Computer-aided molecular design of solvents for accelerated reaction kinetics

Struebing, Heiko; Ganase, Zara; Karamertzanis, Panagiotis G.; Siougkrou, Eirini; Haycock, Peter R.; Piccione, Patrick M.; Armstrong, Alan; Galindo, Amparo; Adjiman, Claire S.

doi:10.1038/nchem.1755

Cited by 154 publications

(123 citation statements)

References 43 publications

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“…71,72 The issue of determining the best solvent for a specific chemical reaction has been recently addressed by combining quantum chemistry calculations with computeraided molecular design. 73 Thus, accurate prediction on solvent effects remain an important goal and can be very useful in the future studies of the design of best solvent for diverse chemical reactions of practical interest. 74 …”

Section: Resultsmentioning

confidence: 99%

How Accurate is the SMD Model for Predicting Free Energy Barriers for Nucleophilic Substitution Reactions in Polar Protic and Dipolar Aprotic Solvents?

Miguel¹,

Santos²,

Silva³

et al. 2016

Journal of the Brazilian Chemical Society

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In the past seven years, the SMD (Solvent Model Density) method has been widely used by computational chemists. Thus, assessment on the reliability of this model for modeling chemical process in solution is worthwhile. In this report, it was investigated six anion-molecule nucleophilic substitution reactions in methanol and dipolar aprotic solvents. Geometry optimizations have been done at SMD/X3LYP level and single point energy calculations at CCSD(T)/TZVPP + diff level. Our results have indicated that the SMD model is not adequate for dipolar aprotic solvents, with a root of mean squared (RMS) error of 5.6 kcal mol . The classical protic to dipolar aprotic solvent rate acceleration effect was not predicted by the SMD model for the tested systems.Keywords: continuum solvation model, ion solvation, solvent effect, aromatic nucleophilic substitution, M11 functional IntroductionIn the middle of the twentieth century, several experimental studies have led to foundation of empirical rules for qualitative prediction of solvent effects on chemical reactions, authoritatively reviewed by Parker 1 in a classical paper. Nevertheless, a deeper view on solvent effects was only possible with experimental studies of gas phase ion-molecule reactions [2][3][4][5][6] and theoretical modeling of these processes. [7][8][9] It was evident from theoretical studies that solute-solvent interactions can be very strong and produce a profound effect on chemical reactivity. [10][11][12][13][14][15][16][17] On the other hand, gas phase dynamic of chemical reactions can open new mechanistic possibilities. 18,19 Among the different solvents used to conduct ionic chemical reactions, polar protic and dipolar aprotic solvents are paramount due to their property of solubilize ionic species. 20 Methanol is a polar protic solvent and its ability to solvate ions is similar to water. 21,22 In addition, it has the advantage of solubilize many organic molecules not soluble in water. Some usual dipolar aprotic solvents are dimethyl sulfoxide (DMSO), dimethylformamide (DMF) and acetonitrile. Because anions are less solvated in these solvents, anion-molecule reactions are accelerated when transferred from protic to dipolar aprotic solvents. Our ability to describe theoretically this effect is an important goal and a challenge for continuum solvation models once requires these models be able to describe specific solutesolvent interactions. 23 Considering that the Born formula for solvation of a spherical ion of charge q and radius R into a solvent with dielectric constant ε is given by:(1) it could be noted that the use of the same "molecular cavity" for an ionic solute into a protic and dipolar aprotic solvent with high dielectric constant would lead to very similar solvation free energy of ions. A possibility to overcome this problem would be to use different molecular cavity for protic and dipolar aprotic solvents. This approach has reached some successful ten years ago using the polarizable continuum model (PCM) in the study of anion-molecule reaction...

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Section: Resultsmentioning

confidence: 99%

How Accurate is the SMD Model for Predicting Free Energy Barriers for Nucleophilic Substitution Reactions in Polar Protic and Dipolar Aprotic Solvents?

Miguel¹,

Santos²,

Silva³

et al. 2016

Journal of the Brazilian Chemical Society

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“…The application of SAFT-VR is later applied by Mac Dowell et al (2011) to describe the fluid phase behaviour in modelling of amines and mixtures of amines with water and carbon dioxide. Struebing et al (2013) proposed a systematic methodology that identifies improved reaction solvents by combining quantum mechanical computations of reaction rate constant with CAMD procedure. The developed methodology allows the identification of high performance solvent within a large set of possible molecules.…”

Section: Computer-aided Molecular Design (Camd)mentioning

confidence: 99%

Robust chemical product design via fuzzy optimisation approach

Chemmangattuvalappil

2015

Computers & Chemical Engineering

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“…Discrete variables are used to represent molecularlevel decisions such as the number of groups of a given kind (for example, how many hydroxyl groups the optimal molecule contains, if any), with constraints used to specify how the groups can be combined. [6][7][8][9] Discrete variables can also be used to represent the connectivity between the groups, 10,11 and the identity of components if the material of interest is a mixture. [12][13][14] The CAMPD problem is inherently more complex than the corresponding process design problem with fixed material choices.…”

Section: Introductionmentioning

confidence: 99%

Outer approximation algorithm with physical domain reduction for computer‐aided molecular and separation process design

et al. 2016

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Integrated approaches to the design of separation systems based on computer-aided molecular and process design (CAMPD) can yield an optimal solvent structure and process conditions. The underlying design problem, however, is a challenging mixed integer nonlinear problem, prone to convergence failure as a result of the strong and nonlinear interactions between solvent and process. To facilitate the solution of this problem, a modified outer-approximation (OA) algorithm is proposed. Tests that remove infeasible regions from both the process and molecular domains are embedded within the OA framework. Four tests are developed to remove subdomains where constraints on phase behavior that are implicit in process models or explicit process (design) constraints are violated. The algorithm is applied to three case studies relating to the separation of methane and carbon dioxide at high pressure. The process model is highly nonlinear, and includes mass and energy balances as well as phase equilibrium relations and physical property models based on a group-contribution version of the statistical associating fluid theory (SAFT-c Mie) and on the GC 1 group contribution method for some pure component properties. A fully automated implementation of the proposed approach is found to converge successfully to a local solution in 30 problem instances. The results highlight the extent to which optimal solvent and process conditions are interrelated and dependent on process specifications and constraints. The robustness of the CAMPD algorithm makes it possible to adopt higher-fidelity nonlinear models in molecular and process design.

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Computer-aided molecular design of solvents for accelerated reaction kinetics

Cited by 154 publications

References 43 publications

How Accurate is the SMD Model for Predicting Free Energy Barriers for Nucleophilic Substitution Reactions in Polar Protic and Dipolar Aprotic Solvents?

How Accurate is the SMD Model for Predicting Free Energy Barriers for Nucleophilic Substitution Reactions in Polar Protic and Dipolar Aprotic Solvents?

Robust chemical product design via fuzzy optimisation approach

Outer approximation algorithm with physical domain reduction for computer‐aided molecular and separation process design

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