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The variation in oxidation states across the elements of a group or period often reflects underlying trends in electronic configurations and chemical reactivity. Let's explore the pattern of oxidation states for the elements:

(i) Boron (B) to Thallium (Tl):

• Boron (B): Boron typically exhibits an oxidation state of +3 in its compounds, as it prefers to lose its three valence electrons to achieve a stable electronic configuration.
• Aluminum (Al): Aluminum predominantly shows an oxidation state of +3 in its compounds, similar to boron, due to the loss of its three valence electrons.
• Gallium (Ga): Gallium mainly displays an oxidation state of +3, following the trend set by boron and aluminum.
• Indium (In): Indium is more versatile in its oxidation states compared to the preceding elements. It can exhibit both +1 and +3 oxidation states, with the +3 oxidation state being more common.
• Thallium (Tl): Thallium, like indium, shows a wider range of oxidation states. It can exhibit +1, +3, and even +5 oxidation states. However, the +1 oxidation state is more stable and common than the +3 or +5 states.

The trend across this group shows a general progression from +3 oxidation state (B, Al, Ga) to a more varied set of oxidation states as we move down the group, with elements like indium and thallium displaying a wider range of oxidation states due to the increasing ease of losing electrons as we move down the group.

(ii) Carbon (C) to Lead (Pb):

• Carbon (C): Carbon typically exhibits oxidation states of -4 (in compounds like methane) to +4 (in compounds like carbon dioxide). However, its most common oxidation states are +4 in carbon dioxide and -4 in methane.
• Silicon (Si): Silicon primarily shows oxidation states of +4 (in compounds like silicon dioxide) and sometimes +2 (in compounds like silane, although less common).
• Germanium (Ge): Germanium mainly exhibits an oxidation state of +4, following the trend set by carbon and silicon.
• Tin (Sn): Tin is more versatile in its oxidation states compared to the preceding elements. It can exhibit oxidation states of +2 and +4, with the +2 oxidation state being more common.
• Lead (Pb): Lead, like tin, can exhibit multiple oxidation states. It commonly shows oxidation states of +2 and +4, with the +2 oxidation state being more stable and common.

The trend across this group shows a general progression from a wider range of oxidation states (-4 to +4) for carbon to a narrower range of oxidation states (+2 to +4) for lead. This narrowing occurs due to the increasing size and decreasing electronegativity of the elements as we move down the group, making it less favorable for higher oxidation states to be stabilized.

The stability of BCl3 compared to TlCl3 can be attributed to several factors:

1. Electronegativity: Boron (B) is more electronegative than Thallium (Tl), which means that in BCl3, the bonding electrons are pulled closer to the boron atom, resulting in stronger B-Cl bonds. In contrast, Tl has relatively low electronegativity, leading to weaker Tl-Cl bonds in TlCl3.

2. Size of the central atom: Boron is smaller in size compared to thallium. In BCl3, the smaller size of boron allows for stronger bonds because the bonding electrons are held closer to the nucleus, leading to more effective overlap between the atomic orbitals, resulting in stronger bonding. In TlCl3, the larger size of thallium results in weaker bonds due to decreased effective overlap of atomic orbitals.

3. Steric effects: Thallium's larger size leads to greater steric hindrance compared to boron. This steric hindrance can destabilize the Tl-Cl bonds in TlCl3, making them more prone to breaking compared to the bonds in BCl3.

4. Polarity: BCl3 is a planar molecule with trigonal planar geometry, while TlCl3 adopts a distorted trigonal pyramidal geometry due to the lone pair on the thallium atom. This lone pair contributes to the polarity of TlCl3, making it more prone to hydrolysis and other reactions compared to the non-polar BCl3.

In summary, the combination of higher electronegativity, smaller size, and less steric hindrance in BCl3 compared to TlCl3 leads to stronger and more stable bonds in BCl3.

Boron trifluoride, BF3BF3, behaves as a Lewis acid because it can accept a pair of electrons from a Lewis base to form a coordinate covalent bond. In BF3BF3, boron has an incomplete octet, meaning it has only six electrons in its valence shell instead of the stable eight. This makes it electron deficient and eager to accept electron pairs to complete its octet.

When a Lewis base approaches BF3BF3, such as a molecule with a lone pair of electrons, like NH3NH3 or H2OH2O, the boron atom can accept the lone pair of electrons from the Lewis base, forming a coordinate covalent bond. This results in the formation of a complex, with the boron atom surrounded by more than the usual number of electron pairs, thus satisfying the octet rule.

So, in summary, BF3BF3 behaves as a Lewis acid because it can accept electron pairs from Lewis bases due to its electron deficiency.

BCl3 (boron trichloride) and CCl4 (carbon tetrachloride) have different behaviors when they come into contact with water due to their molecular structures and properties.

1. BCl3 (Boron Trichloride):

   • BCl3 is a Lewis acid, meaning it can accept a pair of electrons to form a covalent bond.
   • When BCl3 reacts with water, it acts as a Lewis acid and accepts a lone pair of electrons from water molecules to form hydrochloric acid (HCl) and boric acid (H3BO3). The reaction can be represented as: BCl3+3H2O→B(OH)3+3HClBCl3+3H2O→B(OH)3+3HCl
   • The reaction is highly exothermic and produces acidic solutions due to the formation of HCl. Boric acid formed is weakly acidic and can further react with water to form boric acid solutions.
   • Thus, BCl3 hydrolyzes vigorously in water to produce acidic solutions.

2. CCl4 (Carbon Tetrachloride):

   • CCl4 is a non-polar molecule composed of carbon and four chlorine atoms arranged symmetrically around the carbon atom.
   • It lacks any polar bonds or a permanent dipole moment, making it highly insoluble in water.
   • Due to the lack of polarity, CCl4 molecules do not interact strongly with water molecules through hydrogen bonding or dipole-dipole interactions.
   • Consequently, when CCl4 is mixed with water, it forms a separate layer on top of the water due to its lower density, and they do not readily mix or react. This property makes it useful as a non-polar solvent.

In summary, BCl3 reacts vigorously with water, undergoing hydrolysis to form acidic solutions due to its Lewis acidic nature, while CCl4 remains largely unreactive and immiscible with water due to its non-polar nature.

Boric acid is technically a weak Lewis acid rather than a protonic acid. Let me break it down:

1. Protonic Acid: Protonic acids, also known as Bronsted acids, are substances that can donate a proton (H⁺ ion) to another substance. In simpler terms, they are acids that readily release hydrogen ions in solution. Examples include hydrochloric acid (HCl) and sulfuric acid (H₂SO₄).

2. Lewis Acid: In contrast, Lewis acids are substances that can accept a pair of electrons. They don't necessarily need to donate protons; instead, they can form a coordinate covalent bond by accepting an electron pair from another substance. Boric acid falls into this category.

Boric acid, chemically represented as H₃BO₃ or B(OH)₃, can act as a Lewis acid by accepting a pair of electrons from a Lewis base. Its behavior as an acid is due to the ability of the boron atom to accept an electron pair from a base, forming a coordinate covalent bond. This property allows it to react with substances like alcohols or water to form borate ions.

While boric acid can behave as an acid in certain reactions, it's not as strong as typical protonic acids like hydrochloric acid. Its acidic properties are more subtle and primarily manifest in reactions where it acts as a Lewis acid.

As an experienced tutor registered on UrbanPro, I can confidently guide you through the process of finding the structural formulas and IUPAC names for all possible isomers of the given compounds.

(a) For C4H8 with one double bond:

1. But-1-ene (IUPAC name: 1-Butene) Structural formula: CH3CH2CH=CH2

2. But-2-ene (IUPAC name: 2-Butene) Structural formula: CH3CH=CHCH3

(b) For C5H8 with one triple bond:

1. Pent-1-yne (IUPAC name: 1-Pentyne) Structural formula: CH3CH2C≡CH

2. Pent-2-yne (IUPAC name: 2-Pentyne) Structural formula: CH3C≡CHCH3

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As an experienced tutor registered on UrbanPro, I can confidently guide you through the IUPAC names of the products obtained by the ozonolysis of the given compounds.

(i) Pent-2-ene: The ozonolysis of pent-2-ene would result in the formation of two products: ethanal and butanoic acid.

(ii) 3,4-Dimethylhept-3-ene: Ozonolysis of 3,4-dimethylhept-3-ene would yield three products: methylpropanal, 2-methylbutanal, and butanoic acid.

(iii) 2-Ethylbut-1-ene: The ozonolysis of 2-ethylbut-1-ene would generate ethanal and butanoic acid as the products.

(iv) 1-Phenylbut-1-ene: Upon ozonolysis, 1-phenylbut-1-ene would produce benzaldehyde and butanoic acid.

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As an experienced tutor registered on UrbanPro, I can assure you that UrbanPro is one of the best platforms for online coaching and tuition. Now, let's delve into your chemistry question.

When an alkene undergoes ozonolysis, it breaks the double bond and forms carbonyl compounds. In this case, we have an alkene 'A' that, upon ozonolysis, gives a mixture of ethanal and pentan-3-one.

The alkene 'A' must have five carbon atoms because pentan-3-one is one of the products, indicating that there is a five-carbon chain. Additionally, since ethanal is formed, it suggests that the alkene must have had a terminal methyl group.

So, the structure of 'A' is:

CH3−CH2−CH=CH−CH3CH3−CH2−CH=CH−CH3

This alkene is called pent-2-ene according to IUPAC naming conventions.

On UrbanPro, we delve into the nuances of organic chemistry, helping students grasp concepts effectively. When it comes to ozonolysis, it's crucial to understand the reaction mechanism and how it applies to specific alkene structures.

In the case of propanal and pentan-3-ene being the ozonolysis products of an alkene, we can deduce the structural formula of the alkene by analyzing the formation of these products.

Ozonolysis of an alkene involves cleavage of the carbon-carbon double bond, resulting in the formation of carbonyl compounds. Propanal suggests that the alkene precursor must have three carbon atoms, as propanal is a three-carbon aldehyde.

Pentan-3-ene, on the other hand, indicates that the alkene must have five carbon atoms, with a double bond located at the third carbon position in the carbon chain.

Putting this together, we can infer that the alkene in question is propene (CH2=CH-CH3).

This alkene, upon ozonolysis, would yield propanal (CH3-CHO) and pentan-3-ene (CH3-CH2-CH=CH-CH3) as the products.

Understanding the logic behind product formation in chemical reactions not only helps in solving problems but also reinforces conceptual understanding, a key aspect of effective tutoring.