In recent years the interest of shape-persistent organic cage compounds synthesized by dynamic covalent chemistry (DCC) has risen, because these cages are potentially interesting for gas sorption or -separation. One such reaction in DCC is the condensation of boronic acids with diols to form boronic esters. Most interestingly, the variety of geometries and sizes for boronic ester cages is much lower than that of, for example, imine-based cages. Here, a small series of shape-persistent [4+6] tetrahedral boronic ester cages is introduced. One cage has a high specific surface area of 511 m g and selectively adsorbs ethane over ethylene and acetylene.
Iron
complexes supported by novel π-acidic bis(imino)pyrazine (PPzDI) ligands can be functionalized at the nonligated nitrogen
atom, and this has a marked effect on the redox properties of the
resulting complexes. Dearomatization is observed in the presence of
cobaltocene, which reversibly reduces the pyrazine core and not the
imine functionality, as observed in the case of the pyridinediimine-ligated
iron analogues. The resulting ligand-based radical is prone to dimerization
through the formation of a long carbon–carbon bond, which can
be subsequently cleaved under mild oxidative conditions.
A detailed investigation
of the electronic structure of diazinediimine
iron complexes and their comparison with the pyridine analogues reveals
subtle but important differences, imparted by the supporting heterocycle.
In the case of LFe(CO)2 complexes (L = pyrazine- and pyrimidinediimine),
the characterization of three available redox states confirmed that
whereas the nature of the electron-transfer processes is similar,
the differences in π-acidity of the supporting heterocycle significantly
affect the redox potentials. The reduction of LFe(CO)2 can
yield either a ligand-centered radical (for L = pyrimidine) or a C–C-bonded
dimer (for L = pyrazine), supported by a dearomatized core. In the
latter case, the C–C bond can be reversibly cleaved oxidatively.
Compared to the carbonyl analogues, employing weak-field N2 ligands triggers changes in electronic structure for the neutral
and reduced LFe(N2) complexes (L = pyrimidinediimine).
En route to the synthesis of the nitrogen complexes, the square-planar
LFeCl (L = pyrimidinediimine) was isolated. The monoradical
character of the supporting chelate triggers the asymmetric distribution
of electron density around the heterocycle.
An ew redox-active N-heterocyclic carbene (NHC) architecture is obtained using N-methylated pyrazinediimine iron complexes as precursors.The new species exhibit strong paccepting/s-donating properties and are able to ligate two metal centres simultaneously.T he redox activity was demonstrated by the reversible chemicalo xidation of ah eterobimetallic Fe 0 /Rh I example,w hich affords an isolable ligand-based radical cation. The reversible redox process was then applied in the catalytic hydrosilylation of 4,4'-difluorobenzophenone, where the reaction rate could be reversibly controlled as af unction of the catalyst oxidation state.T he new NHC exhibits high electrophilicity and nucleophilicity,w hich was demonstrated in the reversible activation of alcohols and amines.The electronic structure of the resulting complexes was investigated through various spectroscopic and computational methods.
Metal–ligand cooperativity
and redox-active ligands enable
the use of open-shell first-row transition metals in catalysis. However,
the fleeting nature of the reactive intermediates prevents direct
inspection of the relevant catalytic species. By employing phosphine
α-iminopyridine (PNN)-based complexes, we show that chemical
and redox metal–ligand cooperativity can be combined in the
coordination sphere of iron dinitrogen complexes. These systems show
dual activation modes either through deprotonation, which triggers
reversible core dearomatization, or through reversibly accepting one
electron by reducing the imine functionality. (PNN)Fe(N2) fragments can be obtained under mildly reducing conditions. Deprotonation
of such complexes induces dearomatization of the pyridine core while
retaining a terminally coordinated N2 ligand. This species
is nevertheless stable in solution only below −30 °C and
undergoes unusual ligand-assisted redox disproportionation through
proton-coupled electron transfer at room temperature. The origin of
this phenomenon is the significant lability of the α-imine C–H
bonds in the dearomatized species, where the calculated bond dissociation
free energy is 48.7 kcal mol–1. The dispropotionation
reaction yields an overreduced iron compound, demonstrating that the
formation of such species can be triggered by mild bases, and does
not require harsh reducing agents. Reaction of the dearomatized species
with dihydrogen yields a rare anionic Fe hydride that binds dinitrogen
and features a rearomatized core.
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