Understanding The Oppenauer Oxidation at its Base
Oppenauer oxidation has been one of the most essential questions that come in Chemistry. This topic covers all the bases and the concepts that revolve around the oxidation of a given material on the surface of the earth and how the following materials are affected by the process of oppenauer oxidation. Further, this topic also covers the disadvantage of the process besides explaining the reason behind the same. Today, we take a look at the different aspects of the oppenauer oxidation mechanism and understand the reaction in detail. Following which, we will also understand the various favourable aspects for oxidation.
What is Oppenauer Oxidation?
Oppenauer Oxidation is a chemical conversion process in which, the secondary alcohols that are present in a given composition turn to ketones under a controlled atmosphere with the help of selective oxidation. One of the most useful reactions in modern chemistry, the reaction is named after Rupert Viktor Oppenauer. Further, the oxidation under the oppenauer reaction takes place with sufficient [Al(i-Pro)3], provided there is an excess of acetone.
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Oppenauer oxidation is the process where an aluminium alkoxide has catalysed the oxidation of the secondary alcohol that is present over the corresponding ketone. The oppenauer oxidation is the reverse process of Meerwein Ponndorf Verley reduction. The oppenauer oxidation reaction is one of the most reliable methods that help oxidise allylic alcohols to α, β- unsaturated ketones.
Oppenauer Oxidation Reaction Mechanism
Now that we finally understand the process of oppenauer oxidation reaction, let’s have a look at its reaction mechanism to understand better:
Step 1: In the initial stage of the oxidation reaction mechanism, the alcohol present in the reaction coordinates with the aluminium isopropoxide that is present over the solution, to form a complex.
Step 2: Further, the resultant complex then reacts with the ketone, to result in the creation of a six-membered transition complex.
Step 3: In the following stage of the preparation of the transition complex, the alpha-carbon that is present in the alcohol, converts to the carbonyl carbon, procured from the aluminium-catalyzed hydride shift.
Step 4: Now that the carbonyl carbon is formed, the acetone proceeds over a six-membered transition state.
Step 5: The result is the formation of ketone, created post the process of hydride transfer.
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The oppenauer oxidation reaction is used in the process to oxidise alcohols to carbonyl compounds.
Let’s understand the same with an example. Simple ketone acetone or cyclohexanones is often used as a hydride acceptor that is usually used in the presence of aluminium alkoxide, traditionally given as isopropoxide or t-butoxide.
The oxidation reaction comes as an exact result of the reverse of Meerwein-Ponndorf-Verley reduction. It involves the process of deprotonation of the alcohol by equilibration over the alkoxide, concluded by a hydride transfer. This process of equilibrium is generally achieved by displacing to the right, using a large excess of the hydride acceptor.
Advantages of oppenauer oxidation
The basic advantage of the oppenauer oxidation is that it uses non-toxic reagents and is relatively inexpensive. Since the substrates are generally heated in acetone/benzene mixtures, the reaction conditions are mild and gentle. Another advantage of the oppenauer oxidation that is making it an unique oxidation method as compared to the other oxidation reactions like pyridinium chlorochromate (PCC) and Dess–Martin periodinane is that the secondary alcohols are much likely to get oxidized much quicker than the primary alcohols. That is the reason that chemoselectivity is achieved. Moreover, there is no further oxidation reaction where the aldehyde is getting converted into the carboxylic acid as it happens in many of the oxidation processes like that of John's oxidation.
Disadvantages of Oppenauer Oxidation and its Mechanism
The traditional Oppenauer Oxidation is a highly chemoselective oxidation process. However, the reactions and its mechanism do come with their own set of disadvantages.
To begin with, the reaction method makes use of high temperatures that is generally achieved using large quantities of ketone hydride acceptors. The result is the production of aldol condensation products that are formed with hydride acceptors. While there has been extensive research that is focused around the development of more efficient Oppenauer type Oxidations, we can perform some of these oxidation processes under milder conditions.
Let’s understand the same with an example:
For example, aluminium compounds involved in the oxidation are primary; consequently, prototropic shifts that can easily take place within the product. Thus, while the process of oxidation of cholesterol is being processed, the C=C migrates to give α, β – unsaturated ketones.
FAQs on Oppenauer Oxidation
1. What is the Oppenauer oxidation reaction?
Oppenauer oxidation is a chemical reaction used for the gentle and selective oxidation of secondary alcohols to their corresponding ketones. The reaction is catalysed by an aluminium alkoxide, such as aluminium isopropoxide, in the presence of an excess of a ketone, typically acetone, which acts as the hydride acceptor.
2. What are the key reagents used in Oppenauer oxidation?
The primary reagents required for an Oppenauer oxidation are:
- Substrate: A secondary alcohol that needs to be oxidised.
- Catalyst: An aluminium alkoxide, most commonly aluminium isopropoxide [Al(O-i-Pr)₃] or aluminium t-butoxide.
- Hydride Acceptor: A simple ketone, used in excess, such as acetone or cyclohexanone, to drive the reaction equilibrium forward.
3. How does Oppenauer oxidation differ from Meerwein-Ponndorf-Verley (MPV) reduction?
Oppenauer oxidation and MPV reduction are essentially reverse reactions of each other, governed by the same equilibrium. The primary difference lies in the direction of the reaction:
- Oppenauer Oxidation: Oxidises a secondary alcohol to a ketone using a ketone as an oxidant.
- MPV Reduction: Reduces a ketone to a secondary alcohol using an alcohol as a reductant.
The direction is controlled by the reaction conditions; using an excess of the ketone (e.g., acetone) drives the equilibrium towards oxidation.
4. Why is Oppenauer oxidation considered a highly chemoselective method?
Oppenauer oxidation's chemoselectivity is one of its key advantages. It is because secondary alcohols are oxidised much more readily and quickly than primary alcohols. This allows chemists to selectively convert a secondary alcohol to a ketone in a molecule that also contains a primary alcohol group, without affecting the primary alcohol. This selectivity is not always achieved with other stronger oxidising agents.
5. What are the main disadvantages or limitations of the traditional Oppenauer oxidation?
Despite its utility, the traditional Oppenauer oxidation has several limitations:
- It often requires high reaction temperatures and large quantities of the ketone hydride acceptor.
- These harsh conditions can lead to side reactions, such as aldol condensation of the ketone acceptor.
- In certain substrates, like cholesterol, an unwanted prototropic shift can occur, causing the double bond to migrate to form a more stable α,β-unsaturated ketone.
6. Can Oppenauer oxidation be effectively used to prepare aldehydes from primary alcohols?
No, Oppenauer oxidation is generally considered an unreliable and inefficient method for preparing aldehydes from primary alcohols. The oxidation of primary alcohols is much slower compared to secondary alcohols, and the aldehydes formed can undergo further side reactions under the typical reaction conditions. Other methods, such as using PCC or Dess-Martin periodinane, are preferred for this transformation.
7. What is the mechanism of Oppenauer oxidation?
The mechanism of Oppenauer oxidation proceeds through a coordinated, six-membered transition state. The key steps are:
- The substrate alcohol coordinates with the aluminium isopropoxide catalyst.
- This complex then interacts with the hydride acceptor (acetone), forming a six-membered ring transition state.
- A hydride shift occurs within this state: the hydride from the alcohol's α-carbon is transferred to the carbonyl carbon of the acetone.
- The transition state breaks down, releasing the newly formed ketone product and an aluminium alkoxide of the reduced acetone (isopropanol).
