Mononuclear polyunsaturated organosilicon dendrimers simultaneously containing (CH=CH) and (C≡C) fragments

Mononuclear organosilicon tri- and tetradendrons of the zero, first, and second generations, containing double bonds in the internal near-core molecular sphere, internal C≡C groups, and terminal Me, CH=CHSiMe₃, and C≡CH substituents at the central silicon atom were synthesized. Their IR and ¹H, ¹³C, ²⁹Si NMR spectra were studied. The molecular weights of the dendrimers obtained were evaluated, and key parameters of these compounds are presented.     

Zwitterionic copper(I) π-complexes with monosubstituted alkynes. Synthesis and X-ray diffraction study of a π-complex of copper(I) chloride with 4-ethynyl-4-hydroxy-2,2,6,6-tetramethylpiperidinium chloride

The first mononuclear π-complex of copper(I) chloride with monosubstituted alkyne of the formula [(C₉H₁₆NH₂(OH)C≡CH)CuCl₂] was obtained in the system CuCl-HCl-H₂O-(C₉H₁₆NH₂(OH)C≡CH)Cl (C₉H₁₆NH ₂ ⁺ (OH)C≡CH is the 4-ethynyl-4-hydroxy-2,2,6,6-tetramethylpiperidinium cation) and studied by single-crystal X-ray and X-ray powder diffraction. The crystals are monoclinic: a = 16.868(8) Å, b = 13.177(8) Å, c = 13.32(1) Å, γ = 103.50(4)°, space group P2₁/b, Z = 8. The structure of the complex contains two crystallographically independent zwitterionic entities of the formula [(C₉H₁₆NH₂(OH)C≡CH)CuCl₂], which result from π-coordination of the potential π-bidentate bond C≡C of the organic cation to one Cu(I) atom of the inorganic anion CuCl ₂ ^? . The distances Cu-m (m is the midpoint of the C≡C bond) are 1.91(2) Å. Along with weak intermolecular hydrogen bonds ≡CH...Cl and intramolecular contacts OH...Cl, the structure is stabilized by a directed ionic interaction through strong NH...Cl bonds.     

Terminal Alkynes in the Coordination Sphere of Titanocene Complexes – Elementary Steps in Catalytic Dimerizations and Oligomerizations of Alkynes

The titanocene acetylene complex [Cp*₂Ti(η²-Me₃SiC≡CSiMe₃)] ( 14 ) reacts with 1-alkynes such as phenylacetylene ( 15 a ), 1-hexyne ( 15 b ), 1-dodecyne ( 15 c ) and trimethylsilylacetylene ( 15 d ) by ligand exchange and proton shift, to yield exclusively the 1-alkenyltitanocene acetylides [Cp*₂Ti(CH=CHR)(C≡CR)] ( 21 ) (R = Ph ( 21 a ), CH₃(CH₂)₃ ( 21 b ), CH₃(CH₂)₉ ( 21 c ), SiMe₃ ( 21 d )). The X-ray structure of 21 a is presented. In reaction of acetylene HC≡CH ( 15 e ) with 14 other products are formed. However, no intermediates, like [Cp*₂Ti(η²-RC≡CH)] ( 17 ), [Cp*₂Ti(H)C≡CR] ( 17 ) or [Cp*₂Ti=C=CHR] ( 22 ) in reactions of 14 with 15 are detectable. On the other hand, a stable titanocenehydride [Cp*₂Ti(H)OCH₃] ( 23 ) is obtained by oxidative addition of CH₃OH with Cp*₂Ti, generated from 14 .     

Synthesis and Characterization of Rhenabenzyne Complexes

Reactions of [ReH₅(PMe₂Ph)₃] with alkynols HC≡CC(OH)(R)C≡CSiMe₃ (R=tBu, iPr, 1‐adamantyl) in the presence of HCl give the vinylcarbyne complexes [Re{≡CCH?C(R)C≡CSiMe₃}Cl₂(PMe₂Ph)₃], which react with tBuMgCl to give [Re{≡CCH?C(R)C≡CSiMe₃}HCl(PMe₂Ph)₃]. Treatment of [Re{≡CCH?C(R)C≡CSiMe₃}HCl(PMe₂Ph)₃] with nBu₄NF gives [Re{≡CCH?C(R)C≡CH}HCl(PMe₂Ph)₃], which first isomerizes to the bicyclic complexes [Re{CH?CH? C(R)?CCH?}Cl(PMe₂Ph)₃], and then to the rhenabenzynes [Re{≡CCH?C(R)CH?CH}Cl(PMe₂Ph)₃]. The NMR spectroscopic and structural data as well as the aromatic stabilization energy (ASE) and nucleus‐independent chemical‐shift (NICS) values suggest that these rhenabenzynes have aromatic character.     

Further Evidence for ‘Extended’ Cumulene Complexes: Derivatives from Reactions with Halide Anions and Water

Reactions of [Ru{C=C(H)-1,4-C₆H₄C≡CH}(PPh₃)₂Cp]BF₄ ([ 1 a ]BF₄) with hydrohalic acids, HX, results in the formation of [Ru{C≡C-1,4-C₆H₄-C(X)=CH₂}(PPh₃)₂Cp] [X=Cl ( 2 a-Cl ), Br ( 2 a-Br )], arising from facile Markovnikov addition of halide anions to the putative quinoidal cumulene cation [Ru(=C=C=C₆H₄=C=CH₂)(PPh₃)₂Cp]⁺. Similarly, [M{C=C(H)-1,4-C₆H₄-C≡CH}(LL)Cp ]BF₄ [M(LL)Cp’=Ru(PPh₃)₂Cp ([ 1 a ]BF₄); Ru(dppe)Cp* ([ 1 b ]BF₄); Fe(dppe)Cp ([ 1 c ]BF₄); Fe(dppe)Cp* ([ 1 d ]BF₄)] react with H⁺/H₂O to give the acyl-functionalised phenylacetylide complexes [M{C≡C-1,4-C₆H₄-C(=O)CH₃}(LL)Cp’] ( 3 a – d ) after workup. The Markovnikov addition of the nucleophile to the remote alkyne in the cations [ 1 a–d ]⁺ is difficult to rationalise from the vinylidene form of the precursor and is much more satisfactorily explained from initial isomerisation to the quinoidal cumulene complexes [M(=C=C=C₆H₄=C=CH₂)(LL)Cp’]⁺ prior to attack at the more exposed, remote quaternary carbon. Thus, whilst representative acetylide complexes [Ru(C≡C-1,4-C₆H₄-C≡CH)(PPh₃)₂Cp] ( 4 a ) and [Ru(C≡C-1,4-C₆H₄-C≡CH)(dppe)Cp*] ( 4 b ) reacted with the relatively small electrophiles [CN]⁺ and [C₇H₇]⁺ at the β-carbon to give the expected vinylidene complexes, the bulky trityl ([CPh₃]⁺) electrophile reacted with [M(C≡C-1,4-C₆H₄-C≡CH)(LL)Cp’] [M(LL)Cp’=Ru(PPh₃)₂Cp ( 4 a ); Ru(dppe)Cp* ( 4 b ); Fe(dppe)Cp ( 4 c ); Fe(dppe)Cp* ( 4 d )] at the more exposed remote end of the carbon-rich ligand to give the putative quinoidal cumulene complexes [M{C=C=C₆H₄=C=C(H)CPh₃}(LL)Cp’]⁺, which were isolated as the water adducts [M{C≡C-1,4-C₆H₄-C(=O)CH₂CPh₃}(LL)Cp’] ( 6 a–d ). Evincing the scope of the formation of such extended cumulenes from ethynyl-substituted arylvinylene precursors, the rather reactive half-sandwich (5-ethynyl-2-thienyl)vinylidene complexes [M{C=C(H)-2,5-^cC₄H₂S-C≡CH}(LL)Cp’]BF₄ ([ 7 a – d ]BF₄ add water readily to give [M{C≡C-2,5-^cC₄H₂S-C(=O)CH₃}(LL)Cp’] ( 8 a – d )].     

Organometallic reactions as tools to build new metal-containing conjugated polymers

By using organometallic reactions like Pd-catalyzed C-C coupling, metal-carbon bond formation and silicon-carbon bond cleavage, novel carbon-rich organometallic monomers HC≡C-C₆H₄-C≡C-[M]-C≡C-C₆H₄-C≡CH ( [M] = -Ru(dppe)₂- and (η⁵-C₅H₄)₂Fe) and organic monomers H-(C≡C-C₆H₄)_X-C≡CH (x = 1 to 3) have been obtained. They have been used for the design of novel homo and hetero metal-containing polymers via organometallic polycondensation reactions based on quantitative metal-carbon bond formation.     

Synthesis and Characterization of Dirhenadehydro[12]annulenes

The 12‐membered‐ring metallacycles [mer‐Re{≡CCH=C(R)C≡C?}Cl(PMe₂Ph)₃)]₂ (R=CMe₃, 1‐adamantyl), which are organometallic analogues of antiaromatic octadehydro[12]annulene, are prepared by heating the methyl carbyne complexes mer‐Re{≡CCH=C(R)C≡CH}(CH₃)Cl(PMe₂Ph)₃. An intermolecular σ‐bond metathesis between the Re?CH₃ bond and the acetylenic C?H bond is proposed for their formation.     

<Emphasis Type="Italic">N</Emphasis>-allyl and <Emphasis Type="Italic">N</Emphasis>-propargyl trifluoromethanesulfonimides. Theoretical analysis

Tautomers of N-allyl- and N-propargyl-substituted trifluoromethanesulfonimides (CF₃SO₂)₂NR (R = CH₂CH=CH₂, Z/E-CH=CHMe, CH₂C≡CH, CH=CH=CH₂, C≡CCH₂) were calculated by the DFT (B3LYP, wB97XD, PBE1PBE), MP2, and CBS-QB3 methods. The results were compared with the theoretical data for the corresponding amines and amides NHRR¹ (R¹ = H, CF₃SO₂). It was shown that there is no conjugation between the nitrogen atom and C=C bond and that conjugation exists with the C≡C bond with electron density displacement toward the nitrogen atom. The calculations of anions derived from N-allyl- and N-propargyl-trifluoromethanesulfonimides revealed the possibility of their rearrangement with elimination of trifluoromethanesulfinate anion and formation of its H-complex with N-(prop-2-en-1-ylidene)trifluoromethanesulfonamide or N-(prop-2-yn-1-ylidene)trifluoromethanesulfonamide.     

Synthesis of silanes and germanes with polyunsaturated aliphatic substituents

Hydrosilylation of alkynes R₃MC≡CH (M = Si, Ge) afforded adducts whose subsequent treatment with ethynylmagnesium bromide gives polyunsaturated silanes and germanes R₃MCH=CHSi(C≡CH)₃. The latter can be subjected to the same transfomations to result in the unsaturated chain growth.     

N-allenyl-N-benzyltrifl uoromethanesulfonamide

First N-allenyl-substitued triflamides CF₃SO₂N(Bn)CH=C=CH₂ were synthesized from N-allyltriflamides by sucessive reactions of bromination, N-alkylation, and dehydrobromination. Isomeric N-propargyltriflamide CF₃SO₂N(Bn)CH₂C≡CH is present in the reaction products as a minor admixture.     

Synthese eines funktionalen Aluminiumalkinids,Me3C‐C≡C‐AlBr2, und dessen Reaktionen mit der sperrigen Lithiumverbindung LiCH(SiMe3)2

Synthesis of a Functional Aluminium Alkynide, Me₃C‐C≡C‐AlBr₂, and its Reactions with the Bulky Lithium Compound LiCH(SiMe₃)₂ Treatment of aluminium tribromide with the lithium alkynide (Li)C≡C‐CMe₃ afforded the aluminium alkynide Me₃C‐C≡C‐AlBr₂ ( 1 ) in an almost quantitative yield. 1 crystallizes with trimeric formula units possessing Al₃C₃ heterocycles and the anionic carbon atoms of the alkynido groups in the bridging positions. A dynamic equilibrium was determined in solution which probably comprises trimeric and dimeric formula units. Reaction of 1 with one equivalent of LiCH(SiMe₃)₂ yielded the compound [Me₃C‐C≡C‐Al(Br)‐CH(SiMe₃)₂]₂ ( 2 ), which is a dimer via Al‐C‐Al bridges. Two equivalents of the lithium compound gave a mixture of four main‐products, which could be identified as 2 , Li[Me₃C‐C≡C‐Al{CH(SiMe₃)₂}₃] ( 3 ), Me₃C‐C≡C‐Al[CH(SiMe₃)₂]₂ ( 4 ), and Al[CH(SiMe₃)₂]₃. The lithium atom of 3 is coordinated by the C≡C triple bond and an inner carbon atom of one bis(trimethylsilyl)methyl group. Further interactions were observed to C‐H bonds of methyl groups.     

Treatment of a Methylene‐Bridged Dialuminium Compound with Lithium Alkanides and Alkynides ‐ Single vs. Twofold Terminal Coordination

We have investigated the coordination of alkanide and alkynide anions to the coordinatively unsaturated aluminium atoms of the methylene‐bridged dialuminium compound R₂Al‐CH₂‐AlR₂ [ 1 , R = CH(SiMe₃)₂]. Treatment of 1 with the corresponding lithium derivatives in the presence of a small excess of TMEN (TMEN = tetramethylethylenediamine) yielded mono‐adducts [M]⁺[R₂Al‐CH₂‐AlR₂R']^– [ 2a , M = Li(TMEN)₂, R' = Me; 2b , M = Li(TMEN)₂, R' = n‐Bu; 3a , M = Li(TMEN)₂, R' = C≡C‐SiMe₃; 3b , M = Li(TMEN)₂, R' = C≡C‐t‐Bu; 3d , M = Li(DME)₃, R' = C≡C‐Ph; 3e , M = Li(TMEN)₂, R' = C≡C‐PPh₂)] and bis‐adducts [Li(TMEN)₂]⁺[LiCH₂(AlR₂R')₂]^– [ 4a , R' = C≡C‐CH₂‐NEt₂; 4b , R' = C≡C‐t‐Bu]. In the solid state the mono‐adducts have clearly separated coordinatively saturated (coordination number four) and unsaturated aluminium atoms (coordination number three). In solution the groups R' show a fast exchange between both aluminium atoms as evident from the room temperature NMR spectra that showed in most cases equivalent CH(SiMe₃)₂ groups despite different coordination spheres of the metal atoms. Only 2b gave the expected splitting of resonances at ambient temperature, while cooling was required to prevent the dynamic process for 3a . The dialkynide 4a has a unique molecular structure with one of the lithium cations bonded to the α‐carbon atoms of the alkynido ligands and to the carbon atom of the methylene bridge which is five‐coordinate with a distorted trigonal bipyramidal coordination sphere.     

Katalysatordesaktivierungen bei der Acetylen-Polymerisation mit Titanocen- bzw. Zirconocen-Komplexen des Bis(trimethylsilyl)acetylens

Desactivation of Catalysts in the Polymerization of Acetylene by Bis(trimethylsilyl)acetylene Complexes of Titanocene or Zirconocene Unexpected inactive byproducts were observed in the catalytic polymerization of acetylene using metallocene alkyne complexes Cp₂M(L)(η²-Me₃SiC₂SiMe₃), 1 : M = Ti, without L; 2 : M = Zr, L = thf. The reaction of 1 was investigated in detail by NMR to give quantitatively at –20 °C the titanacyclopentadiene Cp₂Ti–CH=CH–C(SiMe₃)=C(SiMe₃) ( 3 ). Around 0 °C 3 starts to rearrange to yield the dihydroindenyl complex 4 via coupling of one Cp-ligand with the titanacyclopentadiene. In the reaction of 2 under analogous conditions a zirconacyclopentadiene Cp₂Zr–CH=CH–C(SiMe₃)=C(SiMe₃) ( 5 ) and the dimeric complex [Cp₂Zr(C(SiMe₃)=CH(SiMe₃)]₂[μ-σ(1,2)-C≡C] ( 6 ) were observed. Whereas 5 decomposes to a mixture of unidentified paramagnetic species, 6 was isolated and investigated by NMR spectroscopy and X-ray analysis. In the reaction of rac-(ebthi)Zr(η²-Me₃SiC₂SiMe₃) (ebthi = ethylenbistetrahydroindenyl) with 2-ethynyl-pyridine the complex rac-(ebthi)ZrC(SiMe₃)=CH(SiMe₃)](σ-C≡CPy) 7 was obtained, which was investigated by an X-ray analysis.     

Synthesis and Characterization of Alkynyl Complexes of Groups 1 and 2

The synthesis of N‐heterocyclic carbene adducts of alkynyl lithium and magnesium is achieved, and different degrees of association are observed. Reaction of strontium amide nacnacSrN(SiMe₃)₂(thf) (nacnac=CH(CMe2,6‐iPr₂C₆H₃N)₂) with PhC≡CH in THF yields the dimeric alkynyl complex [nacnacSr(thf)(μ‐C≡CPh)]₂ which shows an interesting coordination geometry around the metal center. The compound retains the THF molecules, unlike its lighter congener, even in hydrocarbon solvents.     

Ab initio molecular dynamics study for C–Br dissociation within BrH<Subscript>2</Subscript>C–C≡C<Subscript>(ads)</Subscript> adsorbed on an Ag(111) surface: a short-time Fourier transform approach

The reaction dynamics for C–Br dissociation within BrH₂C–C≡CH_(ads) adsorbed on an Ag(111) surface has been investigated by combining density functional theory-based molecular dynamics simulations with short-time Fourier transform (STFT) analysis of the dipole moment autocorrelation function. Two possible reaction pathways for C–Br scission within BrH₂C–C≡CH_(ads) have been proposed on the basis of different initial structural models. Firstly, the initial perpendicular orientation of adsorbed BrH₂C–C≡CH_(ads) with a stronger C–Br bond will undergo dynamic rotation leading to the final parallel orientation of BrH₂C–C≡CH_(ads) to cause the C–Br scission, namely, an indirect dissociation pathway. Secondly, the initial parallel orientation of adsorbed BrH₂C–C≡C_(ads) with a weaker C–Br bond will directly cause the C–Br scission within BrH₂C–C≡CH_(ads), namely, a direct dissociation pathway. To further investigate the evolution of different vibrational modes of BrH₂C–C≡CH_(ads) along these two reaction pathways, the STFT analysis is performed to illustrate that the infrared (IR) active peaks of BrH₂C–C≡CH_(ads) such as vCH₂ [2956 cm^?1(s) and 3020 cm^?1(as)], v≡CH (3320 cm^?1) and vC≡C (2150 cm^?1) gradually vanish as the rupture of C–Br bond occurs and then the resulting IR active peaks such as C=C=C (1812 cm^?1), ω-CH₂ (780 cm^?1) and δ-CH (894 cm^?1) appear due to the formation of H₂C=C=CH_(ads) which are in a good agreement with experimental reflection adsorption infrared spectrum (RAIRS) at temperatures of 110 and 200 K, respectively. Finally, the total energy profiles indicate that the reaction barriers for the scission of C–Br within BrH₂C–C≡CH_(ads) along both direct and indirect dissociation pathways are very close due to a similar rupture of C–Br bond leading to a similar transition state.     

Synthesis, Characterization and Crystal Structures of Some Linked Metal Carbonyl Clusters Derived from Diethynyl-Substituted Silane and Disilane Ligands

The use of diethynylsilane, diethynyldisilane and diethynyldisiloxane in the synthesis of some linked metal carbonyl clusters is demonstrated. New dimeric η²-diyne complexes of cobalt [{Co₂(CO)₆}₂(η²-diyne)], ruthenium [{(μ-H)Ru₃(CO)₉}₂(μ₃-η²,η²-diyne)] and osmium [{(μ-CO)Os₃(CO)₉}₂(μ₃-η²-diyne)] {diyne=HC≡CSi(CH₃)₂C≡CH, HC≡CSi(CH₃)₂–Si(CH₃)₂C≡CH, HC≡CSi(CH₃)₂–O–Si(CH₃)₂C≡CH or HC≡CSi(Ph)₂C≡CH} have been prepared in good yields from the reaction of [Co₂(CO)₈], [Ru₃(CO)₁₂] and [Os₃(CO)₁₀(NCMe)₂] with half an equivalent of the appropriate diyne ligand, respectively. All the twelve compounds have been characterized by IR and ¹H NMR spectroscopies and mass spectrometry. The molecular structures of eight of them have been determined by X-ray crystallography. Structurally, each of the tetracobalt species displays two Co₂C₂ cores adopting the pseudo-tetrahedral geometry with the alkyne bond lying essentially perpendicular to the Co–Co vector. For the group 8 ruthenium and osmium analogues, the hexanuclear carbonyl clusters consist of two trinuclear metal cores with the μ₃-η²,η² bonding mode for the acetylene groups in the former case and μ₃-(η²-||) bonding mode in the latter one. Density functional theory was employed to study the electronic structures of these molecules in terms of the nature of the silyl or disilyl unit and its substituents.     

Theoretical study of the mechanism of the Wittig reaction: Ab initio and MNDO-PM3 treatment of the reaction of unstabilized,semistabilized, and stabilized ylides with acetaldehyde

In this study, we describe the results of ab initio (HF and MP2) and MNDO-PM3 calculations on the model reactions of unstabilized (Me₃P=CH–CH₃), semi-stabilized (Me₃P=CH–C≡CH), and stabilized (Me₃P=CH–C≡N) ylides with acetaldehyde to form their respective Z and E olefins and trimethylphosphine oxide. These reactions occur in three stages: oxaphosphetane formation, oxaphosphetane pseudorotation, and oxaphosphetane decomposition. The calculated barriers for these processes vary considerably depending on the level of theory employed (ab initio vs. MNDO-PM3 or HF vs. MP2 at the ab initio level). However, self-consistent geometries of reactants, intermediates, transition states and products are obtained at all levels. Oxaphosphetane formation is best described as very asynchronous cycloaddition (borderline two-step mechanisms). The geometries of the transition states are near planar with respect to P, C, C, and O atoms. Analysis of the bond indices of these reactions shows that the C–C bonds are between 44% (unstabilized case) and 60% (stabilized case) formed, whereas the corresponding P–O bonds have not been formed to any significant degree. Oxaphosphetane decomposition can be described as a very asynchronous retrocycloaddition where P–C bond breakage runs ahead of C–O bond breakage. These results are compared with experimental findings for the Wittig reaction, and its relevance to the overall mechanism of the olefination is discussed. © 1997 John Wiley & Sons, Inc. Heteroatom Chem 8: 557–569, 1997     

Synthesis of 2‐ and 2,7‐Functionalized Pyrene Derivatives: An Application of Selective C?H Borylation

An efficient synthetic route to 2‐ and 2,7‐substituted pyrenes is described. The regiospecific direct C? H borylation of pyrene with an iridium‐based catalyst, prepared in situ by the reaction of [{Ir(μ‐OMe)cod}₂] (cod=1,5‐cyclooctadiene) with 4,4′‐di‐tert‐butyl‐2,2′‐bipyridine, gives 2,7‐bis(Bpin)pyrene ( 1 ) and 2‐(Bpin)pyrene ( 2 , pin=OCMe₂CMe₂O). From 1 , by simple derivatization strategies, we synthesized 2,7‐bis(R)‐pyrenes with R=BF₃K ( 3 ), Br ( 4 ), OH ( 5 ), B(OH)₂ ( 6 ), and OTf ( 7 ). Using these nominally nucleophilic and electrophilic derivatives as coupling partners in Suzuki–Miyaura, Sonogashira, and Buchwald–Hartwig cross‐coupling reactions, we obtained 2,7‐bis(R)‐pyrenes with R=(4‐CO₂C₈H₁₇)C₆H₄ ( 8 ), Ph ( 9 ), C≡CPh ( 10 ), C≡C[{4‐B(Mes)₂}C₆H₄] ( 11 ), C≡CTMS ( 12 ), C≡C[(4‐NMe₂)C₆H₄] ( 14 ), C≡CH ( 15 ), N(Ph)[(4‐OMe)C₆H₄] ( 16 ), and R=OTf, R′=C≡CTMS ( 13 ). Lithiation of 4 , followed by reaction with CO₂, yielded pyrene‐2,7‐dicarboxylic acid ( 17 ), whilst borylation of 2‐tBu‐pyrene gave 2‐tBu‐7‐Bpin‐pyrene ( 18 ) selectively. By similar routes (including Negishi cross‐coupling reactions), monosubstituted 2‐R‐pyrenes with R=BF₃K ( 19 ), Br ( 20 ), OH ( 21 ), B(OH)₂ ( 22 ), [4‐B(Mes)₂]C₆H₄ ( 23 ), B(Mes)₂ ( 24 ), OTf ( 25 ), C≡CPh ( 26 ), C≡CTMS ( 27 ), (4‐CO₂Me)C₆H₄ ( 28 ), C≡CH ( 29 ), C₃H₆CO₂Me ( 30 ), OC₃H₆CO₂Me ( 31 ), C₃H₆CO₂H ( 32 ), OC₃H₆CO₂H ( 33 ), and O(CH₂)₁₂Br ( 34 ) were obtained from 2 . These derivatives are of synthetic and photophysical interest because they contain donor, acceptor, and conjugated substituents. The crystal structures of compounds 4 , 5 , 7 , 12 , 18 , 19 , 21 , 23 , 26 , and 28 – 31 have also been obtained from single‐crystal X‐ray diffraction data, revealing a diversity of packing modes, which are described in the Supporting Information. A detailed discussion of the structures of 1 and 2 , their polymorphs, solvates, and co‐crystals is reported separately.     

Transition‐Metal Complexes Based on the 1,3,5‐Triethynyl Benzene Linking Unit

The synthesis of a unique series of heteromultinuclear transition metal compounds is reported. Complexes 1‐I‐3‐Br‐5‐(FcC≡C)‐C₆H₃ ( 4 ), 1‐Br‐3‐(bpy‐C≡C)‐5‐(FcC≡C)‐C₆H₃ ( 6 ), 1,3‐(bpy‐C≡C)₂‐5‐(FcC≡C)‐C₆H₃ ( 7 ), 1‐(XC≡C)‐3‐(bpy‐C≡C)‐5‐(FcC≡C)‐C₆H₃ ( 8 , X = SiMe₃; 9 , X = H), 1‐(HC≡C)‐3‐[(CO)₃ClRe(bpy‐C≡C)]‐5‐(FcC≡C)‐C₆H₃ ( 11 ), 1‐[(Ph₃P)AuC≡C]‐3‐[(CO)₃ClRe(bpy‐C≡C)]‐5‐(FcC≡C)‐C₆H₃ ( 13 ), 1‐[(Ph₃P)AuC≡C]‐3‐(bpy‐C≡C)‐5‐(FcC≡C)‐C₆H₃ ( 14 ), [1‐[(Ph₃PAuC≡C]‐3‐[{[Ti](C≡CSiMe₃)₂}Cu(bpy‐C≡C)]‐5‐(FcC≡C)‐C₆H₃]PF₆ ( 16 ), and [1,3‐[(tBu₂bpy)₂Ru(bpy‐C≡C)]₂‐5‐(FcC≡C)‐C₆H₃](PF₆)₄ ( 18 ) (Fc = (η⁵‐C₅H₄)(η⁵‐C₅H₅)Fe, bpy = 2,2′‐bipyridiyl‐5‐yl, [Ti] = (η⁵‐C₅H₄SiMe₃)₂Ti) were prepared by using consecutive synthesis methodologies including metathesis, desilylation, dehydrohalogenation, and carbon–carbon cross‐coupling reactions. In these complexes the corresponding metal atoms are connected by carbon‐rich bridging units comprising 1,3‐diethynyl‐, 1,3,5‐triethynylbenzene and bipyridyl units. They were characterized by elemental analysis, IR and NMR spectroscopy, and partly by ESI‐TOF mass spectrometry., The structures of 4 and 11 in the solid state are reported. Both molecules are characterized by the central benzene core bridging the individual transition metal complex fragments. The corresponding acetylide entities are, as typical, found in a linear arrangement with representative M–C, C–C_C≡C and C≡C bond lengths.     

Hydroalumination of diazo and azido compounds: An Al-H addition to end-on nitrogen of substrates

This paper reports the reactions of a monomeric aluminum dihydride LAlH₂ (L = HC[C(Me)N(Ar)]₂, Ar = 2,6-i-Pr₂C₆H₃) with diazo, azido, and terminal alkyne compounds. The reaction of LAlH₂ with N₂CH(SiMe₃) and N₃(1-Ad) occurred through an Al-H addition to end-on nitrogen to yield respective compounds LAl[N(H)N = CH(SiMe₃)]₂ (1) and LAl[N(H)N=N(1-Ad)]₂ (2), while the reaction of LAlH₂ with PhC≡CH occurred through a stepwise deprotonation to yield LAlH(C≡CPh) (5) and LAl-(C≡CPh)₂ (6), respectively. 2 further reacted by N₂-release to yield LAl[NH(1-Ad)][N(H)N=N(1-Ad)] (3) and LAl[NH-(1-Ad)]₂ (4) upon the increased temperature treatment. Compounds 1–6 have been fully characterized, revealing novel reactivity patterns of LAlH₂ toward different substrates under the steric influence from the bulky L ligand at Al.