Mixed-ligand complexes of technetium XIII. A new and facile synthesis, structure and electrochemical behaviour of trans-[Tc(dppe)2(butNC)2](PF6)· ethanol (dppe = bis(diphenylphosphino)ethane, butNC= tert-butylisocyanide)

Technetium Complexes with an Isocyano-alkyne Ligand and Its Reaction Products

The attachment of an ethyne substituent in the para position of phenylisocyanide, CNPh^pC≡CH, enables the isocyanide to replace carbonyl ligands in the coordination sphere of common technetium(I) starting materials such as (NBu₄)[Tc₂(μ-Cl)₃(CO)₆]. The ligand exchange proceeds under thermal conditions and finally forms the corresponding hexakis(isocyanide)technetium(I) complex. The product undergoes a copper-catalyzed cycloaddition ("Click" reaction), e.g., with benzyl azide, which gives the [Tc(CNPh^azole)₆]⁺ cation. The free, uncoordinated "Click" product is obtained from a reaction of the corresponding tetrakis(CNPh^azole)copper(I) complex and NaCN. It readily reacts with mer-[Tc(CO)₃(tht)(PPh₃)₂](BF₄) (tht = tetrahydrothiophene) under exchange of the thioether ligand. Alternatively, [Cu(CNPh^azole)₄]⁺ can be used as a transmetalation reagent for the synthesis of the hexakis(isocyanide)technetium(I) complex, which is the preferable approach for the synthesis of the technetium complex with the short-lived nuclear isomer ^99mTc, and a corresponding protocol for [^99mTc(CNPh^azole)₆]⁺ is reported. The ⁹⁹Tc and copper complexes have been studied by single-crystal X-ray diffraction and/or spectroscopic methods including IR and multinuclear NMR spectroscopy.

Mixed-Isocyanide Complexes of Technetium under Steric and Electronic Control

Reactions of the alkyl isocyanide fac-[Tc(CO)₃(CNR)₂Cl] complexes (2) (CNR = CNⁿBu or CN^tBu) with the sterically encumbered isocyanide CNp-FAr^DarF2 [DArF = 3,5-(CF₃)₂C₆H₃] allow a selective exchange of the carbonyl ligands of 2 and the isolation of the mixed-isocyanide complexes mer,trans-[Tc(CNp-FAr^DarF2)₃(CNR)₂Cl] (3). Depending on the steric requirements of the residues R, the remaining chlorido ligand can be replaced by another isocyanide ligand. Cationic complexes such as mer-[Tc(CNp-FAr^DarF2)₃(CNⁿBu)₃]⁺ (4a) or mer,trans-[Tc(CNp-FAr^DarF2)₃(CNⁿBu)₂(CN^tBu)]⁺ (6) have been prepared in this way and isolated as their PF₆^- salts. mer,trans-[Tc(CNp-FAr^DarF2)₃(CNⁿBu)₂(CN^tBu)](PF₆) represents to the best of our knowledge the first transition-metal complex with three different isocyanides in its coordination sphere. Since the degree of the ligand exchange seems to be controlled both by the electronic and steric measures of the incoming isocyanides, we undertook similar reactions with the sterically less demanding p-fluorophenyl isocyanide, CNPh^pF, which indeed readily led to the hexakis(isocyanide)technetium(I) cation through an exchange of all ligands in the staring materials [Tc₂(CO)₆(μ-Cl)₃]^- or fac-[Tc(CO)₃(CNR)₂Cl]. The influence of the substituents at the isocyanide ligands in such reactions has been reasoned with the density functional theory-derived electrostatic potential at the accessible surface of the corresponding isocyanide carbon atoms.

Electrochemical Parametrization in Sandwich Complexes of the First Row Transition Metals

Applying the ligand electrochemical parameter approach to sandwich complexes and standardizing to the Fe(III)/Fe(II) couple, we obtained E(L)(L) values for over 200 pi-ligands. Linear correlations exist between formal potential (E degrees ) and the summation operatorE(L)(L) for each metal couple. In this fashion, we report correlation data for many first row transition metal couples. The correlations between the E(L)(L) of the substituted pi-ligand and the Hammett substituent constants (sigma(p)) are also explored.