The Coordination Chemistry of “[BP_3]NiX” Platforms: Targeting Low-Valent Nickel Sources as Promising Candidates to L_3Ni=E and L_3Ni≡E Linkages

A series of divalent, monovalent, and zerovalent nickel complexes supported by the electron-releasing, monoanionic tris(phosphino)borate ligands [PhBP_3] and [PhBP^(iPr)_3] ([PhBP_3] = [PhB(CH_2PPh_2)_3]-, [PhBP^(iPr)_3] = [PhB(CH_2PiPr_2)_3]-) have been synthesized to explore fundamental aspects of their coordination chemistry. The pseudotetrahedral, divalent halide complexes [PhBP_3]NiCl (1), [PhBP_3]NiI (2), and [PhBP^(iPr)_3]NiCl (3) were prepared by the metalation of [PhBP_3]Tl or [PhBP^(iPr)_3]Tl with (Ph_3P)_2NiCl_2, NiI_2, and (DME)NiCl_2 (DME = 1,2-dimethoxyethane), respectively. Complex 1 is a versatile precursor to a series of complexes accessible via substitution reactions including [PhBP_3]Ni(N_3) (4), [PhBP_3]Ni(OSiPh_3) (5), [PhBP_3]Ni(O-p-tBu-Ph) (6), and [PhBP_3]Ni(S-p-tBu-Ph) (7). Complexes 2−5 and 7 have been characterized by X-ray diffraction (XRD) and are pseudotetrahedral monomers in the solid state. Complex 1 reacts readily with oxygen to form the four-electron-oxidation product, {[PhB(CH_2P(O)Ph_2)_2(CH_2PPh_2)]NiCl} (8A or 8B), which features a solid-state structure that is dependent on its method of crystallization. Chemical reduction of 1 using Na/Hg or other potential 1-electron reductants generates a product that arises from partial ligand degradation, [PhBP_3]Ni(η^2-CH_2PPh_2) (9). The more sterically hindered chloride 3 reacts with Li(dbabh) (Hdbabh = 2,3:5,6-dibenzo-7-azabicyclo[2.2.1]hepta-2,5-diene) to provide the three-coordinate complex [κ^2-PhBP^(iPr)_3]Ni(dbabh) (11), also characterized by XRD. Chemical reduction of complex 1 in the presence of L-type donors produces the tetrahedral Ni(I) complexes [PhBP_3]Ni(PPh_3) (12) and [PhBP3]Ni(CNtBu) (13). Reduction of 3 following the addition of PMe_3 or tert-butyl isocyanide affords the Ni(I) complexes [PhBP^(iPr)_3]Ni(PMe_3) (14) and [PhBP^(iPr)_3]Ni(CN^tBu) (15), respectively. The reactivity of these [PhBP_3]Ni^IL and [PhBP^(iPr)_3]NiI^L complexes with respect to oxidative group transfer reactions from organic azides and diazoalkanes is discussed. The zerovalent nitrosyl complex [PhBP_3]Ni(NO) (16) is prepared by the reaction of 1 with excess NO or by treating 12 with stoichiometric NO. The anionic Ni(0) complexes [[κ^2-PhBP_3]Ni(CO)_2][^nBu_4N] (17) and [[κ^2-PhBP^(iPr)_3]Ni(CO)_2][ASN] (18) (ASN = 5-azoniaspiro[4.4]nonane) have been prepared by reacting [PhBP_3]Tl or [PhBP^(iPr)_3]Tl with (Ph_3P)_2Ni(CO)_2 in the presence of R_4NBr. The photolysis of 17 appears to generate a new species consistent with a zerovalent monocarbonyl complex which we tentatively assign as {[PhBP_3]Ni(CO)}{^nBu_4N}, although complete characterization of this complex has been difficult. Finally, theoretical DFT calculations are presented for the hypothetical low spin complexes [PhBP_3]Ni(N^tBu), [PhBP^(iPr)_3]Ni(N^tBu), [PhBP^(iPr)_3]Ni(NMe), and [PhBP^(iPr)_3]Ni(N) to consider what role electronic structure factors might play with respect to the relative stability of these species

Synthesis and characterization of cationic iron complexes supported by the neutral ligands NP^(i-Pr)_3, NArP^(i-Pr)_3, and NS^(t-Bu)_3^1

This paper compares the local geometries, spin states, and redox properties of a series of iron complexes supported by neutral, tetradentate NP_3 (tris(phosphine)amine) and NS_3 (tris(thioether)amine) ligands. Our consideration of an Fe-mediated N_2 fixation scheme similar to that proposed by Chatt for molybdenum motivates our interest in systems of these types. This report specifically describes the synthesis and characterization of cationic Fe(II) chloride complexes supported by the neutral ligands NP^(i-Pr)_3 (NP^(i-Pr)_3 = [N(CH_2CH_2P-i-Pr_2_)3]), NArP^(i-Pr)_3 (NArP^(i-Pr)_3 = [N(2-diisopropylphosphine-4-methylphenyl)_3]), and NS^(t-Bu)_3 (NS^(t-Bu)_3 = [N(CH_2CH_2S-t-Bu)_3]). The solid-state structures, electrochemistry,and magnetic properties of these complexes are reported. Whereas the NPV(i-Pr)_3 and NArP^(i-Pr)_3 ligands provide pseudotetrahedral S = 2 ferrous cations [Fe(NP^(i-Pr)_3)Cl]PF_6 (1[PF_6]) and [Fe(NArP^(i-Pr)_3)Cl]BPh_4 (2[BPh_4]) featuring a long Fe—N bond distance, the NS^(t-Bu)_3 ligand gives rise to a trigonal bipyramidal structure with a S = 1 ground state and a much shorter Fe–N interaction. The complexes 1[BPh_4] and 2[BPh_4] can be reduced under CO to give rise to the five-coordinate Fe(I) monocarbonyls [Fe(NP^(i-Pr)_3)CO]BPh_4 (4[BPh_4]) and [Fe(NAr^(Pi-Pr)_3)CO]BPh_4 (5[BPh_4]). The solidstate structures and electrochemistry of 4[BPh_4] and 5[BPh_4] are described, as is the EPR spectrum of 4[BPh_4]. The synthesis and characterization of the hydride–dinitrogen complex [Fe(NP^(i-Pr)_3)(N_2)(H)]PF_6 (6[PF_6]) has also been accomplished and its properties are also reported

Synthesis and reactivity of nickel complexes supported by the tris(phosphino) borate ligand [PhB(Ch_2PPh_2)_3]^-

The chemistry of nickel complexes supported by phosphine donor ligands has gained recent interest due to the ability of these species to catalyze a variety of chemical transformations. A series of divalent, monovalent, and zerovalent nickel complexes supported by the strongly electron-releasing, monoanionic tris(phosphino) borate ligand, [PhBP_3]=[PhB(CH_2PPh 2)_3]^-, have been synthesized to explore their coordination chemistry and reactivity. The characterization of these complexes will be presented, with comparisons drawn to isostructural nickel complexes supported by neutral phosphine ligands

N-tert-Butyl-2-methylpropanamide

The title compound, C8H17NO, crystallizes with two independent molecules in the asymmetric unit. In the crystal, intermolecular N—H...O hydrogen bonding is observed between neighboring molecules, forming continuous molecular chains along the c-axis direction

N-tert-Butyl-2-methyl­propanamide. Corrigendum

Corrigendum to Acta Cryst. (2011), E67, o2143

The Mechanism of Rhodium-Catalyzed Allylic C-H Amination

Herein, the mechanism of catalytic allylic C-H amination reactions promoted by Cp*Rh complexes is reported. Reaction kinetics experiments, stoichiometric studies, and DFT calculations demonstrate that the allylic C-H activation to generate a Cp*Rh(π-allyl) complex is viable under mild reaction conditions. The role of external oxidants in the catalytic cycle is elucidated. Quantum mechanical calculations, stoichiometric reactions, and cyclic voltammetry experiments concomitantly support an oxidatively induced reductive elimination process of the allyl fragment with an acetate ligand proceeding through a Rh(IV) intermediate. Stoichiometric oxidation and bulk electrolysis of the proposed π-allyl intermediate are also reported to support these analyses. Lastly, evidence supporting the amination of an allylic acetate intermediate is presented. We show that Cp*Rh(III)2+ behaves as a Lewis acid catalyst to complete the allylic amination reaction. © 2020 American Chemical Societ

Lanthanide(III) Di- and Tetra-Nuclear Complexes Supported by a Chelating Tripodal Tris(Amidate) Ligand

Syntheses, structural, and spectroscopic characterization of multinuclear tris­(amidate) lanthanide complexes is described. Addition of K₃[N­(<i>o</i>-PhNC­(O)<i>^t</i>Bu)₃] to LnX₃ (LnX₃ = LaBr₃, CeI₃, and NdCl₃) in <i>N</i>,<i>N</i>-dimethylformamide (DMF) results in the generation of dinuclear complexes, [Ln­(N­(<i>o</i>-PhNC­(O)^<i>t</i>Bu)₃)­(DMF)]₂­(μ-DMF) (Ln = La (<b>1</b>), Ce (<b>2</b>), Nd­(<b>3</b>)), in good yields. Syntheses of tetranuclear complexes, [Ln­(N­(<i>o</i>-PhNC­(O)^<i>t</i>Bu)₃)]₄ (Ln = Ce (<b>4</b>), Nd­(<b>5</b>)), resulted from protonolysis of Ln­[N­(SiMe₃)₂]₃ (Ln = Ce, Nd) with N­(<i>o</i>-PhNCH­(O)^<i>t</i>Bu)₃. In the solid-state, complexes <b>1</b>–<b>5</b> exhibit coordination modes of the tripodal tris­(amidate) ligand that are unique to the 4f elements and have not been previously observed in transition metal systems