Question

Match the reactions in column I with their reagents in column II. Column I Column II (a) \(\mathrm{CH}_{3}-\mathrm{CH}_{2}=\mathrm{CH}-\mathrm{CHO} \rightarrow \mathrm{CH}_{3} \mathrm{CH}=\mathrm{CHCOOH}\) (p) LiAIH \(_{4}\) (b) \(\mathrm{CH}_{3}-\mathrm{CH}=\mathrm{CH}-\mathrm{CHO} \rightarrow \mathrm{CH}_{3} \mathrm{CH}=\mathrm{CH}-\mathrm{CH}_{2} \mathrm{OH}\) (q) \(\mathrm{NaBH}_{4}\) (c) Ph-CH=CH-CHO \(\rightarrow\) Ph-CH \(_{2}-\mathrm{CH}_{2}-\mathrm{CHO}\) (r) \(\mathrm{Pd}-\mathrm{C} / \mathrm{H}_{2}\) (d) \(\mathrm{CH}_{2}=\mathrm{CH}-\mathrm{CH}_{2} \mathrm{CHO} \rightarrow \mathrm{CH}_{2}=\mathrm{CH}-\mathrm{CH}_{2} \mathrm{CH}_{2} \mathrm{OH}\) (s) \(\mathrm{Ag}\left(\mathrm{NH}_{3}\right)_{2}^{\oplus}\)

Short answer

(a) s, (b) q, (c) r, (d) p

Step-by-step solution

Identify Possible Reactions for Each Option

Begin by identifying what each reagent typically does. 1. LiAlH₄ is a strong reducing agent capable of reducing carbonyls, carboxylic acids, and esters to alcohols. 2. NaBH₄ is also a reducing agent, but it is generally milder than LiAlH₄, suitable for reducing aldehydes and ketones to alcohols. 3. Pd-C / H₂ is used for hydrogenation, typically reducing double or triple bonds. 4. Ag(NH₃)₂⁺ is Tollens' reagent and is used to oxidize aldehydes to carboxylic acids.

Analyze Reaction (a)

Observe the transformation from CH₃-CH₂=CH-CHO to CH₃CH=CHCOOH. This is likely an oxidation reaction of an aldehyde to a carboxylic acid. The reagent suitable for this reaction is Tollens' reagent, Ag(NH₃)₂⁺.

Analyze Reaction (b)

In this reaction, CH₃-CH=CH-CHO is converted to CH₃CH=CH-CH₂OH. The aldehyde is being reduced to an alcohol. This is a mild reduction, suggesting that NaBH₄ is the appropriate reagent.

Analyze Reaction (c)

Ph-CH=CH-CHO becomes Ph-CH₂-CH₂-CHO. This shows the reduction of the double bond CH=CH to CH₂-CH₂ but retains the aldehyde. Hydrogenation, likely with Pd-C / H₂, suits this transformation.

Analyze Reaction (d)

Here, CH₂=CH-CH₂CHO is transformed into CH₂=CH-CH₂CH₂OH, indicating the conversion of an aldehyde to an alcohol. Given the strong reducing requirements, LiAlH₄ fits this transformation.

Match Each Reaction with Reagents

(a) CH₃-CH₂=CH-CHO → CH₃CH=CHCOOH: Ag(NH₃)₂⁺ (oxidation to carboxylic acid) (b) CH₃-CH=CH-CHO → CH₃CH=CH-CH₂OH: NaBH₄ (mild reduction to alcohol) (c) Ph-CH=CH-CHO → Ph-CH₂-CH₂-CHO: Pd-C / H₂ (hydrogenation of double bond) (d) CH₂=CH-CH₂CHO → CH₂=CH-CH₂CH₂OH: LiAlH₄ (reduction to alcohol)

Key concepts

Reduction Reagents in Organic Chemistry

In organic chemistry, reduction reagents play a crucial role in transforming functional groups by donating electrons. Reduction involves the gain of hydrogen or the loss of oxygen. Typical reduction reagents include lithium aluminium hydride (LiAlH₄) and sodium borohydride (NaBH₄). These reagents are particularly vital for converting carbonyl groups into alcohols.
Reduction is a central theme in synthetic organic chemistry, allowing chemists to selectively reduce specific groups without altering others. This selectivity enables the fine-tuning of molecular structures for desired properties and reactivities.

• LiAlH₄ is a strong reducing agent used for reducing esters, carboxylic acids, and amides to alcohols.
• NaBH₄ is milder, suitable for converting aldehydes and ketones to alcohols.

Overall, a solid understanding of reduction reagents and their applications is essential for mastering complex organic synthesis tasks.

Oxidation Reagents in Organic Chemistry

Oxidation reagents are another corner of organic chemistry that involves the loss of hydrogen or gain of oxygen. This process is the opposite of reduction. Oxidation reagents like Tollens' reagent are essential for converting alcohols, aldehydes, and other groups into more oxidized states.
One common application is the conversion of aldehydes to carboxylic acids, often using reagents like Tollens' reagent, which is known for its specificity and reliability.

• Oxidation is critical in extending the functionality of compounds, enabling further chemical reactions.
• Common oxidation procedures involve not only Tollens' reagent but also other oxidizing agents like KMnO₄ and CrO₃, depending on the desired transformation.

Understanding oxidation and reduction reactions provides a balanced view of organic reaction mechanisms, facilitating advanced chemical synthesis.

Hydrogenation

Hydrogenation is a key process in organic chemistry that involves the addition of hydrogen atoms to unsaturated bonds, such as double or triple bonds. This reaction is often carried out in the presence of a catalyst like palladium on carbon (Pd-C), which facilitates the uptake of hydrogen.
Through hydrogenation, alkenes are converted to alkanes, providing a means to "saturate" molecules. This reaction is widely used in the food industry to harden oils, and in fine chemical synthesis, to stabilize structures by replacing reactive unsaturated bonds with more stable single bonds.

• Hydrogenation helps produce reduced compounds with increased stability.
• Typical catalysts used include Pd-C, platinum, and nickel, each suiting specific substrates and conditions.

Hydrogenation is a versatile technique that finds broad applications beyond chemistry, impacting the production of everyday products.

Tollens' Reagent

Tollens' reagent is a classical reagent in organic chemistry for the detection and oxidation of aldehydes. It contains complexed silver ions in an aqueous ammonia solution, specifically targeting aldehyde groups.
Its main function is the oxidation of aldehydes to carboxylic acids, resulting in the formation of a silver mirror when aldehydes are oxidized. This silver mirror test is a hallmark of Tollens' reagent, serving as a qualitative analytic tool.

• Its use is confined to aldehydes; ketones generally do not react.
• The silver mirror indicates the presence of an aldehyde, providing visual confirmation of the reagent's action.

Tollens' reagent not only emphasizes the chemistry of oxidation but is also indicative of the specificity chemistry can achieve in targeting functional groups.

LiAlH₄

Lithium aluminium hydride (LiAlH₄) is a powerful reducing agent employed in a wide array of organic transformations. Known for its strength, LiAlH₄ is able to reduce esters, carboxylic acids, and even nitriles to alcohols and amines, respectively.
Despite its potency, care must be taken when using LiAlH₄ as it reacts violently with water, requiring anhydrous conditions for safe handling.

• LiAlH₄ provides extensive applications in drastically reducing various functional groups.
• Its reactivity demands careful control, yet its effectiveness in reducing complex structures is renowned.

Its introduction to organic synthesis marked a significant advance, allowing chemists to perform reductions that were previously challenging or impossible.

NaBH₄

Sodium borohydride (NaBH₄) is a reducing agent often favored for its mildness compared to LiAlH₄. NaBH₄ is primarily used to reduce aldehydes and ketones to alcohols, making it a staple in synthesis whenever sensitive or functionalized molecules are involved.
One of the advantages of NaBH₄ is its selectivity and safety, as it can be utilized in aqueous or alcoholic solutions without the explosive risks associated with stronger reducing agents.

• NaBH₄'s role is crucial for selective reduction where precision is needed.
• Its compatibility with mild conditions allows for reductions without adverse reactions with other functional groups.

This reagent is invaluable in both industrial and academic laboratories for its versatility and ease of use.

Pd-C Catalysis

Palladium on carbon (Pd-C) is a prominent catalyst used extensively for hydrogenation reactions. The catalyst facilitates the addition of hydrogen to unsaturated organic compounds, converting double and triple bonds to single bonds.
Pd-C's role extends to a range of transformations, offering chemists the means to control molecular structure via selective saturation of specific unsaturated sites.

• Pd-C often operates under mild conditions, offering high selectivity.
• Its efficiency makes it a tool of choice in various applications, from pharmaceutical synthesis to petrochemical processing.

Pd-C catalysis is a testament to how catalytic technology advances the capability of organic transformations, making reactions more efficient and selective for the production of a wide array of chemical products.