Redox-active ligands have evolved from being considered spectroscopic curiosities - creating ambiguity about formal oxidation states in metal complexes - to versatile and useful tools to expand on the reactivity of (transition) metals or to even go beyond what is generally perceived possible. This review focusses on metal complexes containing either catechol, o-aminophenol or o-phenylenediamine type ligands. These ligands have opened up a new area of chemistry for metals across the periodic table. The portfolio of ligand-based reactivity invoked by these redox-active entities will be discussed. This ranges from facilitating oxidative additions upon d(0) metals or cross coupling reactions with cobalt(iii) without metal oxidation state changes - by functioning as an electron reservoir - to intramolecular ligand-to-substrate single-electron transfer to create a reactive substrate-centered radical on a Pd(ii) platform. Although the current state-of-art research primarily consists of stoichiometric and exploratory reactions, several notable reports of catalysis facilitated by the redox-activity of the ligand will also be discussed. In conclusion, redox-active ligands containing catechol, o-aminophenol or o-phenylenediamine moieties show great potential to be exploited as reversible electron reservoirs, donating or accepting electrons to activate substrates and metal centers and to enable new reactivity with both early and late transition as well as main group metals.
Transition-metal-based
molecular complexes are a class of catalyst
materials for electrochemical CO2 reduction to CO that
can be rationally designed to deliver high catalytic performance.
One common mechanistic feature of these electrocatalysts developed
thus far is an electrogenerated reduced metal center associated with
catalytic CO2 reduction. Here we report a heterogenized
zinc–porphyrin complex (zinc(II) 5,10,15,20-tetramesitylporphyrin)
as an electrocatalyst that delivers a turnover frequency as high as
14.4 site–1 s–1 and a Faradaic
efficiency as high as 95% for CO2 electroreduction to CO
at −1.7 V vs the standard hydrogen electrode in an organic/water
mixed electrolyte. While the Zn center is critical to the observed
catalysis, in situ and operando X-ray absorption spectroscopic studies
reveal that it is redox-innocent throughout the potential range. Cyclic
voltammetry indicates that the porphyrin ligand may act as a redox
mediator. Chemical reduction of the zinc–porphyrin complex
further confirms that the reduction is ligand-based and the reduced
species can react with CO2. This represents the first example
of a transition-metal complex for CO2 electroreduction
catalysis with its metal center being redox-innocent under working
conditions.
A persistent challenge in chemistry is to activate abundant, yet inert molecules such as hydrocarbons and atmospheric N
2
. In particular, forming C–N bonds from N
2
typically requires a reactive organic precursor
1
, which limits the ability to design catalytic cycles. Here, we report an diketiminate-supported iron system that is able to sequentially activate benzene and N
2
to form aniline derivatives. The key to this new coupling reaction is the partial silylation of a reduced iron-N
2
complex, which is followed by migratory insertion of a benzene-derived phenyl group to the nitrogen. Further reduction releases the nitrogen products, and the resulting iron species can re-enter the cyclic pathway. Using a mixture of sodium powder, crown ether, and trimethylsilyl bromide, an easily prepared diketiminate iron bromide complex
2
can mediate the one-pot conversion of several petroleum-derived compounds into the corresponding silylated aniline derivatives using N
2
as the nitrogen source. Numerous compounds along the cyclic pathway have been isolated and crystallographically characterized; their reactivity outlines the mechanism including the hydrocarbon activation step and the N
2
functionalization step. This strategy incorporates nitrogen atoms from N
2
directly into abundant hydrocarbons.
A naphthyridine‐derived expanded pincer ligand is described that can host two copper(I) centers. The proton‐responsive ligand can undergo reversible partial and full dearomatization of the naphthyridine core, which enables cooperative activation of H2 giving an unusual butterfly‐shaped Cu4H2 complex.
Coordination of FeCl3 to
the redox-active pyridine–aminophenol
ligand NNOH2 in the presence
of base and under aerobic conditions generates FeCl2(NNOISQ) (1), featuring
high-spin FeIII and an NNOISQ radical ligand. The complex has an overall S = 2 spin state, as deduced from experimental and computational data.
The ligand-centered radical couples antiferromagnetically with the
Fe center. Readily available, well-defined, and air-stable 1 catalyzes the challenging intramolecular direct C(sp3)–H amination of unactivated organic azides to generate a
range of saturated N-heterocycles with the highest turnover number
(TON) (1 mol% of 1, 12 h, TON = 62; 0.1 mol% of 1, 7 days, TON = 620) reported to date. The catalyst is easily
recycled without noticeable loss of catalytic activity. A detailed
kinetic study for C(sp3)–H amination of 1-azido-4-phenylbutane
(S1) revealed zero order in the
azide substrate and first order in both the catalyst and Boc2O. A cationic iron complex, generated from the neutral precatalyst
upon reaction with Boc2O, is proposed as the catalytically
active species.
Cobalt‐porphyrin‐catalysed intramolecular ring‐closing C−H bond amination enables direct synthesis of various N‐heterocycles from aliphatic azides. Pyrrolidines, oxazolidines, imidazolidines, isoindolines and tetrahydroisoquinoline can be obtained in good to excellent yields in a single reaction step with an air‐ and moisture‐stable catalyst. Kinetic studies of the reaction in combination with DFT calculations reveal a metallo‐radical‐type mechanism involving rate‐limiting azide activation to form the key cobalt(III)‐nitrene radical intermediate. A subsequent low barrier intramolecular hydrogen‐atom transfer from a benzylic C−H bond to the nitrene‐radical intermediate followed by a radical rebound step leads to formation of the desired N‐heterocyclic ring products. Kinetic isotope competition experiments are in agreement with a radical‐type C−H bond‐activation step (intramolecular KIE=7), which occurs after the rate‐limiting azide activation step. The use of di‐tert‐butyldicarbonate (Boc2O) significantly enhances the reaction rate by preventing competitive binding of the formed amine product. Under these conditions, the reaction shows clean first‐order kinetics in both the [catalyst] and the [azide substrate], and is zero‐order in [Boc2O]. Modest enantioselectivities (29–46 % ee in the temperature range of 100–80 °C) could be achieved in the ring closure of (4‐azidobutyl)benzene using a new chiral cobalt‐porphyrin catalyst equipped with four (1S)‐(−)‐camphanic‐ester groups.
Coordination of the redox-active tridentate NNO ligand L(H2) to Pd(II) yields the paramagnetic iminobenzosemiquinonato complex 3. Single-electron reduction of 3 yields diamagnetic amidophenolato complex 4, capable of activating aliphatic azide 5. Experimental and computational studies suggest a redox-noninnocent pathway wherein the redox-active ligand facilitates intramolecular ligand-to-substrate single-electron transfer to generate an open-shell singlet "nitrene-substrate radical, ligand radical", enabling subsequent radical-type C-H amination reactivity with Pd(II).
A PONNOP ‘expanded pincer’ ligand is described that can bind two copper(i) atoms in close proximity, but undergoes an unexpected rearrangement in the presence of nickel(ii) salts.
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