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1. Conversion of butanol to propene in flow: A triple dehydration, isomerisation and metathesis cascade

Author

Yiping Shi, Andrew S. Weller, A. John Blacker, and Philip W. Dyer

Subjects
Butanol, Propene, Dehydration, Isomerisation, Cross-metathesis, Flow, Chemistry, QD1-999
Abstract

A combined three-step flow cascade conversion of n-butanol to propene is demonstrated. Zeolite H-ZSM-5 gives high conversion in the initial n-butanol dehydration step (98%). Subsequent isomerisation of terminal butenes to internal butenes over zeolite H-Fer takes place with good conversion (87%). Finally, cross-metathesis with ethene over a tungsten on acid-washed SiO2/Al2O3 catalyst affords propene with good selectivity (65%). Coupling these three steps into a single flow sheet gives an overall yield of 64% propene from n-BuOH. Ethene cross-metathesis catalyst performance was probed using 2-pentene as a model co-substrate giving good conversion (~90%) and moderate selectivity to butenes (67%).

Published
2022
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3. Polyphosphinoborane Block Copolymer Synthesis Using Catalytic Reversible Chain-Transfer Dehydropolymerization

Author

James J. Race, Alex Heyam, Matthew A. Wiebe, J. Diego‐Garcia Hernandez, Charlotte E. Ellis, Shixing Lei, Ian Manners, and Andrew S. Weller

Subjects
General Chemistry, General Medicine, Catalysis
Abstract

An amphiphilic block copolymer of polyphosphinoborane has been prepared by a mechanism-led strategy of the sequential catalytic dehydropolymerization of precursor monomers, H

Published
2022

4. Dehydropolymerization of H

Author

Claire N, Brodie, Lia, Sotorrios, Timothy M, Boyd, Stuart A, Macgregor, and Andrew S, Weller

Abstract

The dehydropolymerization of H

Published
2022

6. Ortho-aryl substituted DPEphos ligands: rhodium complexes featuring C–H anagostic interactions and B–H agostic bonds†

Author

Stuart MacGregor, Andrew S. Weller, James J. Race, Alex Heyam, Arron L. Burnage, Antonio J. Martínez-Martínez, and Timothy M. Boyd

Subjects
Agostic interaction, 010405 organic chemistry, Chemistry, Chemical shift, Aryl, chemistry.chemical_element, General Chemistry, 010402 general chemistry, 01 natural sciences, Borylation, 0104 chemical sciences, Rhodium, Metal, Crystallography, chemistry.chemical_compound, visual_art, visual_art.visual_art_medium, Proton NMR, Natural bond orbital
Abstract

The synthesis of new Schrock–Osborn Rh(i) pre-catalysts with ortho-substituted DPEphos ligands, [Rh(DPEphos-R)(NBD)][BArF4] [R = Me, OMe, iPr; ArF = 3,5-(CF3)2C6H3], is described. Along with the previously reported R = H variant, variable temperature 1H NMR spectroscopic and single-crystal X-ray diffraction studies show that these all have axial (C–H)⋯Rh anagostic interactions relative to the d8 pseudo square planar metal centres, that also result in corresponding downfield chemical shifts. Analysis by NBO, QTAIM and NCI methods shows these to be only very weak C–H⋯Rh bonding interactions, the magnitudes of which do not correlate with the observed chemical shifts. Instead, as informed by Scherer's approach, it is the topological positioning of the C–H bond with regard to the metal centre that is important. For [Rh(DPEphos–iPr)(NBD)][BArF4] addition of H2 results in a Rh(iii) iPr–C–H activated product, [Rh(κ3,σ-P,O,P-DPEphos-iPr′)(H)][BArF4]. This undergoes H/D exchange with D2 at the iPr groups, reacts with CO or NBD to return Rh(i) products, and reaction with H3B·NMe3/tert-butylethene results in a dehydrogenative borylation to form a complex that shows both a non-classical B–H⋯Rh 3c-2e agostic bond and a C–H⋯Rh anagostic interaction at the same metal centre., Rh(i) complexes of ortho-substituted DPEphos-R (R = H, Me, OMe, iPr) ligands show anagostic interactions; for R =iPr C–H activation/dehydrogenative borylation forms a product exhibiting both B–H/Rh 3c-2e agostic and C–H/Rh anagostic motifs.

Published
2021

7. A Series of Crystallographically Characterized Linear and Branched σ-Alkane Complexes of Rhodium: From Propane to 3-Methylpentane

Author

Graham J. Tizzard, Bengt E. Tegner, Tobias Krämer, Nicholas H. Rees, Arron L. Burnage, Stuart MacGregor, Antonio J. Martínez-Martínez, Alexander J. Bukvic, Heather Fish, Simon J. Coles, Alasdair I. McKay, Andrew S. Weller, and Mark R. Warren

Subjects
Alkane, chemistry.chemical_classification, Alkene, Ligand, Binding energy, Supramolecular chemistry, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Catalysis, 0104 chemical sciences, Hexane, chemistry.chemical_compound, Crystallography, Colloid and Surface Chemistry, chemistry, Propane, 3-Methylpentane
Abstract

Using solid-state molecular organometallic (SMOM) techniques, in particular solid/gas single-crystal to single-crystal reactivity, a series of σ-alkane complexes of the general formula [Rh(Cy2PCH2CH2PCy2)(ηn:ηm-alkane)][BArF4] have been prepared (alkane = propane, 2-methylbutane, hexane, 3-methylpentane; ArF = 3,5-(CF3)2C6H3). These new complexes have been characterized using single crystal X-ray diffraction, solid-state NMR spectroscopy and DFT computational techniques and present a variety of Rh(I)···H–C binding motifs at the metal coordination site: 1,2-η2:η2 (2-methylbutane), 1,3-η2:η2 (propane), 2,4-η2:η2 (hexane), and 1,4-η1:η2 (3-methylpentane). For the linear alkanes propane and hexane, some additional Rh(I)···H–C interactions with the geminal C–H bonds are also evident. The stability of these complexes with respect to alkane loss in the solid state varies with the identity of the alkane: from propane that decomposes rapidly at 295 K to 2-methylbutane that is stable and instead undergoes an acceptorless dehydrogenation to form a bound alkene complex. In each case the alkane sits in a binding pocket defined by the {Rh(Cy2PCH2CH2PCy2)}+ fragment and the surrounding array of [BArF4]− anions. For the propane complex, a small alkane binding energy, driven in part by a lack of stabilizing short contacts with the surrounding anions, correlates with the fleeting stability of this species. 2-Methylbutane forms more short contacts within the binding pocket, and as a result the complex is considerably more stable. However, the complex of the larger 3-methylpentane ligand shows lower stability. Empirically, there therefore appears to be an optimal fit between the size and shape of the alkane and overall stability. Such observations are related to guest/host interactions in solution supramolecular chemistry and the holistic role of 1°, 2°, and 3° environments in metalloenzymes.

Published
2021
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8. η2-Alkene Complexes of [Rh(PONOP-iPr)(L)]+ Cations (L = COD, NBD, Ethene). Intramolecular Alkene-Assisted Hydrogenation and Dihydrogen Complex [Rh(PONOP-iPr)(η-H2)]+

Author

Simon B. Duckett, Antonio J. Martínez-Martínez, Alice Johnson, Cameron G. Royle, Claire N. Brodie, and Andrew S. Weller

Subjects
chemistry.chemical_classification, 010405 organic chemistry, Hydride, Alkene, Norbornadiene, 010402 general chemistry, 01 natural sciences, Medicinal chemistry, Reductive elimination, 0104 chemical sciences, Inorganic Chemistry, chemistry.chemical_compound, chemistry, Cyclooctene, Forum Article, Dihydrogen complex, Physical and Theoretical Chemistry, Pincer ligand, Cyclooctadiene
Abstract

Rhodium-alkene complexes of the pincer ligand κ3-C5H3N-2,6-(OPiPr2)2 (PONOP-iPr) have been prepared and structurally characterized: [Rh(PONOP-iPr)(η2-alkene)][BArF4] [alkene = cyclooctadiene (COD), norbornadiene (NBD), ethene; ArF = 3,5-(CF3)2C6H3]. Only one of these, alkene = COD, undergoes a reaction with H2 (1 bar), to form [Rh(PONOP-iPr)(η2-COE)][BArF4] (COE = cyclooctene), while the others show no significant reactivity. This COE complex does not undergo further hydrogenation. This difference in reactivity between COD and the other alkenes is proposed to be due to intramolecular alkene-assisted reductive elimination in the COD complex, in which the η2-bound diene can engage in bonding with its additional alkene unit. H/D exchange experiments on the ethene complex show that reductive elimination from a reversibly formed alkyl hydride intermediate is likely rate-limiting and with a high barrier. The proposed final product of alkene hydrogenation would be the dihydrogen complex [Rh(PONOP-iPr)(η2-H2)][BArF4], which has been independently synthesized and undergoes exchange with free H2 on the NMR time scale, as well as with D2 to form free HD. When the H2 addition to [Rh(PONOP-iPr)(η2-ethene)][BArF4] is interrogated using pH2 at higher pressure (3 bar), this produces the dihydrogen complex as a transient product, for which enhancements in the 1H NMR signal for the bound H2 ligand, as well as that for free H2, are observed. This is a unique example of the partially negative line-shape effect, with the enhanced signals that are observed for the dihydrogen complex being explained by the exchange processes already noted., η2-Alkene complexes [Rh(PONOP-iPr)(η2-alkene)][BArF4] [alkene = cyclooctadiene (COD), norbornadiene (NBD), ethene] are reported, for which only the COD complex undergoes significant onward reaction with H2 to form a cyclooctene (COE) complex, the reactivity is which is suggested to be due to intramolecular alkene-assisted reductive elimination. The putative product of H2 addition, [Rh(PONOP-iPr)(η2-H2)][BArF4], is made by an alternative route. Remarkably, enhanced signals for this dihydrogen complex are observed when pH2 is added to [Rh(PONOP-iPr)(η2-ethene)][BArF4], a unique example of the partially negative line-shape effect.

Published
2021
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10. Single-Crystal to Single-Crystal Addition of H

Author

Cameron G, Royle, Lia, Sotorrios, Matthew R, Gyton, Claire N, Brodie, Arron L, Burnage, Samantha K, Furfari, Anna, Marini, Mark R, Warren, Stuart A, Macgregor, and Andrew S, Weller

Abstract

The reactivity of the Ir(I) PONOP pincer complex [Ir(

Published
2022

12. Amine–Borane Dehydropolymerization Using Rh-Based Precatalysts: Resting State, Chain Control, and Efficient Polymer Synthesis

Author

James J. Race, Timothy M. Boyd, Kori A. Andrea, David E. Ryan, Andrew S. Weller, and Guy C. Lloyd-Jones

Subjects
Resting state fMRI, 010405 organic chemistry, Cationic polymerization, chemistry.chemical_element, General Chemistry, Borane, 010402 general chemistry, 01 natural sciences, Medicinal chemistry, Catalysis, 0104 chemical sciences, Rhodium, chemistry.chemical_compound, chemistry, Amine gas treating, Phosphine
Abstract

A detailed study of H3B·NMeH2 dehydropolymerization using the cationic precatalyst [Rh(DPEphos)(H2BNMe3(CH2)2tBu)][BArF4] identifies the resting state as dimeric [Rh(DPEphos)H2]2 and boronium [H2B(NMeH2)2]+ as the chain-control agent. [Rh(DPEphos)H2]2 can be generated in situ from Rh(DPEphos)(benzyl) and catalyzes polyaminoborane formation (H2BNMeH)n [Mn = 15 000 g mol–1]. Closely related Rh(Xantphos)(benzyl) operates at 0.1 mol % to give a higher molecular weight polymer [Mn = 85 000 g mol–1] on the gram scale with low residual [Rh], 81 ppm. This insight offers a mechanistic template for dehydropolymerization.

Published
2020
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13. Solid–State Molecular Organometallic Catalysis in Gas/Solid Flow (Flow-SMOM) as Demonstrated by Efficient Room Temperature and Pressure 1-Butene Isomerization

Author

Samantha K. Furfari, Kongkiat Suriye, Antonio J. Martínez-Martínez, Cameron G. Royle, and Andrew S. Weller

Subjects
Materials science, Double bond, 1-butene, single-crystal to single-crystal, chemistry.chemical_element, 010402 general chemistry, Photochemistry, 01 natural sciences, Catalysis, isomerization, Rhodium, chemistry.chemical_compound, molecular organometallic, Organometallic chemistry, chemistry.chemical_classification, 010405 organic chemistry, 1-Butene, General Chemistry, 0104 chemical sciences, Temperature and pressure, Flow (mathematics), chemistry, rhodium, Isomerization, Research Article
Abstract

The use of solid-state molecular organometallic chemistry (SMOM-chem) to promote the efficient double bond isomerization of 1-butene to 2-butenes under flow-reactor conditions is reported. Single crystalline catalysts based upon the σ-alkane complexes [Rh(R2PCH2CH2PR2)(η2η2-NBA)][BArF4] (R = Cy, tBu; NBA = norbornane; ArF = 3,5-(CF3)2C6H3) are prepared by hydrogenation of a norbornadiene precursor. For the tBu-substituted system this results in the loss of long-range order, which can be re-established by addition of 1-butene to the material to form a mixture of [Rh(tBu2PCH2CH2PtBu2)(cis-2-butene)][BArF4] and [Rh(tBu2PCH2CH2PtBu2)(1-butene)][BArF4], in an order/disorder/order phase change. Deployment under flow-reactor conditions results in very different on-stream stabilities. With R = Cy rapid deactivation (3 h) to the butadiene complex occurs, [Rh(Cy2PCH2CH2PCy2)(butadiene)][BArF4], which can be reactivated by simple addition of H2. While the equivalent butadiene complex does not form with R = tBu at 298 K and on-stream conversion is retained up to 90 h, deactivation is suggested to occur via loss of crystallinity of the SMOM catalyst. Both systems operate under the industrially relevant conditions of an isobutene co-feed. cis:trans selectivites for 2-butene are biased in favor of cis for the tBu system and are more leveled for Cy.

Published
2020

14. A simple cobalt-based catalyst system for the controlled dehydropolymerisation of H3B·NMeH2 on the gram-scale

Author

David E. Ryan, Timothy M. Boyd, Katherine Baston, Kori A. Andrea, Andrew S. Weller, and Alice Johnson

Subjects
chemistry.chemical_classification, Materials science, Scale (ratio), 010405 organic chemistry, Metals and Alloys, chemistry.chemical_element, General Chemistry, Polymer, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Metal, chemistry, Chemical engineering, visual_art, Materials Chemistry, Ceramics and Composites, visual_art.visual_art_medium, Cobalt, Gram
Abstract

A simple Co(ii)-based amine-borane dehydropolymerisation catalyst system is reported that operates at low loadings, to selectively give (H2BNMeH)n polymer on scale, with catalyst control over Mn, narrow dispersities and low residual metal content.

Published
2020
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15. Si–C(sp3) bond activation through oxidative addition at a Rh(<scp>i</scp>) centre

Author

Antonio J. Martínez-Martínez, Miguel A. Huertos, Susan Azpeitia, Andrew S. Weller, and María A. Garralda

Subjects
Inorganic Chemistry, chemistry.chemical_compound, Chemistry, Cationic polymerization, Halide, Medicinal chemistry, Oxidative addition, Silane, Bond cleavage, Extractor
Abstract

An easy, direct and room temperature silicon-carbon bond activation is reported. The reaction of [RhCl(coe)2]2 with the silane Si(Me)2(o-C6H4SMe)2 in the presence of an halide extractor provokes a Si-CH3 bond cleavage yielding a cationic silyl-methyl-Rh(iii). In contrast, if the reaction is performed using the Rh(i) bis-alkene dimers, [RhCl(cod)]2 or [RhCl(nbd)]2, the Si-CH3 bond activation does not occur.

Published
2020
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17. Controlled Synthesis of Well-Defined Polyaminoboranes on Scale Using a Robust and Efficient Catalyst

Author

Claire N. Brodie, David E. Ryan, Lia Sotorríos, James S. Town, Eimear Magee, Stuart MacGregor, Timothy M. Boyd, Steven Huband, Andrew S. Weller, Guy C. Lloyd-Jones, and David M. Haddleton

Subjects
Chain propagation, Induction period, Norbornadiene, Chain transfer, General Chemistry, Biochemistry, Catalysis, chemistry.chemical_compound, Colloid and Surface Chemistry, Transfer agent, chemistry, Polymerization, Physical chemistry, Dehydrogenation, QD
Abstract

The air tolerant precatalyst, [Rh(L)(NBD)]Cl ([1]Cl) [L = κ3-(iPr2PCH2CH2)2NH, NBD = norbornadiene], mediates the selective synthesis of N-methylpolyaminoborane, (H2BNMeH)n, by dehydropolymerization of H3B·NMeH2. Kinetic, speciation, and DFT studies show an induction period in which the active catalyst, Rh(L)H3 (3), forms, which sits as an outer-sphere adduct 3·H3BNMeH2 as the resting state. At the end of catalysis, dormant Rh(L)H2Cl (2) is formed. Reaction of 2 with H3B·NMeH2 returns 3, alongside the proposed formation of boronium [H2B(NMeH2)2]Cl. Aided by isotopic labeling, Eyring analysis, and DFT calculations, a mechanism is proposed in which the cooperative “PNHP” ligand templates dehydrogenation, releasing H2B═NMeH (ΔG‡calc = 19.6 kcal mol–1). H2B═NMeH is proposed to undergo rapid, low barrier, head-to-tail chain propagation for which 3 is the catalyst/initiator. A high molecular weight polymer is formed that is relatively insensitive to catalyst loading (Mn ∼71 000 g mol–1; Đ, of ∼ 1.6). The molecular weight can be controlled using [H2B(NMe2H)2]Cl as a chain transfer agent, Mn = 37 900–78 100 g mol–1. This polymerization is suggested to arise from an ensemble of processes (catalyst speciation, dehydrogenation, propagation, chain transfer) that are geared around the concentration of H3B·NMeH2. TGA and DSC thermal analysis of polymer produced on scale (10 g, 0.01 mol % [1]Cl) show a processing window that allows for melt extrusion of polyaminoborane strands, as well as hot pressing, drop casting, and electrospray deposition. By variation of conditions in the latter, smooth or porous microstructured films or spherical polyaminoboranes beads (∼100 nm) result.

Published
2021
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18. Inverse Isotope Effects in Single-Crystal to Single-Crystal Reactivity and the Isolation of a Rhodium Cyclooctane σ-Alkane Complex

Author

Laurence R. Doyle, Martin R. Galpin, Samantha K. Furfari, Bengt E. Tegner, Antonio J. Martínez-Martínez, Adrian C. Whitwood, Scott A. Hicks, Guy C. Lloyd-Jones, Stuart A. Macgregor, and Andrew S. Weller

Subjects
Inorganic Chemistry, Organic Chemistry, Physical and Theoretical Chemistry
Abstract

The sequential solid/gas single-crystal to single-crystal reaction of [Rh(Cy2P(CH2)3PCy2)(COD)][BArF4] (COD = cyclooctadiene) with H2or D2was followed in situ by solid-state31P{1H} NMR spectroscopy (SSNMR) and ex situ by solution quenching and GC-MS. This was quantified using a two-step Johnson–Mehl–Avrami–Kologoromov (JMAK) model that revealed an inverse isotope effect for the second addition of H2, that forms a σ-alkane complex [Rh(Cy2P(CH2)3PCy2)(COA)][BArF4]. Using D2, a temporal window is determined in which a structural solution for this σ-alkane complex is possible, which reveals an η2,η2-binding mode to the Rh(I) center, as supported by periodic density functional theory (DFT) calculations. Extensive H/D exchange occurs during the addition of D2, as promoted by the solid-state microenvironment.

Published
2021
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19. Metathesis by Partner Interchange in σ-Bond Ligands: Expanding Applications of the σ-CAM Mechanism

Author

Sylviane Sabo-Etienne, Robin N. Perutz, and Andrew S. Weller

Subjects
Agostic interaction, Reaction mechanism, Chemistry, Homogeneous catalysis, General Medicine, General Chemistry, Borane, Metathesis, Catalysis, chemistry.chemical_compound, Oxidation state, Computational chemistry, Salt metathesis reaction
Abstract

In 2007 two of us defined the σ-Complex Assisted Metathesis mechanism (Perutz and Sabo-Etienne, Angew. Chem. Int. Ed. 2007 , 46 , 2578-2592), i.e. the σ-CAM concept. This new approach to reaction mechanisms brought together metathesis reactions involving the formation of a variety of metal-element bonds through partner-interchange of σ-bond complexes. The key concept that defines a σ-CAM process is a single transition state for metathesis that is connected by two intermediates that are σ-bond complexes while the oxidation state of the metal remains constant in precursor, intermediates and product. This mechanism is appropriate in situations where σ-bond complexes have been isolated or computed as well-defined minima. Unlike several other mechanisms, it does not define the nature of the transition state. In this review, we highlight advances in the characterization and dynamic rearrangements of σ-bond complexes, most notably alkane and zincane complexes, but also different geometries of silane and borane complexes. We set out a selection of catalytic and stoichiometric examples of the σ-CAM mechanism that are supported by strong experimental and/or computational evidence. We then draw on these examples to demonstrate that the scope of the σ-CAM mechanism has expanded to classes of reaction not envisaged in 2007 (additional s-bond ligands, agostic complexes, sp 2 -carbon, surfaces). Finally, we provide a critical comparison to alternative mechanisms for metathesis of metal-element bonds.

Published
2021

21. Reversible Encapsulation of Xenon and CH 2 Cl 2 in a Solid‐State Molecular Organometallic Framework (Guest@SMOM)

Author

Nicholas H. Rees, Andrew S. Weller, and Antonio J. Martínez-Martínez

Subjects
Solid-state chemistry, biology, 010405 organic chemistry, Solid-state, Active site, chemistry.chemical_element, General Chemistry, Nuclear magnetic resonance spectroscopy, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Encapsulation (networking), Rhodium, Crystallography, Xenon, chemistry, biology.protein
Abstract

Reversible encapsulation of CH 2 Cl 2 or Xe in a non–porous solid–state molecular organometallic framework of [Rh(Cy 2 PCH 2 PCy 2 )(NBD)][BAr F 4 ] occurs in single–crystal to single–crystal transformations. These processes are also probed by solid–state NMR spectroscopy, including 129 Xe SSNMR. Non–covalent interactions with the –CF 3 groups, and hydrophobic channels formed, of [BAr F 4 ] – anions are shown to be important, and thus have similarly to the transport of substrates and products to and from the active site in metalloenzymes.

Published
2019
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22. Cluster expansion and vertex substitution pathways in nickel germanide Zintl clusters

Author

Oliver P. E. Townrow, Andrew S. Weller, and Jose M. Goicoechea

Subjects
Substitution reaction, Ligand, Metals and Alloys, chemistry.chemical_element, General Chemistry, Electrochemistry, Catalysis, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Germanide, Crystallography, Nickel, chemistry.chemical_compound, chemistry, Cyclopentadienyl complex, Materials Chemistry, Ceramics and Composites, Cluster (physics), Reactivity (chemistry)
Abstract

We describe the reactivity of the hypersilyl-functionalized Zintl cluster salt K[Ge9(Hyp)3] towards the nickel reagents Ni(COD)2 and Ni(Cp)2, which gives rise to markedly different complexes. In the case of Ni(COD)2 (COD = 1,5-cyclooctadiene), a dianionic sandwich-like cluster [Ni{Ge9(Hyp)3}2]2− (1) was obtained, in line with a simple ligand substitution reaction of COD by [Ge9(Hyp)3]−. By contrast, when an analogous reaction with Ni(Cp)2 (Cp = cyclopentadienyl) was performed, vertex substitution of the [Ge9(Hyp)3]− precursor was observed, giving rise to the nine-vertex nido-cluster (Cp)Ni[Ge8(Hyp)3] (2). This is the first instance of vertex substitution at a hypersilyl-functionalized Zintl cluster cage. The electrochemical behavior of these compounds was explored and showed reversible redox behaviour for both clusters.

Published
2021

23. Selectivity of Rh⋅⋅⋅H−C Binding in a σ-Alkane Complex Controlled by the Secondary Microenvironment in the Solid State

Author

Stuart MacGregor, Alexander J. Bukvic, Samantha K. Furfari, Laurence R. Doyle, Arron L. Burnage, Bengt E. Tegner, and Andrew S. Weller

Subjects
Stereochemistry, Selectivity Control | Hot Paper, chemistry.chemical_element, 010402 general chemistry, 01 natural sciences, Catalysis, isomerization, Rhodium, chemistry.chemical_compound, periodic DFT, Norbornane, Alkane, chemistry.chemical_classification, Full Paper, 010405 organic chemistry, Ligand, Organic Chemistry, selectivity, Regioselectivity, General Chemistry, Full Papers, 0104 chemical sciences, chemistry, density functional calculations, rhodium, SMOM, Isomerization, Phosphine
Abstract

Single‐crystal to single‐crystal solid‐state molecular organometallic (SMOM) techniques are used for the synthesis and structural characterization of the σ‐alkane complex [Rh(tBu2PCH2CH2CH2PtBu2)(η2,η2‐C7H12)][BArF 4] (ArF=3,5‐(CF3)2C6H3), in which the alkane (norbornane) binds through two exo‐C−H⋅⋅⋅Rh interactions. In contrast, the bis‐cyclohexyl phosphine analogue shows endo‐alkane binding. A comparison of the two systems, supported by periodic DFT calculations, NCI plots and Hirshfeld surface analyses, traces this different regioselectivity to subtle changes in the local microenvironment surrounding the alkane ligand. A tertiary periodic structure supporting a secondary microenvironment that controls binding at the metal site has parallels with enzymes. The new σ‐alkane complex is also a catalyst for solid/gas 1‐butene isomerization, and catalyst resting states are identified for this., Importance of microenvironment: By using solid‐state molecular organometallic (SMOM) techniques, the σ‐alkane complex [Rh(tBu2PCH2CH2CH2PtBu2)(η2,η2‐C7H12)][BArF 4], in which the alkane binds through two exo‐C−H⋅⋅⋅Rh interactions, is synthesized and structurally characterized. This is different from the analogous complex with PCy2 groups. Subtle differences in the microenvironment, as encoded by the diene precursor complex, are shown to determine the selectivity of alkane binding.

Published
2021

24. A Neutral Heteroatomic Zintl Cluster for the Catalytic Hydrogenation of Cyclic Alkenes

Author

Cheuk Chung, Oliver P. E. Townrow, Jose M. Goicoechea, Andrew S. Weller, and Stuart MacGregor

Subjects
Chemistry, Communication, Homogeneous catalysis, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Catalysis, 0104 chemical sciences, Cyclic Alkenes, Colloid and Surface Chemistry, Polymer chemistry, Cluster (physics), Catalytic hydrogenation
Abstract

We report on the synthesis of an alkane-soluble Zintl cluster, [η4-Ge9(Hyp)3]Rh(COD), that can catalytically hydrogenate cyclic alkenes such as 1,5-cyclooctadiene and cis-cyclooctene. This is the first example of a well-defined Zintl-cluster-based homogeneous catalyst.

Published
2020

25. Tolerant to air σ-alkane complexes by surface modification of single crystalline solid-state molecular organometallics using vapour-phase cationic polymerisation : SMOM@polymer

Author

Hollie G Garwood, Antonio J. Martínez-Martínez, Andrew S. Weller, Thomas T. D. Chen, Dana Georgiana Crivoi, Alexander J. Bukvic, and Alasdair I. McKay

Subjects
Alkane, chemistry.chemical_classification, Materials science, Ethylene, Metals and Alloys, Cationic polymerization, General Chemistry, Polymer, Catalysis, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Metal, chemistry.chemical_compound, chemistry, Polymerization, visual_art, Polymer chemistry, Materials Chemistry, Ceramics and Composites, visual_art.visual_art_medium, Surface modification
Abstract

Vapour-phase surface-initiated cationic polymerisation of ethylvinylether occurs at single-crystals of the σ-alkane complex [Rh(Cy2PCH2CH2PCy2)(NBA)][BArF4]. This new surface interface makes these normally very air sensitive materials tolerant to air, while also allowing for onward single-crystal to single-crystal reactivity at metal sites within the lattice.

Published
2020

26. Computational Studies of the Solid-State Molecular Organometallic (SMOM) Chemistry of Rh s-Alkane Complexes

Author

Tobias Krämer, Andrés G. Algarra, Stuart MacGregor, Rachael E.M. Pirie, Arron L. Burnage, Andrew S. Weller, Bengt E. Tegner, and Marcella Iannuzzi

Subjects
chemistry.chemical_classification, Alkane, chemistry, Computational chemistry, Alkene, Solid-state, chemistry.chemical_element, Reactivity (chemistry), Periodic density functional theory, Catalysis, Rhodium
Abstract

A review of computational studies on the structures, bonding and reactivity of rhodium σ-alkane complexes in the solid state is presented. These complexes of the general form [(R2P(CH2)nPR2)Rh(alkane)][BArF4] (where ArF = 3,5-(CF3)2C6H3) are formed via solid/gas hydrogenation of alkene precursors, often in single-crystal-to-single-crystal (SC-SC) transformations. Molecular and periodic density functional theory (DFT) calculations complement experimental characterisation techniques (X-ray, solid-state NMR) to provide a detailed picture of the structure and bonding in these species. These σ-alkane complexes exhibit reactivity in the solid state, undergoing fluxional processes, and access different alkane binding modes that link to C-H activation and H/D exchange. The mechanisms of several of these processes have been defined using periodic DFT calculations which provide excellent quantitative agreement with the available experimental activation barriers. A comparison of computed results derived from periodic DFT calculations, where the full solid-state environment is taken into account, with simple model calculations using the isolated molecular cations highlights the importance of modelling the solid state to reproduce the structures of these alkane complexes. The solid-state environment can also have a significant impact on the computed reaction energetics.

Published
2020
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27. A structurally characterized cobalt(I) σ‐alkane complex

Author

Simon J. Coles, Graham J. Tizzard, Timothy M. Boyd, Michael A. Hayward, Samuel E. Neale, Stuart MacGregor, Andrew S. Weller, Bengt E. Tegner, and Antonio J. Martínez-Martínez

Subjects
Norbornadiene, chemistry.chemical_element, 010402 general chemistry, 01 natural sciences, single crystals, Catalysis, Rhodium, ACTIVATION, chemistry.chemical_compound, periodic density functional theory, General chemistry, Physics::Atomic and Molecular Clusters, Norbornane, Physics::Chemical Physics, alkane complexes, Organometallic chemistry, Cobalt Complexes | Very Important Paper, Alkane, chemistry.chemical_classification, 010405 organic chemistry, Chemistry, Ligand, Communication, General Medicine, General Chemistry, RHODIUM, cobalt, Communications, 0104 chemical sciences, X-ray diffraction, SINGLE-CRYSTAL, ORGANOMETALLIC CHEMISTRY, Crystallography, SOLID-STATE, Cobalt
Abstract

A cobalt σ‐alkane complex, [Co(Cy2P(CH2)4PCy2)(norbornane)][BArF 4], was synthesized by a single‐crystal to single‐crystal solid/gas hydrogenation from a norbornadiene precursor, and its structure was determined by X‐ray crystallography. Magnetic data show this complex to be a triplet. Periodic DFT and electronic structure analyses revealed weak C−H→Co σ‐interactions, augmented by dispersive stabilization between the alkane ligand and the anion microenvironment. The calculations are most consistent with a η1:η1‐alkane binding mode., A cobalt σ‐alkane complex was synthesized by a single‐crystal to single‐crystal solid/gas hydrogenation from a norbornadiene precursor, and its structure was determined by X‐ray crystallography. Periodic DFT and electronic structure analyses revealed weak C−H→Co σ‐interactions, augmented by dispersive stabilization between the alkane ligand and the anion microenvironment.

Published
2020

28. Iron Precatalysts with Bulky Tri( tert ‐butyl)cyclopentadienyl Ligands for the Dehydrocoupling of Dimethylamine‐Borane

Author

Joshua Turner, Amit Kumar, Ian Manners, Hazel A. Sparkes, Nicholas F. Chilton, Annie L. Colebatch, Andrew S. Weller, and George R. Whittell

Subjects
catalysis, iron catalysts, 010405 organic chemistry, Chemistry, boranes, amines, Organic Chemistry, Ab initio, Boranes, General Chemistry, Borane, 010402 general chemistry, 01 natural sciences, Medicinal chemistry, Catalysis, 0104 chemical sciences, law.invention, chemistry.chemical_compound, Cyclopentadienyl complex, law, Yield (chemistry), dehydrocoupling, Electron paramagnetic resonance, Dimethylamine
Abstract

In an attempt to prepare new Fe catalysts for the dehydrocoupling of amine-boranes and to provide mechanistic insight, the paramagnetic FeII dimeric complex [Cp′FeI]2 (1) (Cp′=η5-((1,2,4-tBu)3C5H2)) was used as a precursor to a series of cyclopentadienyl FeII and FeIII mononuclear species. The complexes prepared were [Cp′Fe(η6-Tol)][Cp′FeI2] (2) (Tol=C6H5Me), [Cp′Fe(η6-Tol)][BArF 4] (3) (BArF 4=[B(C6H3(m-CF3)2)4]−), [N(nBu)4][Cp′FeI2] (4), Cp′FeI2 (5), and [Cp′Fe(MeCN)3][BArF 4] (6). The electronic structure of the [Cp′FeI2]− anion in 2 and 4 was investigated by SQUID magnetometry, EPR spectroscopy and ab initio Complete Active Space Self Consistent Field-Spin Orbit (CASSCF-SO) calculations, and the studies revealed a strongly anisotropic S=2 ground state. Complexes 1–6 were investigated as catalysts for the dehydrocoupling of Me2NH⋅BH3 (I) in THF at 20 °C to yield the cyclodiborazane product [Me2N-BH2]2 (IV). Complexes 1–4 and 6 were active dehydrocoupling catalysts towards I (5 mol % loading), however 5 was inactive, and ultra-violet (UV) irradiation was required for the reaction mediated by 3. Complex 6 was found to be the most active precatalyst, reaching 80 % conversion to IV after 19 h at 22 °C. Dehydrocoupling of I by 1–4 proceeded via formation of the aminoborane Me2N=BH2 (II) as the major intermediate, whereas for 6 the linear diborazane Me2NH-BH2-NMe2-BH3 (III) could be detected, together with trace amounts of II. Reactions of 1 and 6 with Me3N⋅BH3 were investigated in an attempt to identify Fe-based intermediates in the catalytic reactions. The σ-complex [Cp′Fe(MeCN)(κ2-H2BH⋅NMe2H][BArF 4] was proposed to initially form in dehydrocoupling reactions involving 6 based on ESI-MS (ESI=Electrospray Ionisation Mass Spectroscopy) and NMR spectroscopic evidence. The latter also suggests that these complexes function as precursors to iron hydrides which may be the true catalytic species.

Published
2018
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29. A General, Rhodium-Catalyzed, Synthesis of Deuterated Boranes andN-Methyl Polyaminoboranes

Author

Annie L. Colebatch, Andrew S. Weller, Nicola L Oldroyd, Benjamin W. Hawkey Gilder, George R. Whittell, and Ian Manners

Subjects
H/D exchange, 010405 organic chemistry, Organic Chemistry, chemistry.chemical_element, dehydropolymerization, Boranes, General Chemistry, Borane, 010402 general chemistry, 01 natural sciences, Medicinal chemistry, Catalysis, 0104 chemical sciences, Rhodium, chemistry.chemical_compound, chemistry, Polymerization, Deuterium, rhodium, Isotopologue, deuterium, borane
Abstract

The rhodium complex [Rh(Ph2PCH2CH2CH2PPh2)(η6-FC6H5)][BArF 4], 2, catalyzes BH/BD exchange between D2 and the boranes H3B⋅NMe3, H3B⋅SMe2 and HBpin, facilitating the expedient isolation of a variety of deuterated analogues in high isotopic purities, and in particular the isotopologues of N-methylamine-borane: R3B⋅NMeR2 1-dx (R=H, D; x=0, 2, 3 or 5). It also acts to catalyze the dehydropolymerization of 1-dx to give deuterated polyaminoboranes. Mechanistic studies suggest a metal-based polymerization involving an unusual hybrid coordination insertion chain-growth/step-growth mechanism.

Published
2018
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30. Encapsulation of Crabtree's Catalyst in Sulfonated MIL‐101(Cr): Enhancement of Stability and Selectivity between Competing Reaction Pathways by the MOF Chemical Microenvironment

Author

Alexios Grigoropoulos, Alasdair I. McKay, Alexandros P. Katsoulidis, Robert P. Davies, Anthony Haynes, Lee Brammer, Jianliang Xiao, Andrew S. Weller, and Matthew J. Rosseinsky

Subjects
SINGLE-SITE CATALYSTS, Chemistry, Multidisciplinary, OXIDATION, 010402 general chemistry, 01 natural sciences, Metal–Organic Frameworks, allylic alcohols, Catalysis, Gas phase, chemistry.chemical_compound, METAL-ORGANIC FRAMEWORK, PRIMARY ALLYLIC ALCOHOLS, Crabtree's catalyst, PINCER COMPLEX, metal-organic frameworks, ISOMERIZATION, Science & Technology, 010405 organic chemistry, Chemistry, Communication, Organic Chemistry, OLEFIN HYDROGENATION, PORE ENVIRONMENT, General Medicine, General Chemistry, HETEROCYCLIC CARBENE LIGANDS, Communications, 0104 chemical sciences, HOMOGENEOUS CATALYSTS, Chemical engineering, Homogeneous, Physical Sciences, encapsulation, Metal-organic framework, hydrogenation, 03 Chemical Sciences, Selectivity, Isomerization
Abstract

Crabtree's catalyst was encapsulated inside the pores of the sulfonated MIL‐101(Cr) metal–organic framework (MOF) by cation exchange. This hybrid catalyst is active for the heterogeneous hydrogenation of non‐functionalized alkenes either in solution or in the gas phase. Moreover, encapsulation inside a well‐defined hydrophilic microenvironment enhances catalyst stability and selectivity to hydrogenation over isomerization for substrates bearing ligating functionalities. Accordingly, the encapsulated catalyst significantly outperforms its homogeneous counterpart in the hydrogenation of olefinic alcohols in terms of overall conversion and selectivity, with the chemical microenvironment of the MOF host favouring one out of two competing reaction pathways.

Published
2018
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31. A simple cobalt-based catalyst system for the controlled dehydropolymerisation of H

Author

Timothy M, Boyd, Kori A, Andrea, Katherine, Baston, Alice, Johnson, David E, Ryan, and Andrew S, Weller

Abstract

A simple Co(ii)-based amine-borane dehydropolymerisation catalyst system is reported that operates at low loadings, to selectively give (H2BNMeH)n polymer on scale, with catalyst control over Mn, narrow dispersities and low residual metal content.

Published
2019

32. Synthesis of highly fluorinated arene complexes of [Rh(chelating phosphine)]+ cations, and their use in synthesis and catalysis

Author

James Barwick-Silk, Michael C. Willis, Andrew S. Weller, Alasdair I. McKay, and Max Savage

Subjects
chemistry.chemical_element, 010402 general chemistry, 01 natural sciences, Aldehyde, Medicinal chemistry, Catalysis, Rhodium, chemistry.chemical_compound, fluoroarene, Tishchenko reaction, Reactivity (chemistry), chemistry.chemical_classification, Full Paper, catalysis, 010405 organic chemistry, Organic Chemistry, Cationic polymerization, phosphine, General Chemistry, Full Papers, Oxidative addition, 0104 chemical sciences, 3. Good health, chemistry, x-ray, rhodium, Catalysis | Hot Paper, Phosphine
Abstract

The synthesis of rhodium complexes with weakly binding highly fluorinated benzene ligands is described: 1,2,3‐F3C6H3, 1,2,3,4‐F4C6H2 and 1,2,3,4,5‐F5C6H are shown to bind with cationic [Rh(Cy2P(CH2)xPCy2)]+ fragments (x=1, 2). Their structures and reactivity with alkenes, and use in catalysis for promoting the Tishchenko reaction of a simple aldehyde, are demonstrated. Key to the synthesis of these complexes is the highly concentrated reaction conditions and use of the [Al{OC(CF3)3}4]− anion., Weakly binding highly fluorinated benzene ligands 1,2,3‐F3C6H3, 1,2,3,4‐F4C6H2 and 1,2,3,4,5‐F5C6H are shown to bind with cationic [Rh(Cy2P(CH2)xPCy2)]+ fragments (x=1, 2), and the resulting complexes have been used in synthesis and catalysis.

Published
2019

33. The role of neutral Rh(PONOP)H, free NMe

Author

E Anastasia K, Spearing-Ewyn, Nicholas A, Beattie, Annie L, Colebatch, Antonio J, Martinez-Martinez, Andrew, Docker, Timothy M, Boyd, Gregg, Baillie, Rachel, Reed, Stuart A, Macgregor, and Andrew S, Weller

Abstract

The σ-amine-borane pincer complex [Rh(PONOP)(η1-H3B·NMe3)][BArF4] [2, PONOP = κ3-NC5H3-2,6-(OPtBu2)2] is prepared by addition of H3B·NMe3 to the dihydrogen precursor [Rh(PONOP)(η2-H2)][BArF4], 1. In a similar way the related H3B·NMe2H complex [Rh(PONOP)(η1-H3B·NMe2H)][BArF4], 3, can be made in situ, but this undergoes dehydrocoupling to reform 1 and give the aminoborane dimer [H2BNMe2]2. NMR studies on this system reveal an intermediate neutral hydride forms, Rh(PONOP)H, 4, that has been prepared independently. 1 is a competent catalyst (2 mol%, ∼30 min) for the dehydrocoupling of H3B·Me2H. Kinetic, mechanistic and computational studies point to the role of NMe2H in both forming the neutral hydride, via deprotonation of a σ-amine-borane complex and formation of aminoborane, and closing the catalytic cycle by reprotonation of the hydride by the thus-formed dimethyl ammonium [NMe2H2]+. Competitive processes involving the generation of boronium [H2B(NMe2H)2]+ are also discussed, but shown to be higher in energy. Off-cycle adducts between [NMe2H2]+ or [H2B(NMe2H)2]+ and amine-boranes are also discussed that act to modify the kinetics of dehydrocoupling.

Published
2019

34. The role of neutral Rh(PONOP)H, free NMe2H, boronium and ammonium salts in the dehydrocoupling of dimethylamine-borane using the cationic pincer [Rh(PONOP)(η2-H2)]+ catalyst

Author

Stuart MacGregor, Andrew Docker, Nicholas A. Beattie, Rachel Reed, Timothy M. Boyd, Annie L. Colebatch, Andrew S. Weller, Gregg Baillie, E. Anastasia K. Spearing-Ewyn, and Antonio J. Martínez-Martínez

Subjects
010405 organic chemistry, Hydride, Dimer, Borane, 010402 general chemistry, 01 natural sciences, Medicinal chemistry, 0104 chemical sciences, Catalysis, Pincer movement, Inorganic Chemistry, chemistry.chemical_compound, Deprotonation, chemistry, Catalytic cycle, Dimethylamine
Abstract

The σ-amine-borane pincer complex [Rh(PONOP)(η1-H3B·NMe3)][BArF4] [2, PONOP = κ3-NC5H3-2,6-(OPtBu2)2] is prepared by addition of H3B·NMe3 to the dihydrogen precursor [Rh(PONOP)(η2-H2)][BArF4], 1. In a similar way the related H3B·NMe2H complex [Rh(PONOP)(η1-H3B·NMe2H)][BArF4], 3, can be made in situ, but this undergoes dehydrocoupling to reform 1 and give the aminoborane dimer [H2BNMe2]2. NMR studies on this system reveal an intermediate neutral hydride forms, Rh(PONOP)H, 4, that has been prepared independently. 1 is a competent catalyst (2 mol%, ∼30 min) for the dehydrocoupling of H3B·Me2H. Kinetic, mechanistic and computational studies point to the role of NMe2H in both forming the neutral hydride, via deprotonation of a σ-amine-borane complex and formation of aminoborane, and closing the catalytic cycle by reprotonation of the hydride by the thus-formed dimethyl ammonium [NMe2H2]+. Competitive processes involving the generation of boronium [H2B(NMe2H)2]+ are also discussed, but shown to be higher in energy. Off-cycle adducts between [NMe2H2]+ or [H2B(NMe2H)2]+ and amine-boranes are also discussed that act to modify the kinetics of dehydrocoupling.

Published
2019

35. Room temperature acceptorless alkane dehydrogenation from molecular σ-alkane complexes

Author

Nicholas H. Rees, Alexander J. Bukvic, Arron L. Burnage, Andrew S. Weller, Bengt E. Tegner, Stuart MacGregor, Antonio J. Martínez-Martínez, and Alasdair I. McKay

Subjects
Alkane, chemistry.chemical_classification, Hydrogen, Chemistry, chemistry.chemical_element, General Chemistry, 010402 general chemistry, Photochemistry, 01 natural sciences, Biochemistry, Endothermic process, Acceptor, Catalysis, Article, 0104 chemical sciences, Colloid and Surface Chemistry, Dehydrogenation
Abstract

The non-oxidative catalytic dehydrogenation of light alkanes via C-H activation is a highly endothermic process that generally requires high temperatures and/or a sacrificial hydrogen acceptor to overcome unfavorable thermodynamics. This is complicated by alkanes being such poor ligands, meaning that binding at metal centers prior to C-H activation is disfavored. We demonstrate that by biasing the pre-equilibrium of alkane binding, by using solid-state molecular organometallic chemistry (SMOM-chem), well-defined isobutane and cyclohexane σ-complexes, [Rh(Cy2PCH2CH2PCy2)(η: η-(H3C)CH(CH3)2][BArF4] and [Rh(Cy2PCH2CH2PCy2)(η: η-C6H12)][BArF4] can be prepared by simple hydrogenation in a solid/gas single-crystal to single-crystal transformation of precursor alkene complexes. Solid-gas H/D exchange with D2 occurs at all C-H bonds in both alkane complexes, pointing to a variety of low energy fluxional processes that occur for the bound alkane ligands in the solid-state. These are probed by variable temperature solid-state nuclear magnetic resonance experiments and periodic density functional theory (DFT) calculations. These alkane σ-complexes undergo spontaneous acceptorless dehydrogenation at 298 K to reform the corresponding isobutene and cyclohexadiene complexes, by simple application of vacuum or Ar-flow to remove H2. These processes can be followed temporally, and modeled using classical chemical, or Johnson-Mehl-Avrami-Kologoromov, kinetics. When per-deuteration is coupled with dehydrogenation of cyclohexane to cyclohexadiene, this allows for two successive KIEs to be determined [kH/kD = 3.6(5) and 10.8(6)], showing that the rate-determining steps involve C-H activation. Periodic DFT calculations predict overall barriers of 20.6 and 24.4 kcal/mol for the two dehydrogenation steps, in good agreement with the values determined experimentally. The calculations also identify significant C-H bond elongation in both rate-limiting transition states and suggest that the large kH/kD for the second dehydrogenation results from a pre-equilibrium involving C-H oxidative cleavage and a subsequent rate-limiting β-H transfer step.

Published
2019

36. A d

Author

Alice, Johnson, Antonio J, Martínez-Martínez, Stuart A, Macgregor, and Andrew S, Weller

Abstract

H3B·NMe3 σ-complexes of d8 [(L1)Rh][BArF4] and d10 [(L1)Ag][BArF4] (where L1 = 2,6-bis-[1-(2,6-diisopropylphenylimino)ethyl]pyridine) have been prepared and structurally characterised. Analysis of the molecular and electronic structures reveal important but subtle differences in the nature of the bonding in these σ-complexes, which differ only by the identity of the metal centre and the d-electron count. With Rh the amine-borane binds in an η2:η2 fashion, whereas at Ag the unsymmetrical {AgH3B·NMe3} unit suggests a structure lying between the η2:η2 and η1 extremes.

Published
2019

37. A d10 Ag(I) amine–borane σ-complex and comparison with a d8 Rh(I) analogue: structures on the η1 to η2:η2 continuum

Author

Antonio J. Martínez-Martínez, Stuart MacGregor, Alice Johnson, and Andrew S. Weller

Subjects
010405 organic chemistry, Borane, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, Inorganic Chemistry, Metal, chemistry.chemical_compound, Crystallography, chemistry, visual_art, Pyridine, visual_art.visual_art_medium, Amine gas treating, Continuum (set theory)
Abstract

H3B·NMe3 σ-complexes of d8 [(L1)Rh][BArF4] and d10 [(L1)Ag][BArF4] (where L1 = 2,6-bis-[1-(2,6-diisopropylphenylimino)ethyl]pyridine) have been prepared and structurally characterised. Analysis of the molecular and electronic structures reveal important but subtle differences in the nature of the bonding in these σ-complexes, which differ only by the identity of the metal centre and the d-electron count. With Rh the amine–borane binds in an η2:η2 fashion, whereas at Ag the unsymmetrical {Ag⋯H3B·NMe3} unit suggests a structure lying between the η2:η2 and η1 extremes.

Published
2019

38. Solvent-free anhydrous Li

Author

Antonio J, Martínez-Martínez and Andrew S, Weller

Abstract

A modified, convenient, preparation of solvent-free, anhydrous, Li+, Na+ and K+ salts of the ubiquitous [BArF4]- anion is reported, that involves a simple additional recrystallisation step. Anhydrous Na[BArF4], K[BArF4], and [Li(H2O)][BArF4], were characterised by single-crystal X-ray diffraction.

Published
2019

39. Dehydropolymerization of H

Author

Gemma M, Adams, David E, Ryan, Nicholas A, Beattie, Alasdair I, McKay, Guy C, Lloyd-Jones, and Andrew S, Weller

Subjects
amine−borane, DPEphos, rhodium, mechanism, dehydropolymerization, Research Article
Abstract

[Rh(κ2-PP-DPEphos){η2η2-H2B(NMe3)(CH2)2tBu}][BArF4] acts as an effective precatalyst for the dehydropolymerization of H3B·NMeH2 to form N-methylpolyaminoborane (H2BNMeH)n. Control of polymer molecular weight is achieved by variation of precatalyst loading (0.1–1 mol %, an inverse relationship) and use of the chain-modifying agent H2: with Mn ranging between 5 500 and 34 900 g/mol and Đ between 1.5 and 1.8. H2 evolution studies (1,2-F2C6H4 solvent) reveal an induction period that gets longer with higher precatalyst loading and complex kinetics with a noninteger order in [Rh]TOTAL. Speciation studies at 10 mol % indicate the initial formation of the amino–borane bridged dimer, [Rh2(κ2-PP-DPEphos)2(μ-H)(μ-H2BN=HMe)][BArF4], followed by the crystallographically characterized amidodiboryl complex [Rh2(cis-κ2-PP-DPEphos)2(σ,μ-(H2B)2NHMe)][BArF4]. Adding ∼2 equiv of NMeH2 in tetrahydrofuran (THF) solution to the precatalyst removes this induction period, pseudo-first-order kinetics are observed, a half-order relationship to [Rh]TOTAL is revealed with regard to dehydrogenation, and polymer molecular weights are increased (e.g., Mn = 40 000 g/mol). Speciation studies suggest that NMeH2 acts to form the precatalysts [Rh(κ2-DPEphos)(NMeH2)2][BArF4] and [Rh(κ2-DPEphos)(H)2(NMeH2)2][BArF4], which were independently synthesized and shown to follow very similar dehydrogenation kinetics, and produce polymers of molecular weight comparable with [Rh(κ2-PP-DPEphos){η2-H2B(NMe3)(CH2)2tBu}][BArF4], which has been doped with amine. This promoting effect of added amine in situ is shown to be general in other cationic Rh-based systems, and possible mechanistic scenarios are discussed.

Published
2019

40. Simultaneous Orthogonal Methods for the Real-Time Analysis of Catalytic Reactions

Author

Lars P. E. Yunker, Amelia V. Hesketh, Robin Theron, Indrek Pernik, Yang Wu, J. Scott McIndoe, and Andrew S. Weller

Subjects
010405 organic chemistry, Abundance (chemistry), Chemistry, Cationic polymerization, Hydroacylation, Infrared spectroscopy, chemistry.chemical_element, General Chemistry, 010402 general chemistry, Photochemistry, Mass spectrometry, 01 natural sciences, Decomposition, Catalysis, 0104 chemical sciences, Rhodium
Abstract

Continuous monitoring of catalyzed reactions using infrared spectroscopy (IR) measures the transformation of reactant into product, whereas mass spectrometry delineates the dynamics of the catalytically relevant species present at much lower concentrations, a holistic approach that provides mechanistic insight into the reaction components whose abundance spans 5 orders of magnitude. Probing reactions to this depth reveals entities that include precatalysts, resting states, intermediates, and also catalyst impurities and decomposition products. Simple temporal profiles that arise from this analysis aid discrimination between the different types of species, and a hydroacylation reaction catalyzed by a cationic rhodium complex is studied in detail to provide a test case for the utility of this methodology.

Published
2016
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41. A convenient route to a norbornadiene adduct of iridium with chelating phosphines, [Ir(R2PCH2CH2PR2)(NBD)][BAr4F] and a comparison of reactivity with H2 in solution and the solid–state

Author

F. Mark Chadwick, Nicholas Olliff, and Andrew S. Weller

Subjects
Denticity, 010405 organic chemistry, Chemistry, Hydride, Stereochemistry, Norbornadiene, Organic Chemistry, Cationic polymerization, chemistry.chemical_element, 010402 general chemistry, 01 natural sciences, Biochemistry, Medicinal chemistry, 0104 chemical sciences, Adduct, Inorganic Chemistry, chemistry.chemical_compound, Materials Chemistry, Iridium, Physical and Theoretical Chemistry, Single crystal, Phosphine
Abstract

The straightforward synthesis of two cationic iridium norbornadiene species bearing simple bidentate phosphines is reported [Ir(R 2 PCH 2 CH 2 PR 2 )(NBD)][ BAr 4 F ] [NBD = norbornadiene; R = t Bu, Cy; Ar F = 3,5–C 6 H 3 (CF 3 ) 2 ]. The hydrogenation of [Ir( t Bu 2 PCH 2 CH 2 P t Bu 2 )(NBD)][ BAr 4 F ] in the solution phase and in the solid state is described in which saturated (solution) or unsaturated (solid–state) dimeric species with bridging hydrides are formed. The solid–state structures, as determined by single crystal X-ray diffraction, of these dimeric species are also discussed.

Published
2016
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42. A Rhodium-Pentane Sigma-Alkane Complex: Characterization in the Solid State by Experimental and Computational Techniques

Author

Stuart MacGregor, F. Mark Chadwick, Andrew S. Weller, Marcella Iannuzzi, Tobias Krämer, Nicholas H. Rees, University of Zurich, and Weller, Andrew S

Subjects
10120 Department of Chemistry, computation, 1503 Catalysis, Stereochemistry, chemistry.chemical_element, 1600 General Chemistry, Crystal structure, 010402 general chemistry, 01 natural sciences, C−H activation, Catalysis, Rhodium, chemistry.chemical_compound, Molecular dynamics, General chemistry, 540 Chemistry, Spectroscopy, Alkane, chemistry.chemical_classification, 010405 organic chemistry, Chemistry, Communication, Alkane Complexes, General Chemistry, Communications, 0104 chemical sciences, sigma complexes, Pentane, rhodium, Physical chemistry, alkanes
Abstract

The pentane σ-complex [Rh{Cy2 P(CH2 CH2 )PCy2 }(η(2) :η(2) -C5 H12 )][BAr(F) 4 ] is synthesized by a solid/gas single-crystal to single-crystal transformation by addition of H2 to a precursor 1,3-pentadiene complex. Characterization by low temperature single-crystal X-ray diffraction (150 K) and SSNMR spectroscopy (158 K) reveals coordination through two Rh⋅⋅⋅H-C interactions in the 2,4-positions of the linear alkane. Periodic DFT calculations and molecular dynamics on the structure in the solid state provide insight into the experimentally observed Rh⋅⋅⋅H-C interaction, the extended environment in the crystal lattice and a temperature-dependent pentane rearrangement implicated by the SSNMR data.

Published
2016
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44. Back Cover: A Structurally Characterized Cobalt(I) σ‐Alkane Complex (Angew. Chem. Int. Ed. 15/2020)

Author

Michael A. Hayward, Samuel E. Neale, Simon J. Coles, Graham J. Tizzard, Bengt E. Tegner, Stuart MacGregor, Timothy M. Boyd, Antonio J. Martínez-Martínez, and Andrew S. Weller

Subjects
Alkane, chemistry.chemical_classification, Crystallography, Materials science, chemistry, INT, X-ray crystallography, chemistry.chemical_element, Cover (algebra), General Chemistry, Cobalt, Catalysis, Periodic density functional theory
Published
2020
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45. Modulation of σ-Alkane Interactions in [Rh(L

Author

Antonio J, Martínez-Martínez, Bengt E, Tegner, Alasdair I, McKay, Alexander J, Bukvic, Nicholas H, Rees, Graham J, Tizzard, Simon J, Coles, Mark R, Warren, Stuart A, Macgregor, and Andrew S, Weller

Abstract

Solid/gas single-crystal to single-crystal (SC-SC) hydrogenation of appropriate diene precursors forms the corresponding σ-alkane complexes [Rh(Cy

Published
2018

46. Amine-Borane Dehydropolymerization: Challenges and Opportunities

Author

Annie L, Colebatch and Andrew S, Weller

Subjects
amine–borane, catalysis, dehydrogenation, Concept, Inorganic Polymers | Reviews Showcase, dehydropolymerization, polyaminoborane, Concepts
Abstract

The dehydropolymerization of amine–boranes, exemplified as H2RB⋅NR′H2, to produce polyaminoboranes (HRBNR′H)n that are inorganic analogues of polyolefins with alternating main‐chain B−N units, is an area with significant potential, stemming from both fundamental (mechanism, catalyst development, main‐group hetero‐cross‐coupling) and technological (new polymeric materials) opportunities. This Concept article outlines recent advances in the field, covering catalyst development and performance, current mechanistic models, and alternative non‐catalytic routes for polymer production. The substrate scope, polymer properties and applications of these exciting materials are also outlined. Challenges and opportunities in the field are suggested, as a way of providing focus for future investigations.

Published
2018

47. Controlling structure and reactivity in cationic Solid–State Molecular OrganoMetallic (SMOM) systems using anion templating

Author

Andrew S. Weller, Tobias Krämer, Alasdair I. McKay, Antonio J. Martínez-Martínez, Hannah J. Griffiths, Nicholas H. Rees, Jordan B. Waters, and Stuart MacGregor

Subjects
010405 organic chemistry, Norbornadiene, Organic Chemistry, Solid-state, Cationic polymerization, chemistry.chemical_element, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, Catalysis, Ion, Inorganic Chemistry, chemistry.chemical_compound, Crystallography, chemistry, Octahedron, Reactivity (chemistry), Physical and Theoretical Chemistry, Boron
Abstract

The role that the supporting anion has on the stability, structure, and catalytic performance, in solid-state molecular organometallic systems (SMOM) based upon [Rh- (Cy2PCH2CH2PCy2)(η2 η2 -NBD)][BArX 4], [1-NBD][BArX 4], is reported (X = Cl, F, H; NBD = norbornadiene). The tetra-aryl borate anion is systematically varied at the 3,5-position, ArX= 3,5- X2C6H3, and the stability and structure in the solid-state compared with the previously reported [1-NBD][BArCF34] complex. Single-crystal X-ray crystallography shows that the three complexes have different packing motifs, in which the cation sits on the shared face of two parallelepipeds for [1- NBD][BArCl4], is surrounded by eight anions in a gyrobifastigium arrangement for [1-NBD][BArF 4], or the six anions show an octahedral cage arrangement in [1-NBD][BArH 4], similar to that of [1-NBD][BArCF34]. C−X···X−C contacts, commonly encountered in crystal-engineering, are suggested to be important in determining structure. Addition of H2 in a solid/gas reaction affords the resulting σ-alkane complexes, [Rh(Cy2PCH2CH2PCy2)(η2 η2 -NBA)][BArX 4] [1-NBA][BArX 4] (NBA = norbornane), which can then proceed to lose the alkane and form the zwitterionic, anion-coordinated, complexes. The relative rates at which hydrogenation and then decomposition of σ-alkane complexes proceed are shown to be anion dependent. [BArCF34] − promotes fast hydrogenation and an indefinitely stable σ-alkane complex. With [BArH 4] − hydrogenation is slow and the σ-alkane complex so unstable it is not observed. [BArCl4] − and [BArF 4] − promote intermediate reactivity profiles, and for [BArCl4] −, a single-crystal to single-crystal hydrogenation results in [1-NBA][BArCl4]. The molecular structure derived from X-ray diffraction reveals a σalkane complex in which the NBA fragment is bound through two exo Rh···H−C interactions-different from the endo selective binding observed with [1-NBA][BArCF34]. Periodic DFT calculations demonstrate that this selectivity is driven by the microenvironment dictated by the surrounding anions. [1-NBA][BArX 4] are catalysts for gas/solid 1-butene isomerization (298 K, 1 atm), and their activity can be directly correlated to the stability of the σ-alkane complex compared to the anion-coordinated decomposition products.

Published
2018
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48. Rh(DPEPhos)-catalyzed alkyne hydroacylation using β-carbonyl-substituted aldehydes: mechanistic insight leads to low catalyst loadings that enables selective catalysis on gram-scale

Author

Hardy Simon, James Barwick-Silk, Andrew S. Weller, and Michael C. Willis

Subjects
chemistry.chemical_classification, 010405 organic chemistry, Chemistry, Decarbonylation, Migratory insertion, Hydroacylation, Alkyne, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Combinatorial chemistry, Aldehyde, Oxidative addition, Catalysis, 0104 chemical sciences, Colloid and Surface Chemistry, Selectivity
Abstract

The detailed mechanism of the hydroacylation of β-amido-aldehyde, 2,2-dimethyl-3-morpholino-3-oxopropanal, with 1-octyne using [Rh(cis-κ2-P,P-DPEPhos)(acetone)2][BArF4]-based catalysts, is described [ArF = (CF3)2C6H3]. A rich mechanistic landscape of competing and interconnected hydroacylation and cyclotrimerization processes is revealed. An acyl-hydride complex, arising from oxidative addition of aldehyde, is the persistent resting state during hydroacylation, and quaternary substitution at the β-amido-aldehyde strongly disfavors decarbonylation. Initial rate, KIE, and labeling studies suggest that the migratory insertion is turnover-limiting as well as selectivity determining for linear/branched products. When the concentration of free aldehyde approaches zero at the later stages of catalysis alkyne cyclotrimerization becomes competitive, to form trisubstituted hexylarenes. At this point, the remaining acyl-hydride turns over in hydroacylation and the free alkyne is now effectively in excess, and the resting state moves to a metallacyclopentadiene and eventually to a dormant α-pyran-bound catalyst complex. Cyclotrimerization thus only becomes competitive when there is no aldehyde present in solution, and as aldehyde binds so strongly to form acyl-hydride when this happens will directly correlate to catalyst loading: with low loadings allowing for free aldehyde to be present for longer, and thus higher selectivites to be obtained. Reducing the catalyst loading from 20 mol % to 0.5 mol % thus leads to a selectivity increase from 96% to ∼100%. An optimized hydroacylation reaction is described that delivers gram scale of product, at essentially quantitative levels, using no excess of either reagent, at very low catalyst loadings, using minimal solvent, with virtually no workup.

Published
2018

49. Reactivity of an Unsaturated Iridium(III) Phosphoramidate Complex, [Cp*Ir{κ2-N,O}][BArF4]

Author

Laurel L. Schafer, Jennifer A. Love, Andrew S. Weller, Heather C. Johnson, and Marcus W. Drover

Subjects
010405 organic chemistry, Ligand, Stereochemistry, Organic Chemistry, Solid-state, chemistry.chemical_element, Phosphoramidate, Nuclear magnetic resonance spectroscopy, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, 3. Good health, Adduct, Inorganic Chemistry, chemistry, Reactivity (chemistry), Iridium, Lewis acids and bases, Physical and Theoretical Chemistry
Abstract

The three-legged piano stool complex [Cp*Ir(κ2-N,O-Xyl(N)P(O)(OEt)2)(Cl)], [1] (Cp* = η5-C5Me5, Xyl = 2,6-dimethylphenyl), was prepared from reaction of 0.5 equiv of [Cp*IrCl2]2 with the sodiated phosphoramidate ligand Na[Xyl(N)P(O)(OEt)2]. Treatment of [1] with Na[BArF4], [BArF4] = [B(C6H3(CF3)2)4], led to the formation of the 16-electron two-legged piano stool species [Cp*Ir(κ2-N,O-Xyl(N)P(O)(OEt)2)][BArF4], [2][BArF4], which was characterized in both solution and solid state. Reactivity screening revealed that complex [2][BArF4] undergoes addition of a variety of Lewis bases to afford the corresponding 18-electron adducts with concomitant movement of the phosphoramidate ligand from κ2-N,O to κ1-N, [Cp*Ir(κ1-N-Xyl(N)P(O)(OEt)2)(L)2][BArF4]; L = CNtBu, [3][BArF4], CNXyl, [4][BArF4], MeCN, [7][BArF4], bipy, [8][BArF4]; bipy = 2,2′-bipyridine. For complex [7][BArF4], variable-temperature 31P{1H} NMR spectroscopy revealed that MeCN coordination was reversible between 238 and 190 K. To probe E–H (E = Si, B) ...

Published
2015
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50. Rhodium-Catalyzed Selective Partial Hydrogenation of Alkynes

Author

J. Scott McIndoe, Laura J. Sewell, Thomas N. Hooper, Andrew S. Weller, Robin Theron, Jingwei Luo, and Allen G. Oliver

Subjects
chemistry.chemical_classification, 010405 organic chemistry, Chemistry, Alkene, Organic Chemistry, Fluorobenzene, chemistry.chemical_element, Alkyne, Hydroacylation, 010402 general chemistry, Photochemistry, 01 natural sciences, Medicinal chemistry, Oxidative addition, 0104 chemical sciences, Rhodium, Catalysis, Inorganic Chemistry, chemistry.chemical_compound, Deprotonation, Physical and Theoretical Chemistry
Abstract

The cationic rhodium complex [Rh(PcPr3)2(η6-PhF)]+[B{3,5-(CF3)2C6H3}4]− (PcPr3 = triscyclopropylphosphine, PhF = fluorobenzene) was used as a catalyst for the hydrogenation of the charge-tagged alkyne [Ph3P(CH2)4C2H]+[PF6]−. Pressurized sample infusion electrospray ionization mass spectrometry (PSI-ESI-MS) was used to monitor reaction progress. Experiments revealed that the reaction is first order in catalyst and first order in hydrogen, so under conditions of excess hydrogen the reaction is pseudo-zero order. Alkyne hydrogenation was 40 times faster than alkene hydrogenation. The turnover-limiting step is proposed to be oxidative addition of hydrogen to the alkyne (or alkene)-bound complex. Addition of triethylamine caused a dramatic reduction in rate, suggesting a deprotonation pathway was not operative.

Published
2015
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