Studies towards the Synthesis of a Heterobimetallic Zirconium Germanium Complex from Imidozirconocenes, Germanimines and Germylenes

<p>Early-late transition metal heterobimetallic complexes with direct metal to metal interactions are desirable synthetic targets due to the complementary reactivity of the two different metals present in these compounds. The electron-rich late transition metal (often Rh, Ir, Fe, or Mo), and electron-poor early transition metal create an ideal environment for heterolytic bond cleavage in what is often termed ‘cooperative reactivity’. This project aimed to synthesise a zirconium-germanium heterobimetallic complex based on a known heterobimetallic ligand scaffold; 1. The synthesis of the desired heterobimetallic 1 was attempted using two different synthetic approaches. The first involved the investigating the reactivity between an unsaturated zirconium nitrogen bond (an imidozirconocene) and a germanium(II) source with a lone pair of electrons (known as a germylene). The second approach investigated the reactivity between an unsaturated germanium nitrogen bond (a germanimine) and a zirconium(II) source. In order to have the highest chance of success, a wide range of germanium and zirconium complexes were synthesised. The novel germylenes include [Ge(NAPHTMS)] (NAPHTMS = [1,8-((CH3)3Si)N)2C10H6]) and [Ge(BIANMes)] (BIANMes = [((2,4,6-Me(C6H2)N)2)C12H6)]). These proved to be unreactive towards the imidozirconium species [Cp2Zr(NAr*)(THF)] and [Cp2Zr(NDipp)(THF)] (Ar* = (2,6-(C6H5)2CH)-4-(tBu)C6H2), Dipp = (2,6-((CH3)2CH)C6H3)) as well as other amidozirconocenes. However, within these studies, the mixed coordination germanium species [[Ge(NAPHTMS)Ge(Bu)(NAPHTMS)]-[Li(THF4)]+] and [[Ge(NAPHTMS)Ge(Me)(NAPHTMS)]-[Li(THF4)]+]were synthesised. Density functional theory (DFT) molecular orbital calculations were used to help explain the observed reactivity. With regards to the second approach, routes to new germanimine complexes such as [(HMDS)2Ge(NMes)] ((HMDS) = ((CH3)3Si)2N), Mes = (2,4,6-CH3(C6H3))), were explored, and several methods for generating “Cp2Zr” were examined. Although these conditions proved unsuccessful for generating 1, the reaction between dialkyl zirconocene with azides to form novel zirconocene triazenido complexes was discovered and the sterics affecting the synthesis of new germanimine complexes was investigated.</p>

Studies towards the Synthesis of a Heterobimetallic Zirconium Germanium Complex from Imidozirconocenes, Germanimines and Germylenes

<p>Early-late transition metal heterobimetallic complexes with direct metal to metal interactions are desirable synthetic targets due to the complementary reactivity of the two different metals present in these compounds. The electron-rich late transition metal (often Rh, Ir, Fe, or Mo), and electron-poor early transition metal create an ideal environment for heterolytic bond cleavage in what is often termed ‘cooperative reactivity’. This project aimed to synthesise a zirconium-germanium heterobimetallic complex based on a known heterobimetallic ligand scaffold; 1. The synthesis of the desired heterobimetallic 1 was attempted using two different synthetic approaches. The first involved the investigating the reactivity between an unsaturated zirconium nitrogen bond (an imidozirconocene) and a germanium(II) source with a lone pair of electrons (known as a germylene). The second approach investigated the reactivity between an unsaturated germanium nitrogen bond (a germanimine) and a zirconium(II) source. In order to have the highest chance of success, a wide range of germanium and zirconium complexes were synthesised. The novel germylenes include [Ge(NAPHTMS)] (NAPHTMS = [1,8-((CH3)3Si)N)2C10H6]) and [Ge(BIANMes)] (BIANMes = [((2,4,6-Me(C6H2)N)2)C12H6)]). These proved to be unreactive towards the imidozirconium species [Cp2Zr(NAr*)(THF)] and [Cp2Zr(NDipp)(THF)] (Ar* = (2,6-(C6H5)2CH)-4-(tBu)C6H2), Dipp = (2,6-((CH3)2CH)C6H3)) as well as other amidozirconocenes. However, within these studies, the mixed coordination germanium species [[Ge(NAPHTMS)Ge(Bu)(NAPHTMS)]-[Li(THF4)]+] and [[Ge(NAPHTMS)Ge(Me)(NAPHTMS)]-[Li(THF4)]+]were synthesised. Density functional theory (DFT) molecular orbital calculations were used to help explain the observed reactivity. With regards to the second approach, routes to new germanimine complexes such as [(HMDS)2Ge(NMes)] ((HMDS) = ((CH3)3Si)2N), Mes = (2,4,6-CH3(C6H3))), were explored, and several methods for generating “Cp2Zr” were examined. Although these conditions proved unsuccessful for generating 1, the reaction between dialkyl zirconocene with azides to form novel zirconocene triazenido complexes was discovered and the sterics affecting the synthesis of new germanimine complexes was investigated.</p>

Factors Promoting Alkene Migratory Insertion into Metal-Nitrogen Bond during Hydroamination in Recent Studies

: Migratory insertion is a fundamental organometallic transformation that enables the functionalization of an unsaturated bond. Recent reports on catalytic hydroamination provide evidence that supports an intermolecular migratory insertion pathway featuring alkene insertion into metal-nitrogen (M-N) bonds. This article presents factors influencing the rate of migratory insertion in late-transition metal-catalyzed hydroamination, including steric and electronic effects from ligands, alkenes, and metal centers, along with stabilization from coordinated amine intermediates and ordered transition states.

Carbon-Nitrogen bond formation on Cu electrodes during CO2 reduction in NO3- solution

In performing electrochemical reduction of CO2 over Cu electrodes, the anions present in solution typically do not participate in the formation of reaction products. NO3- is an exception, and previous reports indicate the formation of urea in certain process conditions. Here we demonstrate by use of Surface Enhanced Raman Spectroscopy and Electrochemical Mass spectrometry that simultaneous reduction of NO3- and CO2 on Cu surfaces forms carbon-nitrogen bonds in the form of cyanide. The Raman peak position of C≡N is dependent on the oxidation state of the Cu surface, and Cu-C≡N can be oxidized by anodic polarization yielding NO. More importantly, Cyanide likely forms soluble Cu-C≡N complexes, which cause catalyst surface instability. The implications of this observation for practical application of a process for electrochemical formation of urea, are discussed.

COMPOSITION FOR PROTECTING TECHNOLOGICAL EQUIPMENT AGAINST SALT DEPOSITS AND INTERNAL CORROSION

Aimed studies on the synthesis of metal complexonates have carried out. The reaction of obtaining zincate zincate oxyethylene diphosphonic acid OEDP has studied. On the basis of synthesized zincate-OEDP, compositions of corrosion inhibitors and deposits of mineral salts with the addition of a vacuum residue of monoethanolamine (RMEA) and polyaminocrotanol (PKI-3), which are able to effectively suppress corrosion processes in environments with different initial corrosive activity, have been compiled. It is proved that the high efficiency of the composition OEDP : zincate-OEDP : PKI-3 (maximum protective effect - 97.9%) is much more effective than the composition OEDP : zincate-OEDP : RMEA (maximum protective effect - 92.0%). This is due to an increase in ammonium centers, the strength of complexonates based on OEDP, and the presence of a strong methyl-nitrogen bond in the compositions prepared with PKI-3, as a result of which stronger protective layers are formed on the surface of the metal subject to corrosion. Low-stage, energy-saving technologies for the production of inhibitors of mineral salt deposition and corrosion based on local raw materials and secondary industrial products have developed.