Frustrated Lewis pair

A frustrated Lewis pair (FLP) is a compound or mixture containing a Lewis acid and a Lewis base that, because of steric hindrance, cannot combine to form a classical adduct. Many kinds of FLPs have been devised, and many simple substrates exhibit activation.

The discovery that some FLPs split H₂ triggered a rapid growth of research into FLPs. Because of their "unquenched" reactivity, such systems are reactive toward substrates that can undergo heterolysis. For example, many FLPs split hydrogen molecules. Thus, a mixture of tricyclohexylphosphine (PCy₃) and tris(pentafluorophenyl)borane reacts with hydrogen to give the respective phosphonium and borate ions:

This reactivity has been exploited to produce FLPs which catalyse hydrogenation reactions.

Frustrated Lewis pairs have been shown to activate many small molecules, either by inducing heterolysis or by coordination.

The discovery that some FLPs are able to split, and therefore activate, H₂ triggered a rapid growth of research into this area. The activation and therefore use of H₂ is important for many chemical and biological transformations. Using FLPs to liberate H₂ is metal-free, this is beneficial due to the cost and limited supply of some transition metals commonly used to activate H₂ (Ni, Pd, Pt). FLP systems are reactive toward substrates that can undergo heterolysis (e.g. hydrogen) due to the "unquenched" reactivity of such systems. For example, it has been previously shown that a mixture of tricyclohexylphosphine (PCy₃) and tris(pentafluorophenyl)borane reacts with H₂ to give the respective phosphonium and borate ions:

In this reaction, PCy₃ (the Lewis base) and B(C₆F₅)₃ (the Lewis acid) cannot form an adduct due to the steric hindrance from the bulky cyclohexyl and pentafluorophenyl groups. The proton on the phosphorus and hydride from the borate are now 'activated' and can subsequently be 'delivered' to an organic substrate, resulting in hydrogenation.

The mechanism for the activation of H₂ by FLPs has been discussed for both the intermolecular and intramolecular cases. Intermolecular FLPs are where the Lewis base is a separate molecule to the Lewis acid, it is thought that these individual molecules interact through secondary London dispersion interactions to bring the Lewis base and acid together (a pre-organisational effect) where small molecules may then interact with the FLPs. The experimental evidence for this type of interaction at the molecular level is unclear. However, there is supporting evidence for this type of interaction based on computational density functional theory studies. Intramolecular FLPs are where the Lewis acid and Lewis base are combined in one molecule by a covalent linker. Despite the improved 'pre-organisational effects', rigid intramolecular FLP frameworks are thought to have a reduced reactivity to small molecules due to a reduction in flexibility.

FLPs are also reactive toward many unsaturated substrates beyond H₂. Some FLPs react with CO₂, specifically in the deoxygenative reduction of CO₂ to methane.