Structure and reactivity/selectivity control by oriented-external electric fields

Shaik, Sason; Ramanan, Rajeev; Mandal, Debasish

doi:10.1039/c8cs00354h

Cited by 370 publications

(571 citation statements)

References 46 publications

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“…In recent years, (external) electric fields are increasingly being recognized as potent—and smart—effectors of chemical change . Their introduction in the toolbox of synthetic chemists could potentially be a game changer, opening new (and more sustainable) routes toward chemical synthesis .…”

Section: Introductionmentioning

confidence: 99%

“…The seemingly endless potential of electric fields as a means for the control of chemical reactivity has sparked a lot of interest, not only from the biochemistry community, but also from organic chemists, as well as others . As a consequence, there is an increasing need for computational and theoretical chemists to extend their activities and expertise to this new research field.…”

Section: Introductionmentioning

confidence: 99%

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TITAN: A Code for Modeling and Generating Electric Fields—Features and Applications to Enzymatic Reactivity

et al. 2019

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We present here a versatile computational code named “elecTric fIeld generaTion And maNipulation (TITAN),” capable of generating various types of external electric fields, as well as quantifying the local (or intrinsic) electric fields present in proteins and other biological systems according to Coulomb's Law. The generated electric fields can be coupled with quantum mechanics (QM), molecular mechanics (MM), QM/MM, and molecular dynamics calculations in most available software packages. The capabilities of the TITAN code are illustrated throughout the text with the help of examples. We end by presenting an application, in which the effects of the local electric field on the hydrogen transfer reaction in cytochrome P450 OleTJE enzyme and the modifications induced by the application of an oriented external electric field are examined. We find that the protein matrix in P450 OleTJE acts as a moderate catalyst and that orienting an external electric field along the Fe─O bond of compound I has the biggest impact on the reaction barrier. The induced catalysis/inhibition correlates with the calculated spin density on the O‐atom. © 2019 Wiley Periodicals, Inc.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

TITAN: A Code for Modeling and Generating Electric Fields—Features and Applications to Enzymatic Reactivity

et al. 2019

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“…The directions of one‐dimension EEF are oriented along the X ‐, Y ‐, and Z ‐axes as showed in Figure . It is to be noted that the positive direction of the electric field vector is defined from the negative to the positive charge in Gaussian 09, which is opposite to the conventional definition in physics . Multiwfn program was used to draw the electron density difference (EDD) maps for the transition states relative to field‐free TSs.…”

Section: Computational Detailsmentioning

confidence: 99%

“…Up to now, some endeavors had been done to develop a new methodology in accordance with green chemistry principles . An emerging greener catalyst is coming into one's sight, which is the external electric field (EEF), as a smart reagent to catalyze reactions had been reported by theory and experiment . Especially, the experiment of EEF by Aragonés et al paved the way for the development of EEF in catalyzing chemistry reactions.…”

Section: Introductionmentioning

confidence: 99%

A greener catalyst for hydroboration of imines—external electric field modify the reaction mechanism

Zhang

2019

J Comput Chem

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Usually, an extra catalyst (for example, the transition metal complexes) need to be used in catalyzing hydroboration, which involved the cost, environment, and so forth. Here, a greener and controllable catalyst—external electric field (EEF) was used to study its effect on hydroboration of N‐(4‐methylbenzyl)aniline (PhN═CHPhMe) with pinacolboane (HBPin). The results demonstrated that EEF could affect the barrier heights of both two pathways of this reaction. More significantly, flipping the direction of EEF could modify the reaction mechanism to induce a dominant inverse hydroboration at some field strength. That is to say, oriented EEF is a controlling switch for the anti‐ or Markovnikov hydroboration reaction of imines. This investigation is meaningful for the exploration of greener catalyst for chemistry reaction and guide a new method for the Markovnikov hydroboration addition. © 2019 Wiley Periodicals, Inc.

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“…[29] In DBM, two covalent structures OÀ H···O and O···HÀ O mix with two charge-transfer structures O + À H···O À and O À -···HÀ O + giving the ground molecular state. Generally, electric field increases the mixing of covalent with ionic and charge-transfer valence-bond structures and subsequently modifies the reaction barrier.…”

Section: The Effects Of Hydrogen Bonding and Homogeneous Electric Fiementioning

confidence: 99%

Elucidating Solvent Effects on Strong Intramolecular Hydrogen Bond: DFT‐MD Study of Dibenzoylmethane in Methanol Solution

et al. 2019

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The dynamic aspect of solvation plays a crucial role in determining properties of strong intramolecular hydrogen bonds since solvent fluctuations modify instantaneous hydrogen-bonded proton transfer barriers. Previous studies pointed out that solvent-solute interactions in the first solvation shell govern the position of the proton but the ability of the electric field due to other solvent molecules to localize the proton remains an important issue. In this work, we examine the structure of the OÀ H···O intramolecular hydrogen bond of dibenzoylmethane in methanol solution by employing density functional theory-based molecular dynamics and quantum chemical calculations. Our computations showed that homoge-neous electric fields with intensities corresponding to those found in polar solvents are able to considerably alter the proton transfer barrier height in the gas phase. In methanol solution, the proton position is correlated with the difference in electrostatic potentials on the oxygen atoms of dibenzoylmethane even when dibenzoylmethane-methanol hydrogen bonding is lacking. On a timescale of our simulation, the hydrogen bonding and solvent electrostatics tend to localize the proton on different oxygen atoms. These findings provide an insight into the importance of the solvent electric field on the structure of a strong intramolecular hydrogen bond.

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Structure and reactivity/selectivity control by oriented-external electric fields

Cited by 370 publications

References 46 publications

TITAN: A Code for Modeling and Generating Electric Fields—Features and Applications to Enzymatic Reactivity

TITAN: A Code for Modeling and Generating Electric Fields—Features and Applications to Enzymatic Reactivity

A greener catalyst for hydroboration of imines—external electric field modify the reaction mechanism

Elucidating Solvent Effects on Strong Intramolecular Hydrogen Bond: DFT‐MD Study of Dibenzoylmethane in Methanol Solution

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