Diskoneksi 1 gugus CX | Kimia organik sintesis

Chemster Lab

12 Jun 202413:28

Summary

TLDRThis video from ChamsterLab covers the technique of CX disconnection in organic synthesis, focusing on the cleavage of bonds between carbon and heteroatoms like oxygen, nitrogen, and sulfur. It explores how to identify nucleophiles and electrophiles in various molecular structures, emphasizing the use of reagents like organometallics and acyl chlorides for creating reactive intermediates. The video also demonstrates retrosynthetic analysis with examples, such as synthesizing herbicides and perfumes, and discusses the principles of acidity and reactivity. The viewer is encouraged to practice disconnections and reaction mechanisms through exercises.

Takeaways

🔬 Diskonection is a technique in synthesis involving breaking a bond between a carbon and a heteroatom like nitrogen, sulfur, or oxygen.
🧪 The process involves identifying which part of the molecule acts as the nucleophile and which as the electrophile.
📉 Carbanions can be generated using reagents like organolithium or Grignard reagents, making carbon nucleophilic.
⚛️ Carbonyl compounds like alcohols and acyl chlorides are common targets for disconnection, yielding nucleophiles and electrophiles.
🧠 In retrosynthesis, disconnecting between C and O or C and N helps in identifying simpler starting materials like alcohols or amines.
🌿 The example of propanil synthesis (a herbicide) demonstrates disconnection between C and N, yielding an amine and an acyl chloride.
🚫 Route B was chosen in a case study due to the higher acidity of phenol, making it more reactive compared to bromobenzene.
🔗 Thiol (HS) compounds are more acidic than alcohols, facilitating easier reactions involving sulfur-containing molecules.
🔄 The synthesis of sulfides involves disconnection at the sulfur atom, leading to starting materials like halides and thiol compounds.
🧬 Retrosynthetic analysis is emphasized as a critical technique in organic chemistry to simplify complex molecules into their starting materials.

Q & A

What is the primary focus of this video?
-The video focuses on the concept of disconnection in organic synthesis, specifically targeting CX bonds, where C represents carbon and X represents heteroatoms like oxygen, nitrogen, or sulfur.
What is meant by a CX bond in the context of this video?
-A CX bond refers to a bond between carbon and a heteroatom such as oxygen, nitrogen, or sulfur. This bond is often targeted in synthetic disconnection strategies.
Why is disconnection between C and X bonds important in organic synthesis?
-Disconnection between C and X bonds is important because it allows chemists to break down complex molecules into simpler starting materials. This approach is used to identify nucleophiles and electrophiles for synthesis.
What is the difference between a nucleophile and an electrophile in the context of the video?
-A nucleophile is a negatively charged or electron-rich species that donates electrons, while an electrophile is a positively charged or electron-poor species that accepts electrons. In CX bond disconnections, the heteroatom (X) typically acts as a nucleophile, while the carbon (C) acts as an electrophile.
How can the roles of nucleophile and electrophile be reversed in a disconnection strategy?
-The roles of nucleophile and electrophile can be reversed by using reagents such as organometallic compounds. For example, R-lithium or Grignard reagents can turn the carbon into a nucleophile (R-) and the heteroatom into an electrophile.
What types of compounds are commonly involved in disconnections at CX bonds?
-Common compounds involved in CX bond disconnections include alcohols, amines, thiols, alkyl halides, acyl chlorides, and carbanions derived from organometallic reagents.
How does disconnection work for carbonyl-containing compounds?
-For carbonyl-containing compounds, disconnection typically occurs between the carbonyl carbon and the heteroatom. This strategy breaks down carbonyl compounds, like esters or amides, into their corresponding alcohols and acyl halides.
Why is acyl chloride frequently used in organic synthesis?
-Acyl chloride is frequently used in organic synthesis because it is highly reactive and serves as a strong electrophile. It can easily react with nucleophiles to form esters, amides, or anhydrides.
What is the significance of choosing between two synthetic routes, as discussed in the video?
-Choosing between two synthetic routes depends on factors like the strength of nucleophiles and electrophiles, and potential side reactions. The more favorable route minimizes side reactions and maximizes the yield of the desired product.
How is phenol's acidity relevant to the synthetic strategy discussed?
-Phenol's acidity is important because it determines the ease with which it can lose a proton, forming the phenoxide ion, a stronger nucleophile. This property is relevant in disconnections where phenoxide attacks electrophiles like allyl bromide.