Prediction of Infinite Dilution Molar Conductivity for Unconventional Ions: A Quantitative Structure–Property Relationship Study

Song, Fan; Xiao, Yongjun; An, Shuhao; Ren, Wan; Xu, Yingjie; Peng, Changjun; Liu, Honglai

doi:10.1021/acs.iecr.1c03019

Cited by 6 publications

(11 citation statements)

References 55 publications

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“…The key to constructing a QSPR model is to choose a set of suitable descriptors that are also unique, which can indicate the structural characteristics of cations and anions. This study used work by Song et al 42 to divide the charge density distribution area of cations and anions into certain intervals S σi (e•nm −2 ) as the descriptors to develop the λ-QSPR model. Table 1 shows the σ profiles of cations divided into 5 intervals, concentrating at −2.0−0.5 e•nm −2 .…”

Section: Dataset Of Thermal Conductivitymentioning

confidence: 99%

“…The second is that the fragment area descriptor obtained by COSMO-SAC in the work can distinguish the isomers of substances. In recent studies, QSPR models showed accurate predictions for the infinite dilution molar conductivity and infinite dilution diffusion coefficient of ILs developed based on fragment charge density distributions obtained using the COSMO-SAC model. , The reason for selecting the COSMO-SAC model is that it can generate the charge density distribution’s profile, namely, σ profiles that are called molecular fingerprints, which are identical to the human fingerprints and are unique . Moreover, the fragment charge density distributions separated by various intervals are unique.…”

Section: Introductionmentioning

confidence: 99%

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Predicting the Thermal Conductivity of Ionic Liquids Using a Quantitative Structure–Property Relationship

Ren

Song

et al. 2022

Ind. Eng. Chem. Res.

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Thermal conductivity (λ) is an extremely crucial indicator of the heat transfer capability of ionic liquids (ILs) and plays a critical function in their industrial applications. In this study, there are two descriptors for model construction, namely, the charge density distribution area of ions at a specific interval (S σi) obtained using the conductor-like screening model for the segment activity coefficient (COSMO-SAC) and the cavity volume of ILs (V cosmo). Using the multiple linear regression (MLR) approach, a quantitative structure–property relationship (QSPR) model was proposed to describe the thermal conductivity of ILs. Furthermore, 606 experiment data points for 44 ILs at different temperatures and pressures were collected from the literature, which were randomly divided into a training set and a testing set for feasibility analysis. For the model built by the total data, its determination coefficients (R 2), root mean square error (RMSE), and average absolute relative deviation (AARD) are 0.9713, 0.004304, and 2.18%, respectively; thus, the developed λ-QSPR model offers a relatively good prediction of λ for ILs. Meanwhile, the percentage of extraterritorial points in the model’s application domain (AD) analysis is only 3.80% and the double extraterritorial region is blank. Overall, the proposed model reproduces the change of λ with temperature (T) and pressure (p) well and outperforms other models of similar type. Moreover, it provides an effective approach to predicting the thermal conductivity of ILs.

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Section: Dataset Of Thermal Conductivitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Predicting the Thermal Conductivity of Ionic Liquids Using a Quantitative Structure–Property Relationship

Ren

Song

et al. 2022

Ind. Eng. Chem. Res.

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“… 11 − 13 In QSPR, the quantitative relationship among the physicochemical properties, biological properties, and molecular structures of compounds is explored with various statistical methods and mathematical models. 14 , 15 Usually, the molecular descriptors were selected as inputs of the models. 16 In previous studies, the main methods used in the QSPR model include multivariable linear regression (MLR), artificial neural network (ANN), Gaussian process (GP), and support vector machine (SVM).…”

Section: Introductionmentioning

confidence: 99%

“…To replace traditional mechanistic models, many researchers turned to the quantitative structure–property relationship (QSPR) model. − In QSPR, the quantitative relationship among the physicochemical properties, biological properties, and molecular structures of compounds is explored with various statistical methods and mathematical models. , Usually, the molecular descriptors were selected as inputs of the models . In previous studies, the main methods used in the QSPR model include multivariable linear regression (MLR), artificial neural network (ANN), Gaussian process (GP), and support vector machine (SVM). , However, the complex correlation between molecular descriptors and high-dimensional nonlinear data required for dissolution prediction poses great difficulties in traditional machine learning methods …”

Section: Introductionmentioning

confidence: 99%

Prediction of the Aqueous Solubility of Compounds Based on Light Gradient Boosting Machines with Molecular Fingerprints and the Cuckoo Search Algorithm

Chen

Zhang

et al. 2022

ACS Omega

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Aqueous solubility is one of the most important physicochemical properties in drug discovery. At present, the prediction of aqueous solubility of compounds is still a challenging problem. Machine learning has shown great potential in solubility prediction. Most machine learning models largely rely on the setting of hyperparameters, and their performance can be improved by setting the hyperparameters in a better way. In this paper, we used MACCS fingerprints to represent the structural features and optimized the hyperparameters of the light gradient boosting machine (LightGBM) with the cuckoo search algorithm (CS). Based on the above representation and optimization, the CS-LightGBM model was established to predict the aqueous solubility of 2446 organic compounds and the obtained prediction results were compared with those obtained with the other six different machine learning models (RF, GBDT, XGBoost, LightGBM, SVR, and BO-LightGBM). The comparison results showed that the CS-LightGBM model had a better prediction performance than the other six different models. RMSE, MAE, and R 2 of the CS-LightGBM model were, respectively, 0.7785, 0.5117, and 0.8575. In addition, this model has good scalability and can be used to solve solubility prediction problems in other fields such as solvent selection and drug screening.

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“…The COSMO-SAC model can be used to obtain the charge density distribution (σ-profile) and cavity volume ( V COSMO ). The charge density distribution area of molecules in a specific interval ( S σ i ) obtained from the σ-profile can be used as a structural descriptor reflecting the interactions, and the obtained V COSMO can be used as a structural descriptor reflecting the size of the molecular volume. ,, Consequently, a unique set of descriptors for the molecular structure can be obtained directly from the molecular structure.…”

Section: Introductionmentioning

confidence: 99%

Predicting the Self-Diffusion Coefficient of Liquids Based on Backpropagation Artificial Neural Network: A Quantitative Structure–Property Relationship Study

Zeng

Ren

Xiao

et al. 2022

Ind. Eng. Chem. Res.

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The self-diffusion coefficient of pure liquids, a fundamental transport property, is involved in a wide range of applications. Many methods have been employed to study the self-diffusion coefficient, with the most popular being semiempirical models. The quantitative structure–property relationship (QSPR) has been widely used to predict various physicochemical properties of substances, but the appropriate molecular descriptors must be selected first. In this study, the charge density distribution area of molecules at a specific interval (S σi ) and cavity volume (V COSMO) was determined based on the conductor-like screening model for the segment activity coefficient (COSMO-SAC). Using these molecular descriptors, a backpropagation artificial neural network (BP-ANN) method was employed to construct a nonlinear QSPR model that can predict the self-diffusion coefficients of pure liquids under normal pressure. The data set used included 2596 data points for 238 compounds, covering a self-diffusion coefficient range of 8.74 × 10–13 to 8.66 × 10–9 m2·s–1 and a temperature range of 90.5–475.1 K. The coefficients of determination (R 2) of the BP-ANN model on the training, validation, and testing sets were all greater than 0.99. For the entire data set, the R 2, absolute average relative deviation (AARD), and root mean square error (RMSE) were 0.9940, 7.09%, and 0.1106, respectively. In an application domain (AD) analysis, 94.67% of the data were within the AD range of the model. Consequently, the model developed in this study can satisfactorily predict the self-diffusion coefficients of liquids.

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Prediction of Infinite Dilution Molar Conductivity for Unconventional Ions: A Quantitative Structure–Property Relationship Study

Cited by 6 publications

References 55 publications

Predicting the Thermal Conductivity of Ionic Liquids Using a Quantitative Structure–Property Relationship

Predicting the Thermal Conductivity of Ionic Liquids Using a Quantitative Structure–Property Relationship

Prediction of the Aqueous Solubility of Compounds Based on Light Gradient Boosting Machines with Molecular Fingerprints and the Cuckoo Search Algorithm

Predicting the Self-Diffusion Coefficient of Liquids Based on Backpropagation Artificial Neural Network: A Quantitative Structure–Property Relationship Study

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