Prediction of Equilibrium Interfacial Tension between CO<sub>2</sub> and Water Based on Mutual Solubility

Chen, Zehua; Yang, Daoyong

doi:10.1021/acs.iecr.8b01554

Cited by 8 publications

(2 citation statements)

References 43 publications

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“…In recent years, Niroomand-Toomaj et al, Partovi et al, and Chen and Yang have adopted a multilayer perceptron model, least squares support vector machine, adaptive neurofuzzy inference system, radial basis function network optimized by particle swarm optimization method, adaptive neurofuzzy inference system trained by a hybrid method, and mutual solubility model; the models are established for temperature, pressure, salinity/molality concentration, and gas mole fraction, all of which have achieved high prediction accuracy.…”

Section: Introductionmentioning

confidence: 99%

Comparative Analysis of Four Neural Network Models on the Estimation of CO₂–Brine Interfacial Tension

et al. 2021

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During the CO 2 injection of geological carbon sequestration and CO 2enhanced oil recovery, the contact of CO 2 with underground salt water is inevitable, where the interfacial tension (IFT) between gas and liquid determines whether the projects can proceed smoothly. In this paper, three traditional neural network models, the wavelet neural network (WNN) model, the back propagation (BP) model, and the radical basis function model, were applied to predict the IFT between CO 2 and brine with temperature, pressure, monovalent cation molality, divalent cation molality, and molar fraction of methane and nitrogen impurities. A total of 974 sets of experimental data were divided into two data groups, the training group and the testing group. By optimizing the WNN model (I_WNN), a most stable and precise model is established, and it is found that temperature and pressure are the main parameters affecting the IFT. Through the comparison of models, it is found that I_WNN and BP models are more suitable for the IFT evaluation between CO 2 and brine.

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Section: Introductionmentioning

confidence: 99%

Comparative Analysis of Four Neural Network Models on the Estimation of CO₂–Brine Interfacial Tension

et al. 2021

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“…However, empirical correlations are demonstrated to exhibit relatively low accuracy and weak generality when used for estimating new data that are blind to model constructions. , The density gradient theory (DGT) based on phase thermodynamics is another alternative method for predicting CO 2 /brine IFT data, whose accuracy however remains questionable when applied for modeling systems with high brine salinities . The correlations based on the mutual solubility are demonstrated to result in noticeable underestimation of the CO 2 /brine IFT at high salinities or when bivalent cations are present in the brine phase.…”

Section: Introductionmentioning

confidence: 99%

A Supervised Learning Approach for Accurate Modeling of CO₂–Brine Interfacial Tension with Application in Identifying the Optimum Sequestration Depth in Saline Aquifers

et al. 2020

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The CO 2 −brine interfacial tension (IFT) is a key parameter affecting the CO 2 storage capacity in saline aquifers and therefore should be accurately characterized to ensure the optimal design of CO 2 sequestration projects. This paper proposed the use of the extreme gradient boosting (XGBoost) trees for the fast and accurate modeling of the CO 2 −brine IFT. Results show that the novel model is capable of not only estimating the IFT but also reproducing the underlying correlation between the IFT and each input variable with remarkably high accuracies. Statistical matrices and point-wise error analyses demonstrate that the new model outperforms previous machine learning (ML) methods significantly. The estimation model was then applied for determining the optimum CO 2 sequestration depth in saline aquifers, which reveals that higher pressure and/or lower geothermal gradients result in a significant increase in the maximum structural trapping capacity that occurs at noticeably shallower formations.

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Determination of mutual solubility between n-alkanes/n-alkylbenzenes and water by using Peng-Robinson equation of state with modified alpha functions and generalized BIP correlations

Chen

Yang

2018

Fluid Phase Equilibria

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Prediction of Equilibrium Interfacial Tension between CO₂ and Water Based on Mutual Solubility

Cited by 8 publications

References 43 publications

Comparative Analysis of Four Neural Network Models on the Estimation of CO₂–Brine Interfacial Tension

Comparative Analysis of Four Neural Network Models on the Estimation of CO₂–Brine Interfacial Tension

A Supervised Learning Approach for Accurate Modeling of CO₂–Brine Interfacial Tension with Application in Identifying the Optimum Sequestration Depth in Saline Aquifers

Determination of mutual solubility between n-alkanes/n-alkylbenzenes and water by using Peng-Robinson equation of state with modified alpha functions and generalized BIP correlations

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Prediction of Equilibrium Interfacial Tension between CO2 and Water Based on Mutual Solubility

Cited by 8 publications

References 43 publications

Comparative Analysis of Four Neural Network Models on the Estimation of CO2–Brine Interfacial Tension

Comparative Analysis of Four Neural Network Models on the Estimation of CO2–Brine Interfacial Tension

A Supervised Learning Approach for Accurate Modeling of CO2–Brine Interfacial Tension with Application in Identifying the Optimum Sequestration Depth in Saline Aquifers

Determination of mutual solubility between n-alkanes/n-alkylbenzenes and water by using Peng-Robinson equation of state with modified alpha functions and generalized BIP correlations

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Prediction of Equilibrium Interfacial Tension between CO₂ and Water Based on Mutual Solubility

Comparative Analysis of Four Neural Network Models on the Estimation of CO₂–Brine Interfacial Tension

Comparative Analysis of Four Neural Network Models on the Estimation of CO₂–Brine Interfacial Tension

A Supervised Learning Approach for Accurate Modeling of CO₂–Brine Interfacial Tension with Application in Identifying the Optimum Sequestration Depth in Saline Aquifers