Polysulfonylamine. LXIX. Neuartige Pniktogendisulfonylamide: Synthese von Bismutdimesylamiden und Kristallstrukturen des zwölfgliedrigen Cyclodimers [Ph2BiN(SO2Me)2]2 und des ionischen Komplexes [H(OAsPh3)2]⊕(MeSO2)2N⊖

Polysulfonyl Amines. LXIX. Novel Pnictogen Disulfonylamides: Synthesis of Bismuth Dimesylamides and Crystal Structures of the Twelve-Membered Cyclodimer [Ph₂BiN(SO₂Me)₂]₂ and of the Ionic Complex [H(OAsPh₃)₂]^⊕(MeSO₂)₂N^? The novel bismuth(III or V) disulfonylamides Ph₂BiN(SO₂Me)₂ ( 1 ), PhBi[N(SO₂Me)₂]₂ ( 2 ), PhBi[N(SO₂Me)₂]Br ( 3 ), Bi[N(SO₂Me)₂]₂Cl ( 4 ), Bi[N(SO₂Me)₂]Cl₂ · 12-crown-4 ( 5 ) and Ph₃Bi[N(SO₂Me)₂]Cl ( 6 ) were obtained by acidolysis of Ph₃Bi with HN(SO₂Me)₂ (→ 1 ), by metathesis of AgN(SO₂Me)₂ with Ph₂BiCl (→ 1 ) or PhBiBr₂ (→ 2, 3 ), by condensation of BiCl₃ with Me₃SiN(SO₂Me)₂ (→ 4 ; in presence of 12-crown-4: → 5 ), or by oxidative addition of ClN(SO₂Me)₂ to Ph₃Bi (→ 6 ). Independently of the molar ratio employed, triphenylarsane oxide and dimesylamine form the crystalline 2/1 complex [H(OAsPh₃)₂]^⊕(MeSO₂)₂N^? ( 7 ). The crystal packing of 7 (monoclinic, space group C2/c) consists of discrete cations displaying crystallographic C_i symmetry and a strong O …? H …? O hydrogen bond (H atom located on a centre of symmetry, O …? O′ 241.2 pm, As? O …? O′ 120°, As? O 168.3 pm), and chiral anions with crystallographic C₂ symmetry (N? S 157.3 pm, S? N? S 122,9°). In the solid state, the bismuth(III) compound 1 (triclinic, space group P1 ) is a cyclodimer with crystallographic C_i symmetry, in which two Ph₂Bi^⊕ cations are connected through two (α-O, ω-O)-donating dimesylamide ligands to form a roughly twelve-membered [BiOSNSO]₂ ring (Bi? O 239.7 and 246.6, O? S 148.0 and 145.4, S? N 157.7 and 159.2 pm, Bi? O? S 126.6 and 127.5°). The bismuth atom adopts a pseudo-trigonal-bipyramidal geometry (O? Bi? O 165.4, C? Bi? C 93.0, O? Bi? C 83.8 to 86.5°). The essentially similar conformations of the discrete anion in 7 and of the bidentate bridging ligand in 1 are discussed in detail.     

High-spin iron(III) complexes: structural,spectroscopic, and photochemical studies

Reaction of FeCl₃ with one equivalent of acac (acac = pentane-2,4-dionate) and KTp^Me2 (Tp^Me2 = hydrotris(3,5-dimethyl-pyrazol-1-yl)borate) yielded Tp^Me2Fe(acac)Cl (3), which upon reaction with methanolic solution of sodium azide resulted in the formation of a six coordinate compound Tp^Me2Fe(acac)N₃ (4) with a single azide. When the reaction of FeCl₃ and KTp^Me2 was performed with two equivalents of sodium azide and one equivalent of 3,5-dimethylpyrazole (Pz^Me2H), a six coordinate cis azide compound [Tp^Me2Fe(Pz^Me2H)(N₃)₂] (5) was obtained. These compounds were characterized by spectroscopic methods and single crystal X-ray crystallography. Electrochemical studies of 5 show that it can be irreversibly reduced at relatively lower potential than 4. The photolysis of 5 was performed at 77 K at different wavelengths (480, 419, and 330 nm) showing that 5 was photoreduced to a high-spin Fe(II) species instead of photooxidized to Fe(V).     

Versatile Reactivity of Scorpionate‐Anchored Yttrium?Dialkyl Complexes towards Unsaturated Substrates

A series of unusual chemical‐bond transformations were observed in the reactions of high active yttrium? dialkyl complexes with unsaturated small molecules. The reaction of scorpionate‐anchored yttrium? dibenzyl complex [Tp^Me2Y(CH₂Ph)₂(thf)] ( 1 , Tp^Me2=tri(3,5‐dimethylpyrazolyl)borate) with phenyl isothiocyanate led to C?S bond cleavage to give a cubane‐type yttrium–sulfur cluster, {Tp^Me2Y(μ₃‐S)}₄ ( 2 ), accompanied by the elimination of PhN?C(CH₂Ph)₂. However, compound 1 reacted with phenyl isocyanate to afford a C(sp³)? H activation product, [Tp^Me2Y(thf){μ‐η¹:η³‐OC(CHPh)NPh}{μ‐η³:η²‐OC(CHPh)NPh}YTp^Me2] ( 3 ). Moreover, compound 1 reacted with phenylacetonitrile at room temperature to produce γ‐deprotonation product [(Tp^Me2)₂Y]⁺[Tp^Me2Y(N=C?CHPh)₃]^? ( 6 ), in which the newly formed N?C?CHPh ligands bound to the metal through the terminal nitrogen atoms. When this reaction was carried out in toluene at 120 °C, it gave a tandem γ‐deprotonation/insertion/partial‐Tp^Me2‐degradation product, [(Tp^Me2Y)₂(μ‐Pz)₂{μ‐η¹:η³‐NC(CH₂Ph)CHPh}] ( 7 , Pz=3,5‐dimethylpyrazolyl).     

P−P Condensation and P−N/P−P Bond Metathesis: Facile Synthesis of Cationic Tri- and Tetraphosphanes

[L_C^RP((PhP)₂C₂H₄)][OTf] ( 4 a,b [OTf]) and [L_C^iPrP(PPh₂)₂][OTf] ( 5 b [OTf]) were prepared from the reaction of imidazoliumyl-substituted dipyrazolylphosphane triflate salts [L_C^RP(pyr)₂][OTf] ( 3 a,b [OTf]; a : R=Me, b =iPr; L_C^R=1,3-dialkyl-4,5-dimethylimidazol-2-yl; pyr=3,5-dimethylpyrazol-1-yl) with the secondary phosphanes PhP(H)C₂H₄P(H)Ph) and Ph₂PH. A stepwise double P−N/P−P bond metathesis to catena-tetraphosphane-2,3-diium triflate salt [(Ph₂P)₂(L_C^MeP)₂][OTf]₂ ( 7 a [OTf]₂) is observed when reacting 3 a [OTf] with diphosphane P₂Ph₄. The coordination ability of 5 b [OTf] was probed with selected coinage metal salts [Cu(CH₃CN)₄]OTf, AgOTf and AuCl(tht) (tht=tetrahydrothiophene). For AuCl(tht), the helical complex [{(Ph₂PPL_C^iPr)Au}₄][OTf]₄ ( 9 [OTf]₄) was unexpectedly formed as a result of a chloride-induced P−P bond cleavage. The weakly coordinating triflate anion enables the formation of the expected copper(I) and silver(I) complexes [( 5 b )M(CH₃CN)₃][OTf]₂ (M=Cu, Ag) ( 10 [OTf]₂, 11 [OTf]₂).     

Subvalente Galliumtriflate – mögliche Ausgangsverbindungen für Clusterverbindungen des Galliums

Subvalent Gallium Triflates – Potentially Useful Starting Materials for Gallium Cluster Compounds By reaction of GaCp* with trifluormethanesulfonic acid in hexane a mixture of gallium trifluormethanesulfonates (triflates, OTf) is obtained. This mixture reacts readily with lithiumsilanides [Li(thf)₃Si(SiMe₃)₂R] (R = Me, SiMe₃) to afford the cluster compounds [Ga₆{Si(SiMe₃)Me}₆], [Ga₂{Si(SiMe₃)₃}₄] and [Ga₁₀{Si(SiMe₃)₃}₆]. By crystallization from various solvents the gallium triflates [Ga(OTf)₃(thf)₃], [HGa(OTf)(thf)₄]⁺ [Ga(OTf)₄(thf)₃]⁻, [Cp*GaGa(OTf)₂]₂ and [Ga(toluene)₂]⁺ [Ga₅(OTf)₆(Cp*)₂]⁻ were isolated and characterized by single crystal X ray structure analysis.     

Synthesis and Structure of Heterometallic Bi(III) Complex with Diethylenetriaminepentaacetic Acid

A new heterometallic Bi(III) complex with diethylenetriaminepentaacetic acid anion (Dtpa)⁵⁻ of the composition [Co(Tsc)₃]₂[Bi(Dtpa)]₂SO⁴ ⋅ 6H₂O (I) (Tsc is thiosemicarbazide) is synthesized and its crystal structure is determined. The complex consists of the [Co(Tsc)₃]³⁺ cations, [Bi(Dtpa)]²⁻ and SO ₄ ²⁻ anions, and crystallization water molecules. The SO ₄ ²⁻ ion and two water molecules are randomly disordered over two positions. In the complex cation [Co(Tsc)₃]³⁺, the metal polyhedron has fac-form. The carboxyl groups of octadentate (Dtpa)⁵⁻ ligand in the [Bi(Dtpa)]²⁻ anion are fully deprotonated. The coordination polyhedron of the Bi atom is a distorted bicapped trigonal prism. Thermogravimetric analysis of complex I indicates that its decomposition occurs through several stages, i.e., dehydration, burning of organic ligands, and the formation of inorganic residue.__________Translated from Koordinatsionnaya Khimiya, Vol. 31, No. 6, 2005, pp. 446–454.Original Russian Text Copyright © 2005 by Bulimestru, Petrenko, Gulea, Gdaniec, Simonov.     

Direct Synthesis of a Dimeric Mixed-Anions Bismuth(III) Complex: Synthesis and Structural Characterization of [Bi2(Phen)4(No3)4.4I0.6]I3 (A New Dimeric Compound)

A direct synthetic method of mixing Bi(NO₃)₃ and NaI with 1,10-phenanthroline yielded red crystals of [Bi₂(phen)₄(NO₃)_4.4I_0.6]I₃. In this complex the cationic part is in fact binuclear and contains two [Bi(phen)(NO₃)_1.7I_0.3] groups linked via a bridging NO^? ₃ anion. The I^? ₃ anion was not coordinated to bismuth(III) and the lone pair of valence electrons of the bismuth(III) ions appears to be stereochemically inactive. There are two independent NO^? ₃ anions, one coordinated to bismuth but another shares a position with I^? anion. The final results of crystallography show that 40% of these positions are occupied by NO^? ₃ anions and 60% by I^? anions that are coordinated to bismuth atom in bidentate fashion (NO^? ₃) and in unidentate fashion (I^?). An interesting point is that the I^? ₃ anion was produced by direct synthetic method (Branched tube method). There is a π-π stacking interaction between the parallel aromatic rings around the Bi(III) ion.     

Cationic tris(pyrazolyl)borate bipyrimidine complexes

The cationic complexes, [Tp^RNi(bpym)]⁺ {Tp^R = tris(3,5-diphenylpyrazolyl)borate, R = Ph₂ 1; tris(3-phenyl-5-methylpyrazolyl)borate, R = Ph,Me 2} were synthesized by reacting [Tp^RNiBr] (R = Ph₂; Ph,Me) with bipyrimidine followed by subsequent addition of KPF₆ in CH₂Cl₂. The green solids have been characterized by IR, UV–Vis and ¹H NMR spectroscopy. Crystallographic studies of [Tp^Ph,MeNi(bpym)]PF₆ reveal a five-coordinate square pyramidal nickel centre with a κ³-coordinated Tp^Ph,Me ligand and a chelating bipyrimidine ligand. Cyclic voltammetric studies show irreversible reduction with the degree of reversibility dependent on the type of Tp^R ligand.     

Bis(di‐2‐pyridylamine‐κ2N2,N2′)silver(I) trifluoromethanesulfonate: polar arrangement of trifluoromethanesulfonate anions in a pseudo‐centrosymmetric framework of coordination cations

The asymmetric unit of the title compound, [Ag(C₁₀H₉N₂)₂]CF₃SO₃ or [Ag(dpa)₂]OTf (dpa is di‐2‐pyridylamine and OTf is the trifluoromethanesulfonate anion), contains two [Ag(dpa)₂]⁺ coordination cations and two OTf anions. The coordination geometry of the Ag^I atom is intermediate between square‐planar and tetrahedral, with similar deformations at the two symmetry‐independent metal centres. The dpa ligands coordinate in a bidentate chelating mode. The OTf anions are in the outer coordination sphere and bridge the coordination cations via N—H...O interactions to form two symmetry‐independent hydrogen‐bonded chains. The [Ag(dpa)₂]⁺ cations are arranged via interactions involving the aromatic groups into a pseudo‐centrosymmetric three‐dimensional framework with two types of channels, each confining congeners of one of the symmetry‐independent anions. The most interesting feature of this structure is its bulk polarity resulting from an approximately parallel alignment of the anions in the channels.     

The Photochemistry of (Diene)(hydro)[tris(3,5-dimethylpyrazolyl)borato]rhodium Complexes,Preliminary Communication

The photochemical rearrangement of [Rh(η⁴-1,5-cod)Tp^Me2](Tp^Me2=hydrotris(3,5-dimethylpyrazolyl)borato, 1,5-cod=cycloocta-1,5-diene) to the new compound [Rh(η⁴-1,3-cod)Tp^Me2] ( 2 ) is described. The characterization of 2 was carried out using ¹H-, ¹³C-, and ¹⁰³Rh-HMQC-NMR spectroscopy. Photolysis of 2 is a versatile entry point into the organometallic chemistry of the {RhTp^Me2} fragment as it can be used to produce a) hydrido-carbonyl ([Rh(CO)H₂Tp^Me2]), b) hydrido-phenyl-phosphite ([RhH(Ph)(P(OMe)₃)Tp^Me2]), and c) ethoxide-hydrido-phosphite ([RhH(OEt)(P(OMe)₃)Tp^Me2]) complexes.     

P−P Condensation and P−N/P−P Bond Metathesis: Facile Synthesis of Cationic Tri‐ and Tetraphosphanes

[L_C^RP((PhP)₂C₂H₄)][OTf] ( 4 a,b [OTf]) and [L_C^iPrP(PPh₂)₂][OTf] ( 5 b [OTf]) were prepared from the reaction of imidazoliumyl‐substituted dipyrazolylphosphane triflate salts [L_C^RP(pyr)₂][OTf] ( 3 a,b [OTf]; a : R=Me, b =iPr; L_C^R=1,3‐dialkyl‐4,5‐dimethylimidazol‐2‐yl; pyr=3,5‐dimethylpyrazol‐1‐yl) with the secondary phosphanes PhP(H)C₂H₄P(H)Ph) and Ph₂PH. A stepwise double P?N/P?P bond metathesis to catena‐tetraphosphane‐2,3‐diium triflate salt [(Ph₂P)₂(L_C^MeP)₂][OTf]₂ ( 7 a [OTf]₂) is observed when reacting 3 a [OTf] with diphosphane P₂Ph₄. The coordination ability of 5 b [OTf] was probed with selected coinage metal salts [Cu(CH₃CN)₄]OTf, AgOTf and AuCl(tht) (tht=tetrahydrothiophene). For AuCl(tht), the helical complex [{(Ph₂PPL_C^iPr)Au}₄][OTf]₄ ( 9 [OTf]₄) was unexpectedly formed as a result of a chloride‐induced P?P bond cleavage. The weakly coordinating triflate anion enables the formation of the expected copper(I) and silver(I) complexes [( 5 b )M(CH₃CN)₃][OTf]₂ (M=Cu, Ag) ( 10 [OTf]₂, 11 [OTf]₂).     

Neutral and Cationic β‐Ketoiminato Bismuth Complexes

The first examples of neutral and cationic bismuth complexes bearing β‐ketoiminato ligands were isolated by employing salt metathesis route. BiCl₃ reacts with [O=C(Me)]CH[C(Me)N(K)Ar] ( 1 ) resulting in a homoleptic β‐ketoiminato bismuth complex Bi[{O=C(Me)}CH{C(Me)NAr}]₃ ( 2 ). The reaction between BiCl₃ and [(CH₂)₂{N(K)C(Me)CHC(Me)=O}₂] ( 3 ) leads to the formation of a cationic bismuth complex [Bi{(CH₂)₂(NC(Me)CHC(Me)=O)₂}]₄[Bi₂Cl₁₀] ( 4 ).     

Catenated Gallium Compounds Supported by a<Emphasis Type="Italic"> Tris</Emphasis>(pyrazolyl)hydroborato Ligand

[ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]M (M = K, Tl) reacts with “GaI” to give a series of compounds that feature Ga–Ga bonds, namely [ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]Ga→GaI₃, [ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]GaGaI₂GaI₂( \textHpz^\textMe₂ {\text{Hpz}}^{{{\text{Me}}_{2} }} ) and [ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]Ga(GaI₂)₂Ga[ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ], in addition to the cationic, mononuclear Ga(III) complex {[ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]₂Ga}⁺. Likewise, [ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]M (M = K, Tl) reacts with (HGaCl₂) ₂ and Ga[GaCl₄] to give [ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]Ga→GaCl₃, {[ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]₂Ga}[GaCl₄], and {[ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]GaGa[ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]}[GaCl₄]₂. The adduct [ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]Ga→B(C₆F₅)₃ may be obtained via treatment of [ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]K with “GaI” followed by addition of B(C₆F₅)₃. Comparison of the deviation from planarity of the GaY₃ ligands in [ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]Ga→GaY₃ (Y = Cl, I) and [ \textTm^{\textBu\textt} {\text{Tm}}^{{{\text{Bu}}^{\text{t}} }} ]Ga→GaY₃, as evaluated by the sum of the Y–Ga–Y bond angles, Σ(Y–Ga–Y), indicates that the [ \textTm^{\textBu\textt} {\text{Tm}}^{{{\text{Bu}}^{\text{t}} }} ]Ga moiety is a marginally better donor than [ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]Ga. In contrast, the displacement from planarity for the B(C₆F₅)₃ ligand of [ \textTp^\textMe₂ {\text{Tp}}^{{{\text{Me}}_{2} }} ]Ga→B(C₆F₅)₃ is greater than that of [ \textTm^{\textBu\textt} {\text{Tm}}^{{{\text{Bu}}^{\text{t}} }} ]Ga→B(C₆F₅)₃, an observation that is interpreted in terms of interligand steric interactions in the former complex compressing the C–B–C bond angles.     

In the footsteps of August Michaelis: Syntheses and Thermodynamics of Extremely Low-Volatile Ionic Liquids

A series of nine different known ionic liquids or low melting salts was synthesised and purified. They are composed of the [NTf₂]^– (bis(trifluoromethane)sulfonimide), [OTf]^– (trifluoro-methane-sulfonate), or [B(CN)₄]^– (tetracyanidoborate) anion and [Ph₄P]⁺ (tetraphenylphosphonium), [Ph₃BzP]⁺ (triphenylbenzyl phosphonium), [ⁿBu₄P]⁺ (tetra-ⁿbutylphosphonium), [ⁿBuPh₃P]⁺ (tri-phenyl-ⁿbutylphosphonium), [ⁿBu₄N]⁺ (tetra-ⁿbutylammonium), or the [PPN]⁺ (bis(triphenylphosphine)iminium) cation. Precise vapour pressure data and enthalpies of vaporisation were measured using the Quartz Crystal Microbalance (QCM) method and evaluated. Structure-property relations are established using the obtained data as well as literature known data of ILs with alkyl-substituted imidazolium cations. It turns out that ILs with the tetracyanidoborate anion have even higher values of the enthalpy of vaporisation than those with the common [NTf₂]⁻ or [OTf]⁻ anion and therefore are even less volatile.     

[Bi4]6– – The Zintl Anion with the Highest Charge per Atom Obtained from Solution

From the dark‐purple solution of the Zintl phase KBi in liquid ammonia dark‐blue crystals of the ammonia solvate K₆[Bi₄](NH₃)₈ were obtained. In contrast to known Bi_n polyanions the chemical bond in the anion [Bi₄]^6– is in accordance with the (8‐N) rule featuring solely Bi–Bi single bonds. [Bi₄]^6– is a butane‐analog valence compound, and with 6 negative charges per 4 atoms it is the anion with the highest known charge per atom obtained from solution. The planarity of the trans‐[Bi₄]^6– unit hints at π orbital contributions of the bismuth atoms. The corresponding reactions of the phases K₅Bi₄ and K₃Bi₂ in liquid ammonia in the presence of [2.2.2]crypt(4, 7, 13, 16, 21, 24‐hexaoxa‐1, 10‐diazabicyclo‐[8.8.8]hexacosane) lead to the salt [K([2.2.2]crypt)]₂[Bi₂](NH₃)₄ with the known electron‐deficient [Bi₂]^2– polyanion and a Bi=Bi double bond.     

Synthesis and Structure of Phosphorus-Containing Complexes [Ph4P]

Complexes [Ph₄P] ₂ ⁺ [Hg₄I₁₀]²⁻ (I) and [[Ph₄P] ₂ ⁺ [BiI₅(Me₂S=O)]²⁻ (II) are synthesized by the reactions of tetraphenylphosphonium Ph₄PI with mercury diiodide in acetone and with bismuth triiodide in dimethyl sulfoxide, respectively. According to X-ray diffraction analysis, structural units of these complexes are tetraphenylphosphonium cations and tetra- and mononuclear anions, respectively. The phosphorus atoms in the tetraphenylphosphonium cations have a distorted tetrahedral coordination. In the central fragment of the centrosymmetric anion [Hg₄I₁₀]²⁻, the distances between the terminal mercury atoms and iodine atoms are 3.503(2) Å. The mercury atoms in the central and terminal fragments of compound I have distorted tetrahedral and trigonal coordinations, respectively. The bismuth atom in the mononuclear octahedral anion of complex II contains a dimethyl sulfoxide molecule along with five iodine atoms in the coordination sphere. __________ Translated from Koordinatsionnaya Khimiya, Vol. 31, No. 10, 2005, pp. 791–795. Original Russian Text Copyright ? 2005 by Sharutin, Egorova, Sharutina, Dorofeeva, Molokov, Fukin.     

Syntheses and structures of lanthanide(III) complexes with some bis(pyrazolyl)borate and tris(pyrazolyl)borate podand ligands

Two new poly(pyrazolyl)borate ligands have been prepared: potassium tris[3-{(4-^tbutyl)-pyrid-2-yl}-pyrazol-1-yl]hydroborate (KTp^BuPy) which has three bidentate arms and is therefore hexadentate; and potassium bis[3-(2-pyridyl)-5-(methoxymethyl)pyrazol-1-yl]-dihydroborate (KBp^(COC)Py) which has two bidentate arms and is therefore tetradentate. The crystal structures of their lanthanide complexes [La(Tp^BuPy)(NO₃)₂] and [La(Bp^(COC)Py)₂X] (X=nitrate or triflate) have been determined. In [La(Tp^BuPy)(NO₃)₂] the metal ion is ten-coordinate, from the hexadentate N-donor podand ligand and two bidentate nitrates. [La(Bp^(COC)Py)₂(NO₃)] is also ten-coordinate, from two tetradentate ligands and a bidentate nitrate, but in [La(Bp^(COC)Py)₂(CF₃SO₃)] the metal ion is nine-coordinate because the triflate anion is monodentate. Two unexpected new complexes which arose from partial decomposition of the poly(pyrazolyl)borate ligands have also been characterised structurally. In [La(^BuPypzH)₃(O₃SCF₃)₃] the metal ion is nine-coordinate from three bidentate pyrazolyl-pyridine arms (liberated by decomposition of KTp^BuPy) and three triflate anions; there is extensive NH· · · O hydrogen-bonding between the pyrazolyl and triflate ligands. [Nd(Tp^Py)(Bp^Py)][Nd(PypzH)(NO₃)₄] was isolated from the reaction of hexadentate tris[3-(2-pyridyl)-pyrazol-1-yl]hydroborate (Tp^Py) with Nd(NO₃)₃. One of the Tp^Py ligands has lost one bidentate pyrazolyl-pyridine ‘arm’ (PypzH) to leave tetradentate tris[3-(2-pyridyl)-pyrazol-1-yl]dihydroborate (Bp^Py). In this structure, the cation [Nd(Tp^Py)(Bp^Py)]⁺ is ten-coordinate from inter-leaved hexadentate and tetradentate ligands, and the anion [Nd(PypzH)(NO₃)₄]⁻ is also ten-coordinate from the bidentate N-donor ligand PypzH and four bidentate nitrates.     

Reactions of bismuth iodide with ammonium,phosphonium, and bismuthonium salts

The reactions of ammonium, phosphonium, and bismuthonium salts with bismuth iodide were used to synthesize a series of complex compounds with bismuth-containing anions: [(HOC₂H₄)₃NH]⁺ ₄[Bi₄I₁₆]^4?, [Ph₃EtP] ₃ ⁺ [Bi₂I₉]^3?, and [Ph₄Bi] ₃ ⁺ [Bi₅I₁₈]^3?. X-ray diffraction data show that the nitrogen atoms in the two types of crystallographically independent cations of the nitrogen-containing complex possess a distorted tetrahedral coordination [the CNC angles are 110.3(9)°–113.2(9)°]. In the tetranuclear centrosymmetric [Bi₄I₁₆]^4? anion, the bismuth atoms have an octahedral coordination: Two types of groups, BiI₂ and BiI₃, are bound with one another by four μ₂-and two μ₃-iodine bridges (the Bi-I-μ₂, Bi-I-μ₃, and Bi-I-μ₁ distances are 3.1296(10), 3.2808(8); 3.3210(8) and 2.8670(8)–2.9108(9) Å, respectively). The coordination of the phosphorus atom in the [Ph₃EtP]⁺ cations of the phosphorus-containing complex is close to tetrahedral (the CPC angles are 107.5°–114.1°). In the binuclear [Bi₂I₉]^3? anions, the bismuth atoms have an octahedral coordination. The axial I-Bi-I angles are 167.52(2)°, 169.84(2)°, and 174.97(2)°. The terminal BiI₃ fragments [Bi²-I^7,8,9 2.9238(7), 2.9236(7), and 2.9522(7) Å] are in the eclipsed conformation.     

Water‐Promoted Generation of a Diazairida Homobarrelene by CC Coupling Between an Iridacyclic Alkylidene and Acetonitrile

The stable cationic iridacyclopentenylidene [Tp^Me2Ir(?CHC(Me)?C(Me)C H₂(NCMe)]PF₆ ( A ; Tp^Me2=hydrotris(3,5‐dimethylpyrazolyl)borate) has been obtained by α‐hydride abstraction from the iridacyclopent‐2‐ene [Tp^Me2Ir(CH₂C(Me)?C(Me)C H₂)(NCMe)]. Complex A exhibits Brønsted–Lowry acidity at the Ir? CH₂ and proximal (relative to Ir? CH₂) methyl sites. The coordination of an extra molecule of acetonitrile to the iridium center initiates the reversible isomerization of the chelating carbon chain of A to the monodentate butadienyl ligand of complex [Tp^Me2Ir(CH?C(Me)C(Me)?CH₂)(NCMe)₂]PF₆, which is capable to engage in a water‐promoted C? C coupling with the MeCN co‐ligands. The product is an aesthetically appealing bicyclic structure that resembles the hydrocarbon barrelene.     

Bismuth Undecahydro‐closo‐dodecaborane: A Retainable Intermediate of B−H Bond Activation by Bismuth(III) Cations

The [B₁₂H₁₂]^2? anion shows an extensive substitutional chemistry based on its three‐dimensional aromaticity. The replacement of functional groups can be attained by electrophilically induced substitution caused by Brønsted or Lewis acidic electrophiles (e.g. Pt²⁺). Until now, it was impossible to structurally characterize a metal‐substituted [B₁₂H₁₂]^2? cage. When an aqueous solution containing both Bi³⁺ cations and [B₁₂H₁₂]^2? anions was heated, the charge‐neutral bismuth undecahydro‐closo‐dodecaborane BiB₁₂H₁₁ was obtained, representing a new class of metalated [B₁₂H₁₂]^2? clusters. The title compound was characterized by single‐crystal X‐ray diffraction and NMR spectroscopic methods. Compared to the typical B?H bond, the short B?Bi single bond (230 pm) exhibits inverted polarity.