lewis acid.

(ii) Boron and fluorine do not have d−orbitals. Hence, both of these participate in strong 2p(B)−2p(F) back π-bonding. On the other hand, due to large size and availability of vacant d−orbitals, Cl does not participate in such type of back π-bonding. Hence, BF3 is less acidic than BCl3.

(iii) Lead and tin are both in the +4 oxidation state in PbO₂ and SnO₂. Pb²⁺ ions are more stable than Sn²⁺ ions because of the stronger inert pair effect. The oxidation state of Sn⁺⁴ is more stable than the oxidation state of Sn⁺². However, +2 oxidation state of Pb is more stable due to the inert pair effect, Pb⁺⁴ easily converts to Pb⁺² and works as a good oxidiser.

(iv) +1 oxidation state of Tl is more stable than +3 oxidation state of Th due to inert pair effect. It has a high effective nuclear charge due to the existence of d and f orbitals in inner shells, which have a weak shielding effect. As a result, the ns2 electron pair becomes increasingly tethered to the nucleus and unwilling to participate in bonding.

Q3. When aqueous solution of borax is acidified with hydrochloric acid, a white crystalline solid

is formed which is soapy to touch. Is this solid acidic or basic in nature? Explain.

Answer:

Boric acid is generated when an aqueous solution of borax is acidified with HCl.

Na₂B₄O₇ + 2HCl + 5H₂O → 2NaCl + 4H₃BO₃(Boric acid)

Boric acid is a crystalline white substance. It has a soapy feel to it due to its planar layered structure. It isn’t a protonic acid because it doesn’t ionise in water to release H⁺ ions. B(OH)₃ absorbs a pair of electrons from the oxygen atom of a molecule of H₂O, releasing a proton, due to the tiny size of the boron and the presence of only six electrons in its valence shell. As a result, it behaves as a Lewis acid.

Q4. Three pairs of compounds are given below. Identify that compound in each of the pairs

Group 13 element  is in more stable oxidation state

Give reason for your choice. State the nature of bonding also.

• (i) TICl₃, TICI

• (li) AlCl₃ , AICI

• (ili) InCl₃, InCl

Answer:

(i) TlCl is a more stable compound. It’s a type of ionic compound. Because the inert pair effect is strongest in thallium, the +1 oxidation state is more stable than the +3 state.

(ii) AlCl₃ is a more stable compound. The anhydrous state is covalent, whereas the aqueous state is ionic. The oxidation state of +3 is more stable than that of +1. Because AlCl₃ has no inert pair effect, it is a covalent molecule that accepts electrons to become stable and so acts as a Lewis acid.

(iii) lnCl₃ is a more stable compound. In nature, the anhydrous state is more covalent and less ionic. The inert pair effect is significant, although not as strong as in thallium. Indium exists in both +1 and +3 oxidation states due to the inert pair effect, with the +3 oxidation state being more stable than the +1 oxidation state.

Q5. BCl₃ exists as a monomer whereas AlCl₃ is dimerised through halogen bridging. Give reason.

Explain the structure of the dimer of AlCl₃ also.

Answer:

Despite the fact that BCl₃ is an electron-deficient molecule, it exists as a monomer. It gains stability through the formation of pπ−pπ back bonding. Chlorine donates two electrons to boron’s vacant 2p-orbital. The lengths of the three bonds are identical.

As a result, the backbonding that gives the molecule its double bond property is delocalised. AlCl₃ is an electron-poor chemical as well. Back bonding is not possible in AlCl₃ because aluminium is greater than boron. The octet of aluminium metal is completed by creating a coordinating connection with the chlorine atom of another molecule, AlCl₃. As a result, a dimer molecule is formed when chlorine atoms build bridges between two Al atoms.

Q6. Boron fluoride exists as BF₃ but boron hydride doesn’t exist as BH₃. Give reason. In which

form does it exist? Explain its structure.

Answer:

Due to pπ−pπ back bonding, BF₃ exists as a monomer. Fluorine donates two electrons to the boron’s empty 2p-orbital. The delocalisation minimises the electron shortage on boron, boosting the BF₃ molecule’s stability. Back bonding does not occur in BH₃ due to the absence of a lone pair of electrons on H.

To put it another way, boron’s electron shortage persists, and BH₃ does not exist. BH₃ dimerises to create B₂H₆ to decrease electron deficit. As a result, diborane is the dimeric form of boron hydride. A lone pair exists in hydrogen in BH₃. As a result, it is unable to compensate for the boron deficit by dimerising to generate B₂H₆, which has the structure of a banana.

Q7. (i) What are silicones? State the uses of silicones.

(i) What are boranes? Give chemical equation for the preparation of diborane.

Answer:

(i) Silicones are a form of polymer also known as polysiloxanes. This category of polymers includes any inert, synthetic material made up of iterative units of siloxane. It’s a chain of oxygen and silicon atoms that’s usually mixed with hydrogen and carbon.

Silicones are the most popular sort of synthetic object on the market today, and they’re utilised in thousands of applications that ensure people’s safety and well-being.

Uses of Silicones include:

1. Silicones are non-toxic, heat-stable, and hydrophobic (water-repellent) by nature. By exposing them to silicone vapour, they are used to make waterproof cloth, paper, wool, wood, and other materials.
2. Silicone oils are lubricants that can be utilised at both high and low temperatures.
3. Electric motors and other electrical appliances use them as insulating materials.
4. Silicone rubbers are important because they keep their suppleness across a wide temperature range.
5. To make them resistant to the effects of high temperatures, sunshine, and damp, these are blended with paints and enamels.

(ii) Boranes, like Alkanes, are binary compounds combining boron and hydrogen. Diborane is a type of covalent hydride with the formula B₂H₆. Boron trifluoride is treated with LiAlH₄ in diethyl ether to produce diborane.

4BF₃ + 3LiAlH₄ → 2B₂H₆ + 3LIF + 3AlF₃

The oxidation of sodium borohydride with iodine can also be used to make it. Consider the following scenario:

2NaBH₄ + I₂ → B₂H₆ + 2NaI + H₂

The reaction of a metal hydride with boron produces diborane. This process is frequently utilised in the industrial manufacturing of diborane. The reaction of iodine with sodium borohydride in diglyme can yield diborane in modest doses.

When magnesium boride is heated with HCl, a mixture of volatile boranes forms:

2Mg₃B₂ + 12HCl → 6MgCl₂ + B₄H₁₀ + H₂

B₄H₁₀ + H₂ → 2B₂H₆

Q8. A compound (A) of boron reacts with NMe₃ to give an adduct (B) which on hydrolysis

gives a compound (C) and hydrogen gas. Compound (C) is an acid. Identify the

compounds A, B and C. Give the reactions involved.

Answer:

The breakdown of polymers into monomers using water molecules and an enzyme catalyst is known as hydrolysis. Hydrolysis reactions release energy by breaking bonds.

Because compound A combines with Boron to form [B], it is a Lewis acid because it accepts electrons. When [B] interacts with [C], hydrogen is liberated, and [A] becomes B₂H₆. Thus B is 2BH₃NMe₃, while C is boric acid.

A = B₂H₆ (Diborane)

B = 2BH₃NMe₃ (Adduct)

C = 2B₃N₃H₆ (Inorganic Borazine)

B₂H₆ + 2NMe₃ → 2BH₃NMe₃

3B₂H₆ + 6NH₃ → 3[BH₃(NH₃)₂] + [BH₄]⁺ → 2B₃N₃H₆ + 12H₂

Q9. A nonmetallic element of group 13, used in making bullet proof vests is extremely hard

solid of black colour. It can exist in many allotropic forms and has unusually high melting

point. Its trifluoride acts as Lewis acid towards ammonia. The element exhibits maximum

covalency of four. Identify the element and write the reaction of its trifluoride with

ammonia. Explain why does the trifluoride act as a Lewis acid.

Answer:

Boron is the nonmetallic element of group 13. It has a grey-black colour and is quite hard in nature. It has a high melting point of 2300 degrees Celsius. It comes in two allotropic varieties: Amorphous powder (a) crystalline solid (b) amorphous solid. It produces BF₃ or trifluoride. Because it is an electron-deficient molecule, BF₃ works as a Lewis acid.

BF₃ + NH₃ → H₃N → BF₃

Boron accepts an electron pair donated by NH₃ to saturate its outer shell. Because the valence shell of Boron has four orbitals, it has a maximum covalency of four. As monomeric trihalides lack electrons, they act as powerful Lewis acids. Trifluoride of boron reacts readily with Lewis bases like NH₃ to complete the octet of boron. Boron is unable to exceed the above-mentioned covalence due to the absence of d electrons.

Q10. A tetravalent element forms monoxide and dioxide with oxygen. When air is passed over

heated element (1273 K), producer gas is obtained. Monoxide of the element is a

powerful reducing agent and reduces ferric oxide to iron. Identify the element and write

formulas of its monoxide and dioxide. Write chemical equations for the formation of

producer gas and reduction of ferric oxide with the monoxide.

Answer:

Carbon is a tetravalent element that is being discussed. As a result of the reaction with oxygen, it can form carbon monoxide and dioxide.

Formation of producer gas is as follows:

1. 2C + O₂ → 2CO (Carbon is directly oxidised as a result of this process)
2. HCOOH → H₂O + CO (At 373K, formic acid is dehydrated with concentrated H2SO4)
3. C + H₂O → CO + H₂ (Water gas is a combination of CO and H₂)
4. 2C + O₂ + 4N₂ → 2CO + 4N₂ (The producer gas is a combination of CO and N2)

Ferric Oxide Reduction Using Monoxide:

Fe₂O₃ + 3CO → 2Fe + 3CO₂