Predicting Solvent Effects on Homogeneity and Kinetics of the Hydroaminomethylation: A Thermodynamic Approach Using PC-SAFT

Huxoll, Fabian; Kampwerth, Anna; Seidensticker, Thomas; Vogt, Dieter; Sadowski, Gabriele

doi:10.1021/acs.iecr.1c03891

Cited by 16 publications

(7 citation statements)

References 39 publications

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“…Moreover, the activity coefficient of HAc did not play a crucial role in both kinetics and equilibrium. This finding is new since previous works by Huxoll et al 3 and Pabsch et al 4 found that the solvent influence on the activity coefficient of the acid was the main driving force for slower/faster kinetics. We now see that this is not the case for the addition of CO 2 addition.…”

Section: Influence Of Co 2 On Kinetics and Equilibriummentioning

confidence: 55%

“…This gives rise to the importance of developing thermodynamic models to predict gas solubility in electrolyte solutions as well as to predict the kinetics and equilibria of chemical or biochemical reactions. Several equations of state (EOS) were developed in the last decades, providing a robust modeling framework for calculating the gas solubility in electrolyte solutions and predicting kinetics and equilibria of chemical or biochemical reactions. − Moreover, methods were developed to describe the simultaneous occurrence of chemical reactions and phase equilibria …”

Section: Introductionmentioning

confidence: 99%

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Influence of Solvents and Salts on CO₂ Solubility and the Impact on an Esterification Reaction

Schick,

Chen,

Hellfajer

et al. 2023

J. Chem. Eng. Data

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The influence of solvents and salts on the CO 2 solubility and the impact on esterification reaction kinetics and equilibrium are of particular interest, e.g., for the esterification of acetic acid with ethanol under the influence of CO 2 , N-methyl-2pyrrolidone (NMP), or electrolytes. In this work, the equation of state (EOS) electrolyte Perturbed-Chain Statistical Associating Fluid Theory (ePC-SAFT advanced) was first applied to predict the CO 2 solubility in solvent mixtures containing NMP and water with additional electrolytes (NaCl, CsCl). New experimental data on the CO 2 solubility in electrolyte solutions were measured by two different static synthetic methods, and the ePC-SAFT predictions matched well with the experimental data. As a result, NMP increased the CO 2 solubility, compared to water as the only solvent, while electrolytes caused a salting-out effect on the CO 2 solubility in all investigated systems. Further, the kinetics and equilibria of the esterification reaction were studied in the presence of CO 2 , NMP, and electrolytes. New data were measured by using a high-pressure autoclave with in situ ATR-FTIR spectroscopy, which enabled real-time monitoring of the kinetic profiles. Therein, CO 2 and NMP showed a negative effect on the kinetics. However, the additional CO 2 in the reaction mixture positively influenced the equilibrium, while NMP had a negative influence. Finally, ePC-SAFT advanced was applied to predict the influence of CO 2 and NMP on both kinetics and equilibrium of ethanol esterification using a thermodynamic activity-based kinetic approach. Therein, the experimental findings were successfully predicted by the model without fitting any model parameter to the experimental data. Ultimately, this approach reduces the experimental effort toward screening most suitable reaction conditions for chemical reactions and screening the influence of other compounds on kinetics and equilibria.

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Section: Influence Of Co 2 On Kinetics and Equilibriummentioning

confidence: 55%

Section: Introductionmentioning

confidence: 99%

Influence of Solvents and Salts on CO₂ Solubility and the Impact on an Esterification Reaction

Schick,

Chen,

Hellfajer

et al. 2023

J. Chem. Eng. Data

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“…As it is known from literature [14,26,27] an additional solvent usually decreases kinetics of esterification reactions and reduces the equilibrium concentration of a reaction product. In this work, the activities of reacting agents

{a}

i at reaction equilibrium were predicted using ePC‐SAFT advanced for different conditions.…”

Section: Resultsmentioning

confidence: 99%

Activity‐Based Models to Predict Kinetics of Levulinic Acid Esterification

et al. 2022

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The solvent is of prime importance in biomass conversion as it influences dissolution, reaction kinetics, catalyst activity and thermodynamic equilibrium of the reaction system. So far, activity-based models were developed to predict kinetics and equilibria, but the influence of the catalyst could not be predicted by thermodynamic models. Thus, in this work, the thermodynamic model ePC-SAFT advanced was used to predict the activities of the reactants and of the catalyst at various conditions (temperature, reactant concentrations, γ-valerolactone GVL cosolvent addition, catalyst concentration) for the homogeneously acid-catalyzed esterification of levulinic acid (LA) with ethanol. Different kinetic models were applied, and it was found that the catalyst influence on kinetics could be predicted correctly by simultaneously solving the dissociation equilibrium of H2SO4 catalyst along the reaction coordinate and the relating reaction kinetics to proton activity. ePC-SAFT advanced model parameters were only fitted to reaction-independent phase equilibrium data, but the key reaction properties were determined by one experimental kinetic curve for a set of temperatures, yielding the reaction enthalpy at standard state ∆ 𝑅 𝐻 0 = 11.48 𝑘𝐽 𝑚𝑜𝑙 −1 , activation energy 𝐸 𝐴 = 30.28 𝑘𝐽 𝑚𝑜𝑙 −1 and the intrinsic reaction rate constant k = 0.011 s -1 at 323 K, which is independent of catalyst concentration. The new procedure allowed an a-priori identification of the effects of catalyst, solvent and reactant concentration on LA esterification.

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“…The possible contributions (hard-chain repulsion, dispersion interaction, association, ionic interaction) calculate for the total residual Helmholtz energy by summation. Detailed information about applications can be found in the literature for, e.g., polymer systems, ,, pharmaceuticals, , ionic liquids, ,, solubility modeling, , or reaction modeling. , …”

Section: Methodsmentioning

confidence: 99%

Fitting Error vs Parameter Performance─How to Choose Reliable PC-SAFT Pure-Component Parameters by Physics-Informed Machine Learning

Habicht,

Sadowski,

Brandenbusch

2023

J. Chem. Eng. Data

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State of the art thermodynamic models, such as the Perturbed-Chain Statistical Associating Fluid Theory (PC-SAFT), require a thorough parametrization (three pure-component parameters for nonassociating molecules) of the molecules considered. In our previous work (J. Habicht, C. Brandenbusch, G. Sadowski, Fluid Phase Equilibria, 2023, 565, 113657), we introduced a Machine Learning approach for a predictive parametrization of nonassociating components. Within this approach, training is performed using a Huber-loss function, comparing the ML-predicted parameter set with the original one, e.g., from literature. However, often multiple pure-component parameter sets exist for one molecule. This fact makes the training to only one "true" parameter set questionable. Within this work, we thus performed a detailed analysis on the fact of multiparameter set existence. We further expanded our ML-approach by developing a choice of two physics-informed loss functions that allow for the consideration of multiple "true" parameter sets during training. Results indicate that reliable pure-component parameters have a certain orientation when plotted in the three-dimensional parameter space. The results of this work will lead to a more reliable ML-based parametrization and ensure the prediction of optimized purecomponent parameters for a given molecule.

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Predicting Solvent Effects on Homogeneity and Kinetics of the Hydroaminomethylation: A Thermodynamic Approach Using PC-SAFT

Cited by 16 publications

References 39 publications

Influence of Solvents and Salts on CO₂ Solubility and the Impact on an Esterification Reaction

Influence of Solvents and Salts on CO₂ Solubility and the Impact on an Esterification Reaction

Activity‐Based Models to Predict Kinetics of Levulinic Acid Esterification

Fitting Error vs Parameter Performance─How to Choose Reliable PC-SAFT Pure-Component Parameters by Physics-Informed Machine Learning

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Predicting Solvent Effects on Homogeneity and Kinetics of the Hydroaminomethylation: A Thermodynamic Approach Using PC-SAFT

Cited by 16 publications

References 39 publications

Influence of Solvents and Salts on CO2 Solubility and the Impact on an Esterification Reaction

Influence of Solvents and Salts on CO2 Solubility and the Impact on an Esterification Reaction

Activity‐Based Models to Predict Kinetics of Levulinic Acid Esterification

Fitting Error vs Parameter Performance─How to Choose Reliable PC-SAFT Pure-Component Parameters by Physics-Informed Machine Learning

Contact Info

Product

Resources

About

Influence of Solvents and Salts on CO₂ Solubility and the Impact on an Esterification Reaction

Influence of Solvents and Salts on CO₂ Solubility and the Impact on an Esterification Reaction