Jason C. Brady scite author profile

Cnt1-Y(1)-C(29)109.1 Cnt1-Y(1)-C(30) 99.9 Cnt1-Y(1)-C( 31) 110.0 Cnt2-Y(1)-C(29) 105.8 Cnt2-Y(1)-C(30) 120.4 Cnt2-Y(1)-C(31) 105.5 Cnt1-Y(1)-Cnt2 139.7 C(31)-Y(1)-C(29) 57.16(12) C(31)-Y(1)-C(30) 31.17(11) C(29)-Y(1)-C(30) 30.81(11) C(31)-Y(1)-C(5) 102.42(12) C(29)-Y(1)-C(5) 128.69(11) C(30)-Y(1)-C(5) 107.59(12) C(31)-Y(1)-C(19)109.30( 12) C( 29)-Y(1)-C(19) 85.11(11) C(30)-Y(1)-C(19) 109.14(11) C(5)-Y(1)-C(19) 143.26(10) C(31)-Y(1)-C(15) 132.59(12) C(29)-Y(1)-C(15) 115.45(12) C(30)-Y(1)-C(15) 140.62(12) C(5)-Y(1)-C(15) 111.76(11) C(19)-Y(1)-C(15) 31.58(10) C(31)-Y(1)-C(4) 132.65(12) C(29)-Y(1)-C(4) 131.07(11) C(30)-Y(1)-C(4) 126.93(12) C(5)-Y(1)-C(4) 31.54(10) C(19)-Y(1)-C(4) 117.56(10) C(15)-Y(1)-C(4) 89.52(11) C(31)-Y(1)-C(3) 128.11(12) C(29)-Y(1)-C(3) 101.26(12) C(30)-Y(1)-C(3) 106.46(12) C(5)-Y(1)-C(3) 51.55(10) C(19)-Y(1)-C(3) 115.35(11) C(15)-Y(1)-C(3) 99.09(11) C(4)-Y(1)-C(3) 30.61(9) C(31)-Y(1)-C(1) 83.24(12) S-13165.92( 10) C( 1550.57( 10) C( 31)-Y(1)-C( 16)114.39( 12) C( 29)-Y(1)-C( 16)132.37( 12) C( 30)-Y(1)-C( 16)139.88( 12) C( 5)-Y(1)-C( 16) 98.72( 11) C( 19)-Y(1)-C( 16) 51.44( 10) C( 15)-Y(1)-C(16) 30.81(10) C(4)-Y(1)-C(16) 90.81(11) C(3)-Y(1)-C(16) 113.62(11) C(1)-Y(1)-C(16) 130.01(10) C(31)-Y(1)-C(17) 85.42(12) C(29)-Y(1)-C(17) 109.26(12) C(30)-Y(1)-C(17) 109.50(12) C(5)-Y(1)-C(17) 115.62(10) C(19)-Y(1)-C(17) 51.12(10) C(15)-Y(1)-C(17) 50.76(11) C(4)-Y(1)-C(17) 118.74(11) C(3)-Y(1)-C(17) 144.04(11) C(1)-Y(1)-C(17) 139.11(10) C(16)-Y(1)-C(17) 30.43(11) C(31)-Y(1)-C(18) 82.19(12) C(29)-Y(1)-C(18) 82.35(11) C(30)-Y(1)-C(18) 93.71(11) C(5)-Y(1)-C(18) 146.04(10) C(19)-Y(1)-C(18) 31.07(10) C(15)-Y(1)-C(18) 51.21(11) C(4)-Y(1)-C(18) 139.33(10) C(3)-Y(1)-C(18) 146.33(10) C(1)-Y(1)-C(18) 162.99(10) C(16)-Y(1)-C(18) 50.66(10) S-14 C(17)-Y(1)-C(18) 30.54(10) C(31)-Y(1)-C(2) 97.73(12) C(29)-Y(1)-C(2) 82.71(11) C(30)-Y(1)-C(2) 78.16(12) C(5)-Y(1)-C(2) 51.51(10) C(19)-Y(1)-C(2) 137.44(10) C(15)-Y(1)-C(2) 129.14(11) C(4)-Y(1)-C(2) 50.64(10) C(3)-Y(1)-C(2) 30.41(10) C(1)-Y(1)-C(2) 30.39(10) C(16)-Y(1)-C(2) 141.30(11) C(17)-Y(1)-C(2) 167.11(10) C(18)-Y(1)-C(2) 162.19(10) C(10)-Si(1)-C(5) 114.00(16) C(10)-Si(1)-C(11) 107.78(19) C(5)-Si(1)-C(11) 111.96(18) C(10)-Si(1)-C(12) 104.74(18) C(5)-Si(1)-C(12) 108.65(17) C(11)-Si(1)-C(12) 109.41(19) C(25)-Si(2)-C(19) 114.72(17) C(25)-Si(2)-C(26) 106.85(19) C(19)-Si(2)-C(26) 108.41(18) C(25)-Si(2)-C(24) 106.1(2) C(19)-Si(2)-C(24) 111.71(18) C(26)-Si(2)-C(24) 108.8(2)73.5(2) S-15 C(7)-C(2)-Y(1) 124.3(2) C(4)-C(3)-C(2) 109.2(3) C(4)-C(3)-C(8) 125.2(3) C(2)-C(3)-C(8) 125.2(3) C(4)-C(3)-Y(1) 74.3(2) C(2)-C(3)-Y(1) 76.4(2) C(8)-C(3)-Y(1) 121.9(2) C(3)-C(4)-C(5) 108.3(3) C(3)-C(4)-C(9) 124.7(3) C(5)-C(4)-C(9) 126.1(3) C(3)-C(4)-Y(1) 75.1(2) C(5)-C(4)-Y(1) 73.4(2) C(9)-C(4)-Y(1) 125.9(2) C(4)-C(5)-C(1) 106.0(3) C(4)-C(5)-Si(1) 129.4(3) C(1)-C(5)-Si(1) 123.0(2) C(4)-C(5)-Y(1) 75.1(2) C(1)-C(5)-Y(1) 75.7(2) Si(1)-C(5)-Y(1) 125.95(17) C(13)-C(12)-Si(1) 110.6(3) C(14)-C(13)-C(12) 126.2(4) C(16)-C(15)-C(19) 107.9(3) C(16)-C(15)-C(20) 125.6(3) C(19)-C(15)-C(20) 125.7(3) C(16)-C(15)-Y(1) 7...

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Tethered Olefin Studies of Alkene versus Tetraphenylborate Coordination and Lanthanide Olefin Interactions in Metallocenes

Evans

Perotti

Brady

et al. 2003

J. Am. Chem. Soc.

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The tethered olefin cyclopentadienyl ligand, [(C(5)Me(4))SiMe(2)(CH(2)CH=CH(2))](-), forms unsolvated metallocenes, [(C(5)Me(4))SiMe(2)(CH(2)CH=CH(2))](2)Ln (Ln = Sm, 1; Eu, 2; Yb, 3), from [(C(5)Me(4))SiMe(2)(CH(2)CH=CH(2))]K and LnI(2)(THF)(2) in good yield. Each complex in the solid state has both tethered olefins oriented toward the Ln metal center with the Ln-C(terminal alkene carbon) distances 0.2-0.3 A shorter than the Ln-C(internal alkene carbon) distances. The olefinic C-C bond distances in 2 and 3, 1.328(4) and 1.328(5) A, respectively, are normal. Like its permethyl analogue, (C(5)Me(5))(2)Sm(THF)(2), complex 1 reductively couples CO(2) to form the oxalate-bridged dimer [[(C(5)Me(4))SiMe(2)(CH(2)CH=CH(2))](2)Sm](2)(mu-eta(2):eta(2)-O(2)CCO(2)), 4, in which the tethered olefins are noninteracting substituents. Complex 1 reacts with AgBPh(4) to form an unsolvated cation that has the option of coordinating [BPh(4)](-) or a pendant olefin, a competition common in olefin polymerization catalysis. The structure of [[(C(5)Me(4))SiMe(2)(CH(2)CH=CH(2))](2)Sm][BPh(4)], 5, shows that both pendant olefins are located near samarium rather than the [BPh(4)](-) counterion.

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Double Deprotonation of a Cyclopentadienyl Alkene to Form a Polydentate Trianionic Cyclopentadienyl Allyl Ligand System

2001

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An important part of the evolution of metallocene chemistry and metallocene-based polymerization chemistry has been the development of cyclopentadienyl ligands to which other donor functionalities have been attached. [1][2][3][4][5][6][7][8][9][10][11][12][13][14] Ligand systems have been designed which involve monoanionic cyclopentadienides attached to neutral ether, amine, and hydrocarbon groups as well as dianionic ansa ligands in which the cyclopentadienide is attached to another anionic donor such as a cyclopentadienide or amide.

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Flexibility in the Coordination Chemistry of the 2,3-Dimethylindolide Ligand with Potassium, Yttrium, and Samarium

Evans

Brady

2002

Inorg. Chem.

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The coordination chemistry of the 2,3-dimethylindolide anion (DMI), (Me(2)C(8)H(4)N)(-), with potassium, yttrium, and samarium ions is described. In the potassium salt [K(DMI)(THF)](n), 1, prepared from Me(2)C(8)H(4)NH and KH in THF, the dimethylindole anion binds and bridges potassium ions in three different binding modes, namely eta(1), eta(3), and eta(5), to form a two-dimensional extended structure. In the dimethoxyethane (DME) adduct [K(DMI)(DME)(2)](2), 2, prepared by crystallizing a sample of 1 from DME, DMI exists as a mu-eta(1):eta(1) ligand. Compound 1 reacts with SmI(2)(THF)(4) in THF to form the distorted octahedral complex trans-(DMI)(2)Sm(THF)(4), 3, in which the dimethyindolide anions are bound in the eta(1) mode to samarium. Reaction of 2,3-dimethylindole with Y(CH(2)SiMe(3))(3)(THF)(2) afforded the amide complex (DMI)(3)Y(THF)(2), 4, in which the dimethylindolide anions are also bound in the eta(1) mode to yttrium. Compound 1 also reacts with (C(5)Me(5))(2)LnCl(2)K(THF)(2) (Ln = Sm, Y) to form unsolvated amide complexes (C(5)Me(5))(2)Ln(DMI) (Ln = Sm, 5; Y, 6), in which DMI attaches primarily through nitrogen, although the edge of the arene ring is oriented toward the metals at long distances.

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The bent metallocene geometries of potassium polyalkyl cyclopentadienyl THF solvates: monosolvated [(THF)K(μ-C5Me5)]n, disolvated [(THF)2K(μ-C5Me5)]n and the tethered olefin complex [(THF)K(μ-C5Me4SiMe2CH2CHCH2)]n

Evans

Brady

Fujimoto

et al. 2002

Journal of Organometallic Chemistry

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Jason C. Brady

Metallocene Allyl Reactivity in the Presence of Alkenes Tethered to Cyclopentadienyl Ligands

Tethered Olefin Studies of Alkene versus Tetraphenylborate Coordination and Lanthanide Olefin Interactions in Metallocenes

Double Deprotonation of a Cyclopentadienyl Alkene to Form a Polydentate Trianionic Cyclopentadienyl Allyl Ligand System

Flexibility in the Coordination Chemistry of the 2,3-Dimethylindolide Ligand with Potassium, Yttrium, and Samarium

The bent metallocene geometries of potassium polyalkyl cyclopentadienyl THF solvates: monosolvated [(THF)K(μ-C5Me5)]n, disolvated [(THF)2K(μ-C5Me5)]n and the tethered olefin complex [(THF)K(μ-C5Me4SiMe2CH2CHCH2)]n

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