Your search keyword '"Quyoum, R."' showing total 7 results

1. ChemInform Abstract: Heterogeneous Catalysis of C-C Bond Formation: Black Art or Organometallic Science?

Author

MAITLIS, P. M., primary, LONG, H. C., additional, QUYOUM, R., additional, TURNER, M. L., additional, and WANG, Z.-Q., additional

Published

2010

2. Towards a chemical understanding of the Fischer-Tropsch reaction: alkene formation

Author

Maitlis, P.M., Quyoum, R., Long, H.C., and Turner, M.L.

Published

1999

3. Ethylene, Styrene, and α-Methylstyrene Polymerization by Mono(pentamethylcyclopentadienyl) (Cp*) Complexes of Titanium, Zirconium, and Hafnium:  Roles of Cationic Complexes of the Type [Cp*MR<INF>2</INF>]<SUP>+</SUP> (R = Alkyl) as both Coordination Polymerization Catalysts and Carbocationic Polymerization Initiators

Author

Wang, Q., Quyoum, R., Gillis, D. J., Tudoret, M.-J., Jeremic, D., Hunter, B. K., and Baird, M. C.

Abstract

A variety of monocyclopentadienyl and mono(pentamethylcyclopentadienyl) complexes of titanium, zirconium, and hafnium are assessed for abilities to initiate polymerization of ethylene, styrene, and, in part, α-methylstyrene. In general, little or no activity was found for either neutral species of the types CpMMe3 and CpMMe2OR or for cationic 12- and 14-electron species of the types [CpMR2L]⁺ and [CpMR2L2]⁺, respectively (Cp = η⁵-cyclopentadienyl; R = alkyl; L = amine, phosphine ligands). In contrast, much better olefin polymerization initiators result from abstraction of a methyl carbanion from Cp*MMe3 (Cp* = η⁵-pentamethylcyclopentadienyl) by B(C6F5)3, a reaction which gives cationic, 10-electron species of the type “[Cp*MMe2][BMe(C6F5)3]”. Of these, the complex [Cp*TiMe2][BMe(C6F5)3] (A) is an excellent initiator or initiator precursor for the polymerization of ethylene and styrene, resulting in high yields respectively of high molecular weight polyethylene and atactic (a-PS) and/or syndiotactic polystyrene (s-PS), depending on conditions; the tacticity of purified s-PS, as judged by ¹³C{¹H} NMR spectroscopy, approaches 100%. While the polymerization of ethylene probably involves a classical Ziegler−Natta process, polymerization of styrene to s-PS and a-PS apparently involves respectively a Ziegler−Natta process and carbocationic initiation. High yields of essentially syndiotactic poly(α-methylstyrene) are obtained by utilizing the same initiator system, also apparently via a carbocationic process.

Published

1996

4. Synthesis and Characterization of the Series of d<SUP>0</SUP> Arene Complexes [Cp*MMe<INF>2</INF>(η<SUP>6</SUP>-arene)][MeB(C<INF>6</INF>F<INF>5</INF>)<INF>3</INF>] (M = Ti, Zr, Hf)

Author

Gillis, D. J., Quyoum, R., Tudoret, M.-J., Wang, Q., Jeremic, D., Roszak, A. W., and Baird, M. C.

Abstract

Treatment of the neutral trimethyl compounds Cp*MMe3 (M = Ti, Zr, Hf) with the highly electrophilic borane B(C6F5)3 in methylene chloride in the presence of various arenes results in methyl carbanion abstraction and coordination of the arene to form complexes of the type [Cp*MMe2(η⁶-arene)][MeB(C6F5)3] (M = Ti, Zr, Hf; arene = benzene, toluene, m- and p-xylene, anisole, styrene, mesitylene). Indications of relative metal−arene affinities have been gleaned from a variety of low-temperature ¹H NMR experiments, and it seems that both steric and electronic factors play significant roles in determining stabilities. The crystal and molecular structures of [Cp*HfMe2(η⁶-toluene)][MeB(C6F5)3] have been determined; as anticipated, there are no significant contacts between anion and cation, and the latter assumes a bent-metallocene type of structure.

Published

1996

5. ChemInform Abstract: Heterogeneous Catalysis of C-C Bond Formation: Black Art or Organometallic Science?

Author

MAITLIS, P. M., LONG, H. C., QUYOUM, R., TURNER, M. L., and WANG, Z.-Q.

Published

1996

6. Polymerization of norbornene and 1,5-hexadiene by [Cp^*TiMe~2][MeB(C~6F~5)~3]

Author

Jeremic, D., Wang, Q., Quyoum, R., and Baird, M. C.

Published

1995

7. Investigations by (13)C NMR spectroscopy of ethene-initiated catalytic CO hydrogenation.

Author

Turner ML, Marsih N, Mann BE, Quyoum R, Long HC, and Maitlis PM

Abstract

13C NMR spectroscopy shows that the n-alkene and n-alkane products from the catalytic hydrogenation of CO in the presence of (13)C(2)H(4) probes over Ru/150 degrees C, Co/180 degrees C, Fe/220 degrees C, or Rh/190 degrees C (1 atm, CO:H(2) 1:1, "mild conditions") contain terminal (13)CH(3)(13)CH(2)- units. This is consistent with their formation by a regiospecific polymerization of C(1) species derived from CO and initiated by (13)C(2)H(4). Although the activities toward individual products differed somewhat, similar distributions and similar product labeling patterns were obtained over all the four catalysts. 1-Butene and the higher 1-n-alkenes from all the catalysts were largely (13)CH(3)(13)CH(2)(CH(2))(n)()CH=CH(2) (n = 0-3), propene formed over Ru or Co was (13)CH(3)(13)CH=CH(2), while both (13)CH(3)(13)CH=CH(2) and (13)CH(2)=(13)CHCH(3) were formed over Fe or Rh. Comparison of the conclusions from these probe experiments with those from isotope transient experiments by other workers indicates that the ethene initiator does not significantly modify the course of the CO hydrogenation. The reaction products are largely kinetically determined, and the primary products are mainly linear 1-n-alkenes, while the n-alkanes and 2-n-alkenes largely arise via secondary processes. Since the distribution of products and the labeling in them is so similar, it is concluded that one basic primary mechanism applies over all the four metals. Several different reaction paths involving a polymerization of surface methylene, [CH(2(ad))], have been proposed. Although the predictions based on several of these mechanisms agree with many of the results, the alkenyl + [CH(2(ad))] mechanism, initiated by a surface vinyl [CH(2)=CH((ad))], most easily accommodates the experimental evidence. An alternative path involving sequential addition of surface methylidyne and hydride either to a growing alkylidene chain (alkylidene + [CH(ad) + H(ad)]) or to an alkyl chain (alkyl + [CH((ad)) + H(ad)]) has recently been proposed by van Santen and Ciobica. The [CH(2(ad))] mechanism offers an easier explanation for the formation of the various alkenes, the distribution of products, and of the initiation, while the [CH(ad) + H(ad)] mechanism can explain any n-alkanes formed as primary products and not derived from alkenes. At higher reaction temperatures over Ru and Co, considerable (13)C(1) incorporation (from natural abundance in the CO and from cleavage of the (13)C(2)H(4) probe) was found in all the hydrocarbons. Thus, at higher temperatures (13)C(1(ad)) in addition to (13)C(2(ad)) species participate in both chain growth and initiation. In summary, adsorbed CO is transformed very easily into surface C(1(ad)), probably [CH(2(ad))] in equilibrium with [CH((ad))+H(ad)], which act as the propagating species.

Published

2002