Designing multi-step organic synthesis pathways requires a systematic approach. You must integrate your knowledge of all organic reaction mechanisms, reagents, and conditions to map out the conversion of a starting material into a desired target molecule.
🔑 Key Principle
The core of designing synthesis routes lies in identifying the functional group changes needed and choosing selective reagents that avoid undesired side-reactions, all while maintaining the maximum possible atom economy and yield.
Retrosynthetic Analysis
Retrosynthetic analysis is the standard method for designing synthetic pathways. Instead of trying to build the target molecule forward from the starting material, you work backward: beginning with the target molecule and breaking it down step-by-step into simpler precursors (synthons or intermediates) until you reach readily available starting materials.
A method of planning a chemical synthesis by working backwards from the target molecule to simpler precursor structures.
The desired end product of a multi-step organic synthesis.
A stable compound formed during one step of a multi-step reaction that is then used as a reactant in the subsequent step.
A crucial first step in any synthesis question is to count the number of carbon atoms in both the starting material and the target molecule. If the carbon chain increases in length, you must incorporate a carbon-carbon bond forming step. At A-Level, this typically means using KCN in ethanol to convert a halogenoalkane to a nitrile, or using HCN in nucleophilic addition with an aldehyde or ketone.
The Organic Synthesis Roadmap
The diagram below shows the major functional group interconversions required for the AQA specification, linking both aliphatic and aromatic chemistry pathways.
When stating the reagents for the conversion of nitrobenzene to phenylamine, you must mention both the metals and the acids: write Sn and concentrated HCl, followed by neutralisation with NaOH. Do not write "reduction" or "[H]" as the reagent, as you will lose marks.
Worked Examples of Synthesis Design
Step 1: Convert propene (alkene) to propan-2-ol (secondary alcohol)
- Reagents and Conditions: Steam (\(\text{H}_2\text{O(g)}\)), concentrated phosphoric acid (\(\text{H}_3\text{PO}_4\)) catalyst, high temperature (300 °C) and pressure (60 atm).
- Intermediate: Propan-2-ol, \(\text{CH}_3\text{CH(OH)CH}_3\) (formed as the major product via electrophilic addition according to Markovnikov's rule).
Step 2: Convert propan-2-ol to propanone (ketone)
- Reagents and Conditions: Acidified potassium dichromate(VI) (\(\text{K}_2\text{Cr}_2\text{O}_7 / \text{H}_2\text{SO}_4\)), heat under reflux.
Equations:
1. \(\text{CH}_3\text{CH=CH}_2 + \text{H}_2\text{O} \xrightarrow{\text{H}_3\text{PO}_4} \text{CH}_3\text{CH(OH)CH}_3\)
2. \(\text{CH}_3\text{CH(OH)CH}_3 + [\text{O}] \rightarrow \text{CH}_3\text{COCH}_3 + \text{H}_2\text{O}\)
Analysis: Bromoethane has 2 carbons. Propanoic acid has 3 carbons. The carbon chain must increase by 1.
Step 1: Convert bromoethane to propanenitrile
- Reagent and Conditions: Potassium cyanide (\(\text{KCN}\)) in ethanol/water solvent, heat under reflux.
- Intermediate: Propanenitrile, \(\text{CH}_3\text{CH}_2\text{CN}\).
Step 2: Convert propanenitrile to propanoic acid
- Reagent and Conditions: Dilute hydrochloric acid (\(\text{HCl(aq)}\)), heat under reflux (acidic hydrolysis).
Equations:
1. \(\text{CH}_3\text{CH}_2\text{Br} + \text{CN}^- \rightarrow \text{CH}_3\text{CH}_2\text{CN} + \text{Br}^-\)
2. \(\text{CH}_3\text{CH}_2\text{CN} + \text{HCl} + 2\text{H}_2\text{O} \rightarrow \text{CH}_3\text{CH}_2\text{COOH} + \text{NH}_4\text{Cl}\)
Step 1: Nitration of Benzene to Nitrobenzene
- Reagents and Conditions: Concentrated nitric acid (\(\text{HNO}_3\)) and concentrated sulfuric acid (\(\text{H}_2\text{SO}_4\)) catalyst, heat at 50 to 55 °C.
- Intermediate 1: Nitrobenzene, \(\text{C}_6\text{H}_5\text{NO}_2\).
Step 2: Reduction of Nitrobenzene to Phenylamine
- Reagents and Conditions: Tin (\(\text{Sn}\)) and concentrated hydrochloric acid (\(\text{HCl}\)), heat under reflux, followed by the addition of sodium hydroxide (\(\text{NaOH}\)) solution to liberate the amine.
- Intermediate 2: Phenylamine, \(\text{C}_6\text{H}_5\text{NH}_2\).
Step 3: Acylation of Phenylamine to N-phenylethanamide
- Reagent and Conditions: Ethanoyl chloride (\(\text{CH}_3\text{COCl}\)), room temperature.
Equations:
1. \(\text{C}_6\text{H}_6 + \text{HNO}_3 \xrightarrow{\text{H}_2\text{SO}_4} \text{C}_6\text{H}_5\text{NO}_2 + \text{H}_2\text{O}\)
2. \(\text{C}_6\text{H}_5\text{NO}_2 + 6[\text{H}] \rightarrow \text{C}_6\text{H}_5\text{NH}_2 + 2\text{H}_2\text{O}\)
3. \(\text{C}_6\text{H}_5\text{NH}_2 + \text{CH}_3\text{COCl} \rightarrow \text{C}_6\text{H}_5\text{NHCOCH}_3 + \text{HCl}\)
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