Your search keyword '"Ahlquist MSG"' showing total 27 results

1. Intermolecular O-O Bond Formation between High-Valent Ru-oxo Species.

Author

Liu T, Zhan S, Zhang B, Wang L, Shen N, Ahlquist MSG, Fan X, and Sun L

Abstract

Despite extensive research on water oxidation catalysts over the past few decades, the relationship between high-valent metal-oxo intermediates and the O-O bond formation pathway has not been well clarified. Our previous study showed that the high spin density on O in Ru V =O is pivotal for the interaction of two metal-oxyl radical (I2M) pathways. In this study, we found that introducing an axially coordinating ligand, which is favorable for bimolecular coupling, into the Ru-pda catalyst can rearrange its geometry. The shifts in geometric orientation altered its O-O bond formation pathway from water nucleophilic attack (WNA) to I2M, resulting in a 70-fold increase in water oxidation activity. This implies that the I2M pathway is concurrently influenced by the spin density on oxo and the geometry organization of the catalysts. The observed mechanistic switch and theoretical studies provide insights into controlling reaction pathways for homogeneous water oxidation catalysis.

Published

2024

2. Removing the Barrier in O-O Bond Formation Via the Combination of Intramolecular Radical Coupling and the Oxide Relay Mechanism.

Author

de Gracia Triviño JA and Ahlquist MSG

Abstract

The Ru(tda) catalyst has been a major milestone in the development of molecular water oxidation catalysts due to its outstanding performance at neutral pH. The role of the noncoordinating carboxylate group is to act as a nucleophile, donating an oxygen atom to the oxo group, thereby acting as an oxide relay (OR) mechanism for O-O bond formation. A substitution of the carboxylates for phosphonate groups has been proposed, resulting in the Ru(tPaO) catalyst, which has shown even more efficient performance in experimental characterization. In this study, we explore the feasibility of the OR mechanism in the newly reported Ru(tPaO) molecular catalyst. We investigated the catalytic cycle using density functional theory and identified a variation of the OR mechanism that involves radical oxygen atoms in O-O bond formation. We have also determined that the subsequent hydroxide nucleophilic attack is the sole rate-limiting step in the catalytic cycle. All activation free energies are very low, with a free-energy barrier of 2.1 kcal/mol for O-O bond formation and 4.2 kcal/mol for OH - nucleophilic attack.

Published

2024

3. The Effect of Conformational Freedom vs Restriction on the Rate in Asymmetric Hydrogenation: Iridium-Catalyzed Regio- and Enantioselective Monohydrogenation of Dienones.

Author

Zheng J, Peters BBC, Jiang W, Suàrez LA, Ahlquist MSG, Singh T, and Andersson PG

Abstract

Transition metal-catalyzed asymmetric hydrogenation constitutes an efficient strategy for the preparation of chiral molecules. When dienes are subjected to hydrogenation, control over regioselectivity still presents a large challenge and the fully saturated alkane is often yielded. A few successful monohydrogenations of dienes have been reported, but hitherto these are only efficient for dienes comprised of two distinctly different olefins. Herein, the reactivity of a conjugated carbonyl compound as a function of their conformational freedom is studied, based on a combined experimental and theoretical approach. It was found that alkenes in the (s)-cis conformation experience a large rate acceleration while (s)-trans restrained alkenes undergo hydrogenation slowly. Ultimately, this reactivity aspect was exploited in a novel method for the monohydrogenation of dienes based on conformational restriction ((s)-cis vs (s)-trans). This mode of discrimination conceptually differs from existing monohydrogenations and dienones constructed of two olefins similar in nature could efficiently be hydrogenated to the chiral alkene (up to 99 % ee). The extent of regioselection is even powerful enough to overcome the conventional reactivity order of substituted olefins (di>tri>tetra). This high yielding and atom-economical protocol provides an interesting opportunity to instal a stereogenic center on a carbocycle, while leaving a synthetically useful alkene untouched., (© 2023 The Authors. Chemistry - A European Journal published by Wiley-VCH GmbH.)

Published

2024

4. O-O bond formation via radical coupling in a dinuclear iron water oxidation catalyst with high catalytic activity.

Author

Li G and Ahlquist MSG

Abstract

The use of iron-based catalysts for the water oxidation reaction is highly attractive due to the high abundance of iron. While many molecular catalysts have been made, most show limited activity and short lifetimes. An exception with higher activity was presented by Thummel and co-workers in 2015. Herein we present a study on the feasibility of the coupling of two O centered radicals originating from the two subunits of the dinuclear catalyst. The reaction pathway includes the oxidation to the active species Fe IV -O-Fe IV but avoids further high potential oxidations which previous mechanistic proposals have relied on.

Published

2024

5. Development and mechanistic investigation of the dehydrogenation of alcohols with an iron(III) salen catalyst.

Author

Hansen NSB, Monda F, Bro FS, Liu X, Ahlquist MSG, and Madsen R

Abstract

The iron(III) salen complex ( R , R )- N , N '-bis(salicylidene)-1,2-cyclohexanediamineiron(III) chloride has been developed as a catalyst for the acceptorless dehydrogenation of alcohols. The complex catalyzes the direct synthesis of imines in good yields from different primary alcohols and amines with the liberation of hydrogen gas. The mechanism has been investigated experimentally with labelled substrates and theoretically with density functional theory calculations. In contrast to the corresponding manganese(III) salen-catalyzed dehydrogenation, it has not been possible to identify a homogeneous catalytic pathway with the iron complex. Instead, poisoning experiments with trimethylphosphine and mercury indicated that the catalytically active species are heterogeneous small iron particles.

Published

2023

6. Bioinspired Active Site with a Coordination-Adaptive Organosulfonate Ligand for Catalytic Water Oxidation at Neutral pH.

Author

Liu T, Zhan S, Shen N, Wang L, Szabó Z, Yang H, Ahlquist MSG, and Sun L

Abstract

Many enzymes use adaptive frameworks to preorganize substrates, accommodate various structural and electronic demands of intermediates, and accelerate related catalysis. Inspired by biological systems, a Ru-based molecular water oxidation catalyst containing a configurationally labile ligand [2,2':6',2″-terpyridine]-6,6″-disulfonate was designed to mimic enzymatic framework, in which the sulfonate coordination is highly flexible and functions as both an electron donor to stabilize high-valent Ru and a proton acceptor to accelerate water dissociation, thus boosting the catalytic water oxidation performance thermodynamically and kinetically. The combination of single-crystal X-ray analysis, various temperature NMR, electrochemical techniques, and DFT calculations was utilized to investigate the fundamental role of the self-adaptive ligand, demonstrating that the on-demand configurational changes give rise to fast catalytic kinetics with a turnover frequency (TOF) over 2000 s -1 , which is compared to oxygen-evolving complex (OEC) in natural photosynthesis.

Published

2023

7. Computational comparison of Ru(bda)(py) 2 and Fe(bda)(py) 2 as water oxidation catalysts.

Author

Li G and Ahlquist MSG

Subjects

Carboxylic Acids, Catalysis, Ferric Compounds, Models, Molecular, Water, Ruthenium

Abstract

Ru(bda)(py) 2 (bda = 2,2'-bipyridine-6,6'-dicarboxylate, py = pyridine) has been a significant milestone in the development of water oxidation catalysts. Inspired by Ru(bda)(py) 2 and aiming to reduce the use of noble metals, iron (Fe) was introduced to replace the Ru catalytic center in Ru(bda)(py) 2 . In this study, density functional theory (DFT) calculations were performed on Fe- and Ru(bda)(py) 2 catalysts, and a more stable 6-coordinate Fe(bda)(py) 2 with one carboxylate group of bda disconnecting with Fe was found. For the first time, theoretical comparisons have been conducted on these three catalysts to compare their catalytic performances, such as reduction potentials and energy profiles of the radical coupling process. Explanations for the high potential of [Fe III (bda)(py) 2 -H 2 O] + and reactivity of [Fe V (bda)(py) 2 -O] + have been provided. This study can provide insights on Fe(bda)(py) 2 from a computational perspective if it is utilized as a water oxidation catalyst.

Published

2022

8. Promoting Proton Transfer and Stabilizing Intermediates in Catalytic Water Oxidation via Hydrophobic Outer Sphere Interactions.

Author

Liu T, Li G, Shen N, Wang L, Timmer BJJ, Kravchenko A, Zhou S, Gao Y, Yang Y, Yang H, Xu B, Zhang B, Ahlquist MSG, and Sun L

Subjects

Catalysis, Humans, Kinetics, Oxidation-Reduction, Protons, Water chemistry

Abstract

The outer coordination sphere of metalloenzyme often plays an important role in its high catalytic activity, however, this principle is rarely considered in the design of man-made molecular catalysts. Herein, four Ru-bda (bda=2,2'-bipyridine-6,6'-dicarboxylate) based molecular water oxidation catalysts with well-defined outer spheres are designed and synthesized. Experimental and theoretical studies showed that the hydrophobic environment around the Ru center could lead to thermodynamic stabilization of the high-valent intermediates and kinetic acceleration of the proton transfer process during catalytic water oxidation. By this outer sphere stabilization, a 6-fold rate increase for water oxidation catalysis has been achieved., (© 2022 The Authors. Chemistry - A European Journal published by Wiley-VCH GmbH.)

Published

2022

9. Microscopic Insights into Cation-Coupled Electron Hopping Transport in a Metal-Organic Framework.

Author

Castner AT, Su H, Svensson Grape E, Inge AK, Johnson BA, Ahlquist MSG, and Ott S

Subjects

Cations, Electron Transport, Electrons, Oxidation-Reduction, Metal-Organic Frameworks chemistry

Abstract

Electron transport through metal-organic frameworks by a hopping mechanism between discrete redox active sites is coupled to diffusion-migration of charge-balancing counter cations. Experimentally determined apparent diffusion coefficients, D e app , that characterize this form of charge transport thus contain contributions from both processes. While this is well established for MOFs, microscopic descriptions of this process are largely lacking. Herein, we systematically lay out different scenarios for cation-coupled electron transfer processes that are at the heart of charge diffusion through MOFs. Through systematic variations of solvents and electrolyte cations, it is shown that the D e app for charge migration through a PIZOF-type MOF, Zr(dcphOH-NDI) that is composed of redox-active naphthalenediimide (NDI) linkers, spans over 2 orders of magnitude. More importantly, however, the microscopic mechanisms for cation-coupled electron propagation are contingent on differing factors depending on the size of the cation and its propensity to engage in ion pairs with reduced linkers, either non-specifically or in defined structural arrangements. Based on computations and in agreement with experimental results, we show that ion pairing generally has an adverse effect on cation transport, thereby slowing down charge transport. In Zr(dcphOH-NDI), however, specific cation-linker interactions can open pathways for concerted cation-coupled electron transfer processes that can outcompete limitations from reduced cation flux.

Published

2022

10. Combined Theoretical and Experimental Studies Unravel Multiple Pathways to Convergent Asymmetric Hydrogenation of Enamides.

Author

Yang J, Massaro L, Krajangsri S, Singh T, Su H, Silvi E, Ponra S, Eriksson L, Ahlquist MSG, and Andersson PG

Abstract

We present a highly efficient convergent asymmetric hydrogenation of E / Z mixtures of enamides catalyzed by N,P-iridium complexes supported by mechanistic studies. It was found that reduction of the olefinic isomers ( E and Z geometries) produces chiral amides with the same absolute configuration (enantioconvergent hydrogenation). This allowed the hydrogenation of a wide range of E / Z mixtures of trisubstituted enamides with excellent enantioselectivity (up to 99% ee ). A detailed mechanistic study using deuterium labeling and kinetic experiments revealed two different pathways for the observed enantioconvergence. For α-aryl enamides, fast isomerization of the double bond takes place, and the overall process results in kinetic resolution of the two isomers. For α-alkyl enamides, no double bond isomerization is detected, and competition experiments suggested that substrate chelation is responsible for the enantioconvergent stereochemical outcome. DFT calculations were performed to predict the correct absolute configuration of the products and strengthen the proposed mechanism of the iridium-catalyzed isomerization pathway.

Published

2021

11. Promoting Selective Generation of Formic Acid from CO 2 Using Mn(bpy)(CO) 3 Br as Electrocatalyst and Triethylamine/Isopropanol as Additives.

Author

Madsen MR, Rønne MH, Heuschen M, Golo D, Ahlquist MSG, Skrydstrup T, Pedersen SU, and Daasbjerg K

Abstract

Urgent solutions are needed to efficiently convert the greenhouse gas CO 2 into higher-value products. In this work, fac -Mn(bpy)(CO) 3 Br (bpy = 2,2'-bipyridine) is employed as electrocatalyst in reductive CO 2 conversion. It is shown that product selectivity can be shifted from CO toward HCOOH using appropriate additives, i.e., Et 3 N along with i PrOH. A crucial aspect of the strategy is to outrun the dimer-generating parent-child reaction involving fac -Mn(bpy)(CO) 3 Br and [Mn(bpy)(CO) 3 ] - and instead produce the Mn hydride intermediate. Preferentially, this is done at the first reduction wave to enable formation of HCOOH at an overpotential as low as 260 mV and with faradaic efficiency of 59 ± 1%. The latter may be increased to 71 ± 3% at an overpotential of 560 mV, using 2 M concentrations of both Et 3 N and i PrOH. The nature of the amine additive is crucial for product selectivity, as the faradaic efficiency for HCOOH formation decreases to 13 ± 4% if Et 3 N is replaced with Et 2 NH. The origin of this difference lies in the ability of Et 3 N/ i PrOH to establish an equilibrium solution of isopropyl carbonate and CO 2 , while with Et 2 NH/ i PrOH, formation of the diethylcarbamic acid is favored. According to density-functional theory calculations, CO 2 in the former case can take part favorably in the catalytic cycle, while this is less opportune in the latter case because of the CO 2 -to-carbamic acid conversion. This work presents a straightforward procedure for electrochemical reduction of CO 2 to HCOOH by combining an easily synthesized manganese catalyst with commercially available additives.

Published

2021

12. Molecular Engineering of Photocathodes based on Polythiophene Organic Semiconductors for Photoelectrochemical Hydrogen Generation.

Author

Zhao Z, Zhan S, Feng L, Liu C, Ahlquist MSG, Wu X, Fan K, Li F, and Sun L

Abstract

Organic semiconductors provide significant potentials for the construction of photoelectrochemical (PEC) cells for solar hydrogen production because of their highly tunable properties. Herein, on carbon fiber paper (CFP) surface, pyridyl (Py), and 4,4'-bipyridin-1-ium (Py 2 + ) groups were introduced into polythiophene (pTH) semiconductor by electrochemical copolymerization, respectively. After assembly with the Co(dmgBF 2 ) 2 type catalyst (CoB, dmgBF 2 = difluoroboryldimethylglyoximate), the CoB@Py 2 + -pTH/CFP photocathode displayed nearly twice the photocurrent enhancement (550 μA cm -2 at 0.15 V vs reversible hydrogen electrode, RHE) comparing to that generated by the CoB@Py-pTH/CFP photocathode (290 μA cm -2 at 0.15 V vs RHE) for light-driven H 2 generation under AM 1.5 solar illumination. Investigation of the mechanism revealed that the introduction of the positively charged pyridinium groups could improve the intrinsic Co(dmgBF 2 ) 2 catalyst activity for the H 2 generation reaction. Meanwhile, the positively charged pyridinium groups serve as p -type dopants to increase the semiconductor bulk charge transfer rate and act as electron transfer mediators to promote the interfacial charge transfer kinetics between the catalyst and the pTH-based organic semiconductor.

Published

2021

13. Site- and Enantioselective Iridium-Catalyzed Desymmetric Mono-Hydrogenation of 1,4-Dienes.

Author

Wu H, Su H, Schulze EJ, Peters BBC, Nolan MD, Yang J, Singh T, Ahlquist MSG, and Andersson PG

Abstract

The control of site selectivity in asymmetric mono-hydrogenation of dienes or polyenes remains largely underdeveloped. Herein, we present a highly efficient desymmetrization of 1,4-dienes via iridium-catalyzed site- and enantioselective hydrogenation. This methodology demonstrates the first iridium-catalyzed hydrogenative desymmetriation of meso dienes and provides a concise approach to the installation of two vicinal stereogenic centers adjacent to an alkene. High isolated yields (up to 96 %) and excellent diastereo- and enantioselectivities (up to 99:1 d.r. and 99 % ee) were obtained for a series of divinyl carbinol and divinyl carbinamide substrates. DFT calculations reveal that an interaction between the hydroxy oxygen and the reacting hydride is responsible for the stereoselectivity of the desymmetrization of the divinyl carbinol. Based on the calculated energy profiles, a model that simulates product distribution over time was applied to show an intuitive kinetics of this process. The usefulness of the methodology was demonstrated by the synthesis of the key intermediates of natural products zaragozic acid A and (+)-invictolide., (© 2021 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2021

14. Switching the O-O Bond Formation Pathways of Ru-pda Water Oxidation Catalyst by Third Coordination Sphere Engineering.

Author

Li Y, Zhan S, Tong L, Li W, Zhao Y, Zhao Z, Liu C, Ahlquist MSG, Li F, and Sun L

Abstract

Water oxidation is a vital anodic reaction for renewable fuel generation via electrochemical- and photoelectrochemical-driven water splitting or CO 2 reduction. Ruthenium complexes, such as Ru-bda family, have been shown as highly efficient water-oxidation catalysts (WOCs), particularly when they undergo a bimolecular O-O bond formation pathway. In this study, a novel Ru(pda)-type (pda 2- =1,10-phenanthroline-2,9-dicarboxylate) molecular WOC with 4-vinylpyridine axial ligands was immobilized on the glassy carbon electrode surface by electrochemical polymerization. Electrochemical kinetic studies revealed that this homocoupling polymer catalyzes water oxidation through a bimolecular radical coupling pathway, where interaction between two Ru(pda)-oxyl moieties (I2M) forms the O-O bond. The calculated barrier of the I2M pathway by density-functional theory (DFT) is significantly lower than the barrier of a water nucleophilic attack (WNA) pathway. By using this polymerization strategy, the Ru centers are brought closer in the distance, and the O-O bond formation pathway by the Ru (pda) catalyst is switched from WNA in a homogeneous molecular catalytic system to I2M in the polymerized film, providing some deep insights into the importance of third coordination sphere engineering of the water oxidation catalyst., Competing Interests: The authors declare that there is no conflict of interest regarding the publication of this article., (Copyright © 2021 Yingzheng Li et al.)

Published

2021

15. Electrostatic Interactions Accelerating Water Oxidation Catalysis via Intercatalyst O-O Coupling.

Author

Yi J, Zhan S, Chen L, Tian Q, Wang N, Li J, Xu W, Zhang B, and Ahlquist MSG

Abstract

Intercatalyst coupling has been widely applied in the functional mimics for binuclear synergy in natural metal enzymes. Herein, we introduce two facile and effective design strategies, which facilitate the coupling of two catalytic units via electrostatic interactions. The first system is based on a catalyst molecule functionalized with both a positively charged and a negatively charged group in the structure being able to pair with each other in an antiparallel manner arranged by electrostatic interactions. The other system consists of a mixture of two different of catalysts modified with either positively or negatively charged groups to generate intermolecular electrostatic interactions. Applying these designs to Ru(bda) (H 2 bda = 2,2'-bipyridine-6,6'-dicarboxylic acid) water-oxidation catalysts improved the catalytic performance by more than an order of magnitude. The intermolecular electrostatic interactions in these two systems were fully identified by 1 H NMR, TEM, SAXS, and electrical conductivity experiments. Molecular dynamics simulations further verified that electrostatic interactions contribute to the formation of prereactive dimers, which were found to play a key role in dramatically improving the catalytic performance. The successful strategies demonstrated here can be used in designing other intercatalyst coupling systems for activation and formation of small molecules and organic synthesis.

Published

2021

16. Pivotal Electron Delivery Effect of the Cobalt Catalyst in Photocarboxylation of Alkynes: A DFT Calculation.

Author

Xu Y, Shao Y, Ahlquist MSG, Yu H, and Fu Y

Abstract

Photocarboxylation of alkyne with carbon dioxide represents a highly attractive strategy to prepare functionalized alkenes with high efficiency and atomic economy. However, the reaction mechanism, especially the sequence of elementary steps (leading to different reaction pathways), reaction modes of the H-transfer step and carboxylation step, spin and charge states of the cobalt catalyst, etc., is still an open question. Herein, density functional theory calculations are carried out to probe the mechanism of the Ir/Co-catalyzed photocarboxylation of alkynes. The overall catalytic cycle mainly consists of four steps: reductive-quenching of the Ir catalyst, hydrogen transfer (rate-determining step), outer sphere carboxylation, and the final catalyst regeneration step. Importantly, the cobalt catalyst can facilitate the H-transfer by an uncommon hydride coupled electron transfer (HCET) process. The pivotal electron delivery effect of the Co center enables a facile H-transfer to the α-C(alkyne) of the aryl group, resulting in the high regioselectivity for β-carboxylation.

Published

2021

17. From Ru-bda to Ru-bds: a step forward to highly efficient molecular water oxidation electrocatalysts under acidic and neutral conditions.

Author

Yang J, Wang L, Zhan S, Zou H, Chen H, Ahlquist MSG, Duan L, and Sun L

Abstract

Significant advances during the past decades in the design and studies of Ru complexes with polypyridine ligands have led to the great development of molecular water oxidation catalysts and understanding on the O-O bond formation mechanisms. Here we report a Ru-based molecular water oxidation catalyst [Ru(bds)(pic) 2 ] (Ru-bds; bds 2- = 2,2'-bipyridine-6,6'-disulfonate) containing a tetradentate, dianionic sulfonate ligand at the equatorial position and two 4-picoline ligands at the axial positions. This Ru-bds catalyst electrochemically catalyzes water oxidation with turnover frequencies (TOF) of 160 and 12,900 s -1 under acidic and neutral conditions respectively, showing much better performance than the state-of-art Ru-bda catalyst. Density functional theory calculations reveal that (i) under acidic conditions, the high valent Ru intermediate Ru V =O featuring the 7-coordination configuration is involved in the O-O bond formation step; (ii) under neutral conditions, the seven-coordinate Ru IV =O triggers the O-O bond formation; (iii) in both cases, the I2M (interaction of two M-O units) pathway is dominant over the WNA (water nucleophilic attack) pathway.

Published

2021

18. Oxide Relay: An Efficient Mechanism for Catalytic Water Oxidation at Hydrophobic Electrode Surfaces.

Author

de Gracia Triviño JA and Ahlquist MSG

Abstract

In order to combine the advantages of molecular catalysts with the stability of solid-state catalysts, hybrid systems with catalysts immobilized on carbon nanotubes are prominent candidates. Here we explore our recent mechanistic proposal for Ru(tda)(py) 2 , the oxide relay mechanism, in a hybrid system from an experimental study. It reacts with the same efficiency but with increased stability compared to the homogeneous molecular catalyst. We used the empirical valence bond method and molecular dynamics with enhanced sampling approaches to investigate the two key steps in the mechanism: the intramolecular O-O bond formation and the OH - nucleophilic attack. The results on these calculations show that the oxide relay mechanism remains unaltered in the new environment. We believe that the principles should apply to other oxide containing dangling groups and to other metal centers, opening new possibilities of future developments on hybrid molecular catalyst-based water splitting devices.

Published

2020

19. The Carboxylate Ligand as an Oxide Relay in Catalytic Water Oxidation.

Author

Zhan S, De Gracia Triviño JA, and Ahlquist MSG

Abstract

Carboxylate groups have diverse functionalities in ligands of transition metal catalysts. Here we present a conceptually different function of the carboxylates: the oxide relay. It functions by providing an intramolecular nucleophilic oxygen close to the oxo group to facilitate O-O bond formation and at a later stage a remote electrophilic center to facilitate OH - nucleophilic attack. Empirical valence bond-molecular dynamics (EVB-MD) models were generated for key bond forming steps, diffusion coefficients and binding free energies from potential of mean force estimations were calculated from molecular dynamics (MD) simulations, activation free energies of chemical steps were calculated using density functional theory (DFT). The catalyst studied is the extremely active Ru(tda)(py) 2 water oxidation catalyst. The combination of simulation methods allowed for estimation of the turnover frequencies, which were within 1 order of magnitude from the experimental results at different pH values. From the calculated reaction rates we find that at low pH the OH - anion nucleophilic attack is the rate-limiting step, which changes at high pH to the O-O bond formation step. Both steps are extremely rapid, and key to the efficiency is the oxide relay functionality of a pendant carboxylate group. We cannot exclude all alternative mechanisms and suggest isotope experiments using 18 O-labeled water to support or invalidate the oxide relay mechanism. The functionality was discovered for a ruthenium catalyst, but since there is nothing in the mechanism restricting it to this metal, the oxide relay functionality could open new ways to design the next-generation water oxidation catalysts with improved activity.

Published

2019

20. Paired Electrocatalytic Oxygenation and Hydrogenation of Organic Substrates with Water as the Oxygen and Hydrogen Source.

Author

Zhang P, Sheng X, Chen X, Fang Z, Jiang J, Wang M, Li F, Fan L, Ren Y, Zhang B, Timmer BJJ, Ahlquist MSG, and Sun L

Abstract

The use of water as an oxygen and hydrogen source for the paired oxygenation and hydrogenation of organic substrates to produce valuable chemicals is of utmost importance as a means of establishing green chemical syntheses. Inspired by the active Ni 3+ intermediates involved in electrocatalytic water oxidation by nickel-based materials, we prepared NiB x as a catalyst and used water as the oxygen source for the oxygenation of various organic compounds. NiB x was further employed as both an anode and a cathode in a paired electrosynthesis cell for the respective oxygenation and hydrogenation of organic compounds, with water as both the oxygen and hydrogen source. Conversion efficiency and selectivity of ≥99 % were observed during the oxygenation of 5-hydroxymethylfurfural to 2,5-furandicarboxylic acid and the simultaneous hydrogenation of p-nitrophenol to p-aminophenol. This paired electrosynthesis cell has also been coupled to a solar cell as a stand-alone reactor in response to sunlight., (© 2019 The Authors. Published by Wiley-VCH Verlag GmbH & Co. KGaA.)

Published

2019

21. Development and mechanistic investigation of the manganese(iii) salen-catalyzed dehydrogenation of alcohols.

Author

Samuelsen SV, Santilli C, Ahlquist MSG, and Madsen R

Abstract

The first example of a manganese(iii) catalyst for the acceptorless dehydrogenation of alcohols is presented. N , N' -Bis(salicylidene)-1,2-cyclohexanediaminomanganese(iii) chloride ( 2 ) has been shown to catalyze the direct synthesis of imines from a variety of alcohols and amines with the liberation of hydrogen gas. The mechanism has been investigated experimentally with labelled substrates and theoretically with DFT calculations. The results indicate a metal-ligand bifunctional pathway in which both imine groups in the salen ligand are first reduced to form a manganese(iii) amido complex as the catalytically active species. Dehydrogenation of the alcohol then takes place by a stepwise outer-sphere hydrogen transfer generating a manganese(iii) salan hydride from which hydrogen gas is released.

Published

2018

22. Dynamics and Reactions of Molecular Ru Catalysts at Carbon Nanotube-Water Interfaces.

Author

Zhan S and Ahlquist MSG

Abstract

Immobilization of molecular catalysts to electrode surfaces can improve the recyclability and electron transfer rates. The drawback is that most experimental techniques and theoretical methods are not applicable. Here we present results from a study of a ruthenium water oxidation catalyst [Ru V O(bda)L 2 ] in explicit water at a carbon nanotube water interface, forming the key O-O bond between two 128 atom catalysts, all fully dynamically. Our methodology is based on a recently developed empirical valence bond (EVB) model. We follow the key steps of the reaction including diffusion of the catalysts at the interface, formation of the prereactive dimer, and the bond formation between the two catalysts. On the basis of the calculated parameters, we compute the turnover frequency (TOF) at the experimental loading, in excellent agreement with the experiments. The key O-O bond formation was significantly retarded at the surface, and limiting components were identified that could be improved by catalyst modification.

Published

2018

23. Mechanistic Studies on NaHCO 3 Hydrogenation and HCOOH Dehydrogenation Reactions Catalysed by a Fe II Linear Tetraphosphine Complex.

Author

Marcos R, Bertini F, Rinkevicius Z, Peruzzini M, Gonsalvi L, and Ahlquist MSG

Abstract

We present a theoretical extension of the previously published bicarbonate hydrogenation to formate and formic acid dehydrogenation catalysed by Fe II complexes bearing the linear tetraphosphine ligand tetraphos-1. The hydrogenation reaction was found to proceed at the singlet surface with two competing pathways: A) H 2 association to the Fe-H species followed by deprotonation to give a Fe(H) 2 intermediate, which then reacts with CO 2 to give formate. B) CO 2 insertion into the Fe-H bond, followed by H 2 association and subsequent deprotonation. B was found to be slightly preferred with an activation energy of 22.8 kcal mol -1 , compared to 25.3 for A. Further we have reassigned the Fe-H complex, as a Fe(H)(H 2 ), which undergoes extremely rapid hydrogen exchange., (© 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

24. Capturing the Role of Explicit Solvent in the Dimerization of Ru V (bda) Water Oxidation Catalysts.

Author

Zhan S, Mårtensson D, Purg M, Kamerlin SCL, and Ahlquist MSG

Abstract

A ground-breaking empirical valence bond study for a soluble transition-metal complex is presented. The full reaction of catalyst monomers approaching and reacting in the Ru V oxidation state were studied. Analysis of the solvation shell in the reactant and along the reaction coordinate revealed that the oxo itself is hydrophobic, which adds a significant driving force to form the dimer. The effect of the solvent on the reaction between the prereactive dimer and the product was small. The solvent seems to lower the barrier for the isoquinoline (isoq) complex while it is increased for pyridines. By comparing the reaction in the gas phase and solution, the proposed π-stacking interaction of the isoq ligands is found to be entirely driven by the water medium., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

25. Formation of N-oxide in the third oxidation of [Ru II (tpy)(L)(OH 2 )] 2 .

Author

Wang Y, Rinkevicius Z, and Ahlquist MSG

Abstract

The widely studied water oxidation catalyst [Ru II (tpy)(L)(OH 2 )] 2+ (tpy = 2,2':6',2''-terpyridine, L = bpy = 2,2'-bipyridine or L = bpm = 2,2'-bipyrimidine) is still under scrutiny. Here we present a new suggestion for one of the key steps, results that could resolve conflicting interpretations of experimental results. Instead of the previously proposed Ru V [double bond, length as m-dash]O species, a proposed key species in water oxidation catalysis, we propose that the third oxidation of Ru II could lead to a Ru III N-oxide, via rapid water coordination followed by oxidation and concerted N-O bond formation.

Published

2017

26. Base-Catalyzed Stereospecific Isomerization of Electron-Deficient Allylic Alcohols and Ethers through Ion-Pairing.

Author

Martinez-Erro S, Sanz-Marco A, Bermejo Gómez A, Vázquez-Romero A, Ahlquist MSG, and Martín-Matute B

Abstract

A mild base-catalyzed strategy for the isomerization of allylic alcohols and allylic ethers has been developed. Experimental and computational investigations indicate that transition metal catalysts are not required when basic additives are present. As in the case of using transition metals under basic conditions, the isomerization catalyzed solely by base also follows a stereospecific pathway. The reaction is initiated by a rate-limiting deprotonation. Formation of an intimate ion pair between an allylic anion and the conjugate acid of the base results in efficient transfer of chirality. Through this mechanism, stereochemical information contained in the allylic alcohols is transferred to the ketone products. The stereospecific isomerization is also applicable for the first time to allylic ethers, yielding synthetically valuable enantioenriched (up to 97% ee) enol ethers.

Published

2016

27. Formation of a C-C double bond from two aliphatic carbons. Multiple C-H activations in an iridium pincer complex.

Author

Polukeev AV, Marcos R, Ahlquist MSG, and Wendt OF

Abstract

The search for novel, atom-economic methods for the formation of C-C bonds is of crucial importance in synthetic chemistry. Especially attractive are reactions where C-C bonds are formed through C-H activation, but the coupling of unactivated, alkane-type C sp 3 -H bonds remains an unsolved challenge. Here, we report iridium-mediated intramolecular coupling reactions involving up to four unactivated C sp 3 -H bonds to give carbon-carbon double bonds under the extrusion of dihydrogen. The reaction described herein is completely reversible and the direction can be controlled by altering the reaction conditions. With a hydrogen acceptor present a C-C double bond is formed, while reacting under dihydrogen pressure leads to the reverse process, with some of the steps representing net C sp 3 -C sp 3 bond cleavage. Mechanistic investigations revealed a conceptually-novel overall reactivity pattern where insertion or deinsertion of an Ir carbene moiety, formed via double C-H activation, into an Ir-C bond is responsible for the key C-C bond formation and cleavage steps.

Published

2015