New thiocarbamate and thioureate palladium and platinum complexes: synthesis and use as metalloligands. Unprecedented coordination of the thioureate ligand in [(C6F5)2Pd{μ2,η-SC(NMe2)NPh}Pd(C6F5)(bpzm)]

The di-μ-hydroxo complexes [NBu₄]₂[{(C₆F₅)₂M(μ-OH)}₂] (M=Pd, Pt) react with PhNCS in alcohol ROH solution to yield the N,S-chelating thiocarbamate metal complexes [NBu₄][(C₆F₅)₂M{η²-SC(OR)NPh}] (R=Me, Et or Prⁿ). [NBu₄]₂[{(C₆F₅)₂Pd(μ-OH)}₂] also reacts with PhNCS in the presence of dialkylamines R₂NH to yield the N,S-chelating thioureate (1−) palladium complexes [NBu₄][(C₆F₅)₂Pd{η²-SC(NR₂)NPh}] (R=Me or Et). [NBu₄][(C₆F₅)₂M{η²-SC(X)NPh}] (M=Pd or Pt; X=OMe or NR₂) reacts with [(C₆F₅)Pd(bpzm)(acetone)]ClO₄ to yield the dinuclear complexes [(C₆F₅)₂M{(μ₂,η²-{SC(X)NPh}Pd(C₆F₅)(bpzm)] (M=Pd or Pt, X=OMe or NR₂; bpzm=bis(3,5-dimethylpyrazol-1-yl)methane). The single-crystal structures of [NBu₄][(C₆F₅)₂Pd{η²-SC(OMe)NPh}] and [(C₆F₅)₂Pd{μ₂,η²-SC(NMe₂)NPh}Pd(C₆F₅)(bpzm)] have been established by X-ray diffraction.     

Organometallic nickel(II) complexes with dithiophosphate, dithiophosphonate and monothiophosphonate ligands

The hydroxo complex [NBu₄]₂[Ni₂(C₆F₅)₄(μ-OH)₂] reacts with ammonium O,O^′-dialkyldithiophosphates, O-alkyl-p-methoxyphenyldithiophosphonate acids and ammonium O-alkylferrocenyldithiophosphonates in dichloromethane under mild conditions to give, respectively, [NBu₄][Ni(C₆F₅)₂{S(S)P(OR)₂}] (R=Me (1), Et (2), ⁱPr (3)) and [NBu₄][Ni(C₆F₅)₂{S(S)P(OR)Ar}] (Ar=p-MeOC₆H₄, R=Me (4), Et (5), ⁱPr (6); Ar=ferrocenyl; R=Me (7), Et (8), ⁱPr (9)). The monothiophosphonate nickel complexes [NBu₄][Ni(C₆F₅)₂{S(S)P(OR)(ferrocenyl)}] (R=Et (10), ⁱPr (11)) are obtained by reaction of the hydroxo complex with O-alkylferrocenyldithiophosphonate acids. Analytical (C, H, N, S), conductivity, and spectroscopic (IR, ¹H, ¹⁹F and ³¹P NMR, and FAB-MS) data were used for structural assignments. A single-crystal X-ray diffraction study of [NBu₄][Ni(C₆F₅)₂{S(S)P(OMe)(p-MeOC₆H₄)}] (4) and [NBu₄][Ni(C₆F₅)₂{S(O)P(OEt)(ferrocenyl)}] (10) shows that in both cases the coordination around the nickel atom es essentially square planar with NiC₂S₂ and NiC₂SO central cores, respectively.     

Synthesis, structure and thermochemical behavior of bis-(1,1,1,5,5,5-hexafluoro-2,4-pentanedionato)-(1,4,7,10,13,16-hexaoxa-cyclooctadecane)-strontium in comparison with its structural and thermochemical analogous

The trans-[M(18-crown-6)(C₅HO₂F₆)₂] (M = Ca, Sr, Ba, Pb) complexes have been synthesized and identified. The crystal structure of the Sr complex has been determined by X-ray diffraction. The basic structural unit is the mononuclear complex trans-[Sr(18-crown-6)(C₅HO₂F₆)₂]. The thermal properties of the complexes have been correlated to their structure. The melting and decomposition ranges of the Ca, Sr and Ba complexes and their sublimation temperatures at ∼10⁻² mm Hg have been determined. Experimental evidence is presented that the complexes are similar in volatility.     

Ligand substitution reactions of the [ReX6] (X = Cl, Br) anions. Synthesis and crystal structure of novel oxalato complexes of rhenium(IV)

The reaction of K₂[ReX₆] (X = Cl, Br) with oxalic acid and triethylamine in dimethylformamide solution yields the substituted complexes [ReX₄(ox)]²⁻ and cis-[ReX₂(ox)₂]²⁻, which can be obtained separately depending on the amount of added amine. The crystal structures of (PPh₄)₂[ReBr₄(ox)], cis-(PPh₄)₂[ReBr₂(ox)₂] and cis-(AsPh₄)₂[ReCl₂(ox)₂] have been determined by single-crystal X-ray diffraction. The anionic complexes are octahedral with only slight distortions. The direct isolation of the pure complexes as well as the formation of only the cis isomers - without the presence of trans isomers and/or [Re(ox)₃]²⁻ - is probably due to the kinetic inertness of Re(IV)-X bonds, which increases with the number of oxalato ligands bound to the metal ion.     

A novel ruthenium nitrosyl complex which also contains a free NO-donor moiety

The synthesis and characterisation of a novel ruthenium nitrosyl complex with coordinated 4-pyridinehydroxamic acid, [NBu₄][cis-RuCl₄(4-pyha)NO] (4-pyha=4-pyridinehydroxamic acid, NO=nitric oxide) is reported. [NBu₄][cis-RuCl₄(4-pyha)NO] was prepared from the precursor, NBu₄[trans-RuCl₄(dmso-O)NO] (dmso=dimethylsulfoxide) upon treatment with 4-pyridinehydroxamic acid. [NBu₄][cis-RuCl₄(4-pyha)NO] possesses the linear {Ru^II(NO)⁺} moiety and a cis-pyridinehydroxamic acid group which has the potential to act as an NO donor. The crystal structure of [NBu₄][cis-RuCl₄(4-pyha)NO] was also determined. The nitrosyl complex is novel in that, besides coordinated NO, it also contains a ligand which has the potential to release NO.     

New pentafluorophenyl complexes with phosphine-amide ligands

A series of nickel(II) and palladium(II) complexes containing one or two pentafluorophenyl ligands and the phosphino-amides o-Ph₂PC₆H₄CONHR [R = ⁱPr (a), Ph (b)] displaying different coordination modes have been synthesised. The chelating ability of these ligands and the influence of both coligands and the metal centre in their potential hemilabile behaviour have been explored. The crystal structure of (b) has been determined and reveals N–H⋯O intermolecular hydrogen bonding. Bis-pentafluorophenyl derivatives [M(C₆F₅)₂(o-Ph₂PC₆H₄CO-NHR)] [M = Ni; R = ⁱPr (1a); R = Ph (1b); M = Pd; R = ⁱPr (2a); R = Ph (2b)] in which (a) and (b) act as rigid P, O-chelating ligands were readily prepared from the labile precursors cis-[M(C₆F₅)₂(PhCN)₂]. X-ray structures of (1a), (1b) and (2a) have been established, allowing an interesting comparative structural discussion. Dinuclear [{Pd(C₆F₅)(tht)(μ-Cl)}₂] reacted with (a) and (b) yielding the monopentafluorophenyl complexes [Pd(C₆F₅)Cl{PPh₂(C₆H₄–CONH–R)}] (R = ⁱPr (3a), Ph (3b)) that showed a P, O-chelating behaviour of the ligands, confirmed by the crystal structure determination of (3a). New cationic palladium(II) complexes in which (a) and (b) behave as P-monodentate ligands have been synthesised by reacting them with [{Pd(C₆F₅)(tht)(μ-Cl)}₂], stoichiometric Ag(O₃SCF₃) and external chelating reagents such as cod [Pd(C₆F₅)(cod){PPh₂(C₆H₄-CONH-R)}](O₃SCF₃)(R = ⁱPr (4a), Ph (4b)) and 2,2′-bipy [Pd(C₆F₅)(bipy){PPh₂(C₆H₄-CONH-R)}](O₃SCF₃) (R = ⁱPr (5a), Ph (5b)). When chloride abstraction in [{Pd(C₆F₅)(tht)(μ-Cl)}₂] is promoted by means of a dithioanionic salt as dimethyl dithiophospate in the presence of (a) or (b), the corresponding neutral complexes [Pd(C₆F₅){S(S)P(OMe)₂}{PPh₂(C₆H₄-CONH-R)}] (R = ⁱPr (6a), Ph (6b)) were obtained.     

Silver(I) complexes of fluorinated scorpionates: Ligand effects in silver catalyzed carbene insertion into C-H bonds in alkanes

Activation of C-H bonds of hydrocarbons via intermolecular carbene insertion has been investigated using tris(pyrazolyl)boratosilver(I) catalysts [MeB(3-(CF₃)Pz)₃]Ag(C₂H₄), [MeB(3-(C₂F₅)Pz)₃]Ag(C₂H₄) and [HB(3,5-(CF₃)₂Pz)₃]Ag(C₂H₄). Cyclopentane, 2-methylbutane, and 2,3-dimethylbutane were used as substrates. Carbenes derived from ethyl and tert-butyl diazoacetates have effectively been inserted into tertiary, secondary, as well as primary C-H bonds of hydrocarbons at room temperature using these catalysts. Tertiary C-H bonds in these substrates get preferentially activated over secondary C-H followed by primary C-H bonds. However, it is possible to increase the amount of primary C-H bond activated product by utilizing catalysts with increasingly acidic silver sites and sterically bulky tris(pyrazolyl)borate ligands. The carbene insertion into primary C-H bonds increases in the order: [MeB(3-(CF₃)Pz)₃]Ag(C₂H₄) < [MeB(3-(C₂F₅)Pz)₃]Ag(C₂H₄) < [HB(3,5-(CF₃)₂Pz)₃]Ag(C₂H₄). The carbene derived from tert-butyl diazoacetate with these catalysts shows slightly lower selectivity for primary C-H bonds compared to the ethyl diazoacetate-based carbene.     

Complexation associated rearrangement of iminobiphosphines to diphosphinoamines

The reaction of the iminobiphosphines RNPPh₂-PPh₂, where R = C₆H₄(p-CN), C₆H₄(m-CN), C₆H₄(o-C₆H₅), C₆F₅ or C₆H₄(o-CF₃), with one molecular equivalent of M(cod)Cl₂ (M = Pd or Pt) results in a rearrangement of the NPP unit to the more commonly encountered P-N-P unit, forming mono-chelating complexes of general formula M{RN(PPh₂)₂}Cl₂. The related reaction of the same range of iminobiphosphines with Pt(cod)Cl₂ (but not Pd(cod)Cl₂) in 2:1 ratio affords complexes of general formula [Pt{RN(PPh₂)₂}₂]2Cl. All 15 complexes are isolated in moderate to high yield and they have been fully characterised by spectroscopic methods. Six complexes, viz. [M{C₆H₄(p-CN)N(PPh₂)₂}Cl₂], [M{C₆H₄(m-CN)N(PPh₂)₂}Cl₂] and [M{C₆H₄(o-C₆H₅)N(PPh₂)₂}Cl₂] (M = Pd and Pt), have been characterised in the solid state by single crystal X-ray diffraction analysis.     

Intermetallic coinage metal-catalyzed functionalization of alkanes with ethyl diazoacetate: Gold as a ligand

The complexes [Au₂M₂(C₆F₅)₄(NCMe)₂]_n (M = Cu, 1; M = Ag, 2) have been tested as catalysts for the functionalization of alkanes by the carbene insertion methodology, using ethyl diazoacetate as the carbene source. Moderate to high conversions have been obtained. The observed selectivities seem to favor the proposal that the active metal for catalysis is the Cu/Ag center, the Au(C₆F₅)₂ unit acting as a spectator ligand in both cases.     

Cationic copper(I) and silver(I) nitrile complexes with fluorinated weakly coordinating anions: Metal–nitrile bond strength and its influence on the catalytic performance

Copper(I) and silver(I) complexes of formulae [Cu(NCCH₃)₄]⁺[A]⁻ ([A]⁻ = [B(C₆F₅)₄]⁻ (1), {B[C₆H₃(CF₃)₂]₄}⁻ (2), [(C₆F₅)₃B–C₃H₃N₂–B(C₆F₅)₃]⁻ (3), and [Ag(NCCH₃)₄]⁺[B(C₆F₅)₄]⁻ (4) are examined with particular emphasis on the strength of their M–N bond and its influence on the catalytic performance of these complexes in cyclopropanation and aziridination. To examine the strength of the M–N interactions, vibrational spectra of the related hydrogenated and deuterated species [Cu(NCCH₃)₄]⁺, [Cu(NCCD₃)₄]⁺, [Ag(NCCH₃)₄]⁺, and [Ag(NCCD₃)₄]⁺ are also determined. It is found that the metal–nitrile bond strength is an important factor for the catalytic activity of the respective complexes.     

A theoretical study on the halogen bonding interactions of C6F5I with a series of group 10 metal monohalides

The halogen bonding interactions between C₆F₅I and a series of transition metal monohalides trans-[M(X)(2-C₅NF₄)-(PR₃)₂] (M = Ni, Pd, Pt; X = F, Cl, Br; R = Me, Cy) have been studied with quantum chemical calculations. Optimized geometries of the halogen bonding complexes indicate that angles C₁-I···X are basically linear (178–180°) and angles I···X-M mainly range from 90 to 150°. The strength of these metal-influenced halogen bonds alters with different metal centers, metal-bound halogen atoms and the substitutes on phosphine ligands. Electrostatic potential and natural bond orbital analysis show that both of the electrostatic and orbital interactions make a contribution to the formation of halogen bonds, while the electrostatic term plays a dominant role. AIM analysis suggests that, for trans-[M(F)(2-C₅NF₄)-(PR₃)₂] (M = Ni, Pd, Pt) monomers, the formed halogen bonding complexes are stabilized by local concentration of the charge of intermediate character, while for the metal monomers containing chlorine and bromine, a typical closed-shell interaction exist. These results prove that the structures and geometries of these halogen bonding complexes can be tuned by changing the halogen atoms and metal centers, which may provide useful information for the design and synthesis of new functional materials.

Rhenium(IV) cyanate complexes: Synthesis, crystal structures and magnetic properties of NBu4[ReBr4(OCN)(DMF)] and (NBu4)2[ReBr(OCN)2(NCO)3]

Two new rhenium(IV) mononuclear compounds of formula NBu₄[ReBr₄(OCN)(DMF)] (1) and (NBu₄)₂[ReBr(OCN)₂(NCO)₃] (2) (NBu₄ = tetrabutylammonium cation, OCN = O-bonded cyanate anion, NCO = N-bonded cyanate anion and DMF = N,N-dimethylformamide) have been synthesized and their crystal structures determined by single-crystal X-ray diffraction. 1 crystallizes in the monoclinic system with the space group P2₁/n, whereas 2 crystallizes in the triclinic one with as space group. In both complexes the rhenium atom is six-coordinated, in 1 by four Br atoms in the equatorial plane, and two trans-oxygen atoms, one of a DMF molecule and another one from a cyanato group, while in 2 by one bromide anion and five cyanate ligands, two of which are O-bonded and three N-bonded, forming a somewhat distorted octahedral surrounding. Magnetic susceptibility measurements on polycrystalline samples of 1 and 2 in the temperature range 1.9-300 K are interpreted in terms of magnetically isolated spin quartets with large values of the zero-field splitting (|2D| is ca. 41.6 and 39.2 cm⁻¹ for 1 and 2, respectively).     

Versatility of pyridine-2-methanol as a chelating ligand toward a manganese ion: synthesis and X-ray structural analysis on some manganese-pyridine-2-methanol derivatives

A systematic synthesis and X-ray structural analysis have been made for several manganese derivatives with pyridine-2-methanol as a chelating ligand; neutral Mn(C₅NH₄-2-CH₂OH)₂(C₆F₅CO₂)₂ (1), trans-[Mn(C₅H₄N-2-CH₂-OH)₂{C₆F₄-1,4-(CO₂)₂}]_∞ (2), cis-[Mn(C₅H₄N-2-CH₂-OH)₂{C₆F₄-1,3-(CO₂)₂}]_∞ (3), {Mn(C₅H₄N-2-CH₂-OH)₂(4,4^′-bipyridine)(ClO₄)}_∞ (4), and Mn(C₅H₄N-2-CH₂-OH)₃(ClO₄)₂(4,4-azopiridine) (pyridine-2-methanol) (5) are our results. 1 and 5 are monomers, while 2-4 are polymers. An oxidation state of the manganese ion in 1, 2, 3, and 5 is 2⁺, while that of 4 is suggested to be 3⁺. The magnetic data of 4 down to 2 K are measured. The length of the linker ligand has been suggested to afford a crucial effect on the dimensionality of the product.     

Generation of trans-dioxoruthenium(VI) porphyrins: A photochemical approach

trans-Dioxoruthenium(VI) porphyrin complexes have been developed as one of the best-characterized model systems for heme-containing enzymes. Traditionally, this type of compounds can be prepared by oxidation of ruthenium(II) precursors with peroxyacids and other terminal oxidants under different conditions, depending on the porphyrin ligands. In this work, a new photochemical generation of trans-dioxoruthenium(VI) porphyrins has been developed by extension of the known photo-induced ligand cleavage reactions. Refluxing ruthenium(II) carbonyl porphyrins [Ru^II(Por)(CO)] in carbon tetrachloride afforded dichlororuthenium(IV) complexes [Ru^IV(Por)Cl₂]. Facile exchange of the counterions in [Ru^IV(Por)Cl₂] with Ag(ClO₃) or Ag(BrO₃) gave the corresponding dichlorate [Ru^IV(Por)(ClO₃)₂] or dibromate [Ru^IV(Por)(BrO₃)₂] salts. Visible-light photolysis of the photo-labile porphyrin-ruthenium(IV) dichlorates or dibromates resulted in homolytic cleavage of the two O-Cl or O-Br bonds in the axial ligands to produce trans-dioxoruthenium(IV) species [Ru^VI(Por)O₂] bearing different porphyrin ligands.     

Spectroscopic and structural characterizations of ammonium peroxo-carboxylato molybdate(VI) complexes

New ammonium derivatives of peroxo-carboxylato molybdenum(VI) complexes of general formula (NH₄)₂[MoO(O₂)₂(H_xL)] · nH₂O with L=oxalate (ox), citrate (cit), tartrate (tart), glycolate (glyc) and malate (mal) and (NH₄)₂[MoO₂(O₂)(L)] with L=oxalate (ox) have been prepared and characterized on the basis of elemental and thermal analysis as well as by IR and ¹³C NMR spectroscopy. These last two spectroscopic methods have been used to suggest the coordination mode of the ligand in the complexes. The X-ray crystal structures of the compounds (NH₄)₂[Mo₂O₂(O₂)₂(OH)₂(ox)₂], (NH₄)₂[MoO(O₂)₂(ox)] and (NH₄)₂[MoO(O₂)₂(glyc)] · 0.5EtOH have been determined, all showing a sevenfold-coordinated Mo atom with bidentate peroxides and carboxylate ligands.     

Synthesis, structure and reactivity of complexes containing [M(S2)2] fragments (M=Ru, Os; (S2)=1,2-benzenedithiolate (2−))

Subsequent addition of 1,2-benzenedithiol (S₂-H₂) and nBuLi to a solution of [Ru(NO)Cl₃ · xMeOH] in THF afforded exclusively the monomeric species NBu₄[Ru^II(NO)(S₂)₂] (1). Formation of dimeric (NBu₄)₂[Ru^II(NO)(S₂)₂]₂ (2) has been confirmed when the deprotonated ligand S₂-Li₂ was added to [Ru(NO)Cl₃ · xMeOH] and allowed to stir for 30 h. The monomer 1 undergoes aerial oxidation to give (NBu₄)₂[Ru^IV(S₂)₃] (3). The reaction between RuCl₃ · xH₂O and S₂-H₂ in the presence of NaOMe, afforded the dinulear Ru^III species (NMe₄)₂[Ru^III(S₂)₂]₂ (4). A modified method for the preparation of 1 is being employed to synthesize the osmium analogue NBu₄[Os(NO)(S₂)₂] (5) effectively. The solid state structures of 1, 2 and 3 were determined by X-ray crystal structure analysis. A comparison of relevant bond distance data suggests that 1,2-benzenedithiolate acts as an “innocent” ligand.     

New open-framework phosphate and phosphite compounds of gallium

Five new open-framework compounds of gallium have been synthesized by hydrothermal methods and their structures determined by single crystal X-ray diffraction studies. The compounds, [C₈N₄H₂₆][Ga₆F₄(PO₄)₆], I, [C₅N₃H₁₁][Ga₃F₂(PO₄)₃]·H₂O, II, [C₆N₃H₁₉][Ga₄(C₂O₄)(PO₄)₄(H₂PO₄)]·2H₂O, III, [Ga₂F₃(HPO₄)(PO₄)]·2H₃O, IV, and [C₃N₂H₅]₂[Ga₄(H₂O)₃(HPO₃)₇], V, possess three-dimensional structures. All the compounds are formed by the connectivity between the Ga polyhedra and phosphite/phosphate units. The observation of SBU-6 (I and II) and spiro-5 (IV) secondary building units (SBUs) are noteworthy. The flexibility of the formation of gallium phosphate frameworks has been established by the isolation of two related structures (I and II) from the same SBU units but different organic amines. Some of the present structures have close resemblance to the gallium phosphate phases known earlier. The compounds have been characterized by CHN analysis, powder XRD, IR, and TGA.     

Insertion reactions of 1,4-diisocyanobenzene in binuclear Pd(I) complexes

Reactions between XPd(μ-dmp)₂PdX′ (X = X′ = Cl, Br, I, NCO, SCN, N₃ or C₆F₅; X = C₆F₅, X′ = Cl, Br, I, NCO) with 1,4-diisocyanobenzene lead to the tetranuclear complexes [(μ,μ′-CNC₆H₄NC){XPd(μ-dpm)₂PdX′}₂], where both ends of the diisocyanide are inserted in a metalmetal bond. The cationic derivatives [(μ,μ′-CNC₆H₄NC){(RNC)Pd(μ-dpm)₂(CNR)}₂](BPh₄)₄ and [(μ,μ′-CNC₆H₄NC){(RNC)Pd(μ-dpm)₂Pd(C₆F₅)}₂] (BPh₄)₂ (R = p-Tol, Cy, or ^tBu) are obtained by reacting [(μ,μ′-CNC₆H₄NC){ClPd(μ-dpm)₂PdX}₂] (X= Cl or C₆F₅) with RNC in the presence of NaBPh₄. Treatment of [(μ,μ′-CNC₆H₄NC){ClPd(μ-dpm)₂Pd(C₆F₅)}]₂ with NaBPh₄ causes the di-insertion and subsequent coordination of the isocyanide, yielding [(C₆F₅)Pd(CN-C₆H₄NC) Pd(μ-dpm)₂Pd(C₆F₅)](BPh₄)₂.     

Syntheses, structural and spectroscopic investigation (IR, NMR and luminescence) of new terbium and europium acylpyrazolonates

The synthesis and characterization of new lanthanide complexes of formulae [M(Q)₃(H₂O)(EtOH)], NBu₄[M(Q)₄] and [M(Q)₃(L)] (M = Eu or Tb; HQ = 1-phenyl-3-methyl-4-R-pyrazol-5-one: R = cyclopentylcarbonyl, HQ = HQ^CP; R = cyclopentylpropionyl, HQ = HQ^EtCP; L = 1,10-phenanthroline (phen) or 4,7-diphenyl-1,10-phenanthroline (bathophen)) are reported. The crystal structure of the tetrakis (β-diketonate) complex [NBu₄][Eu(Q^ETCP)₄] containing an eight-coordinated Eu atom in a distorted square antiprismatic environment has been determined. Luminescence studies have been performed on selected derivatives: the data suggested a strong influence of the nature of the acyl moiety in Q ligands and of Ph groups in bathophen (with respect to phen) on the luminescence properties.     

Asymmetric binuclear titanocenes linked by alkyl benzyl ethers: Synthesis, characterization and use as catalysts for ethylene polymerization

A series of novel asymmetric binuclear titanocenes linked with alkyl benzyl ethers p-[(C₅H₅TiCl₂)C₅H₄CH₂]C₆H₄O(CH₂)_n[C₅H₄(TiCl₂C₅H₅)] (n = 2-5) (13-16) have been synthesized by treating p-(LiC₅H₄CH₂)C₆H₄O(CH₂)_n(C₅H₄Li) (n = 2-5) (9-12) with C₅H₅TiCl₃. The new complexes have been characterized by elemental analysis and NMR spectra. Their catalytic activity for ethylene polymerization was investigated in the presence of aluminoxane (MAO). The results show that 13-16 are efficient catalysts for producing polyethylene (PE) with a broad molecular weight distribution (MWD). Their catalytic activity is highly dependent on the length of the alkyl chain and the polymerization conditions. A longer alkyl chain increases the catalytic activity, whereas the molecular weight of the produced polyethylene decreases.