Integration of modern computational chemistry and <scp>ASPEN PLUS</scp> for chemical process design

Tsai, Chang‐Che; Lin, Shiang‐Tai

doi:10.1002/aic.16987

Cited by 7 publications

(6 citation statements)

References 47 publications

(59 reference statements)

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“…The heat of formation is among the most important thermodynamic properties of compounds. It can be used to calculate reaction enthalpies and free energies (when suitably combined with entropy values), which are paramount in a wide variety of applications in chemistry and chemical engineering such as energy storage, [1,2] chemical reaction engineering, [3][4][5] process system design, [6] combustion, [7] electrocatalysis, [8][9][10] and thermochemical and electrochemical stability assessment. [10][11][12][13][14][15][16] However, experimental heats of formation are unavailable for a vast number of compounds.…”

Section: Introductionmentioning

confidence: 99%

Fast Correction of Errors in the DFT‐Calculated Energies of Gaseous Nitrogen‐Containing Species

2021

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Modeling adsorption phenomena on surfaces by DFT calculations often involves substantial errors, resulting in inaccurate predictions of catalytic activities. Such errors partly stem from the inaccurate description of the energetics of free molecules. Herein, we use a semiempirical group-additivity method to correct the DFT-calculated heats of formation of 106 carbonand nitrogen-containing gaseous compounds belonging to 15 different chemical families. PBE, PW91, RPBE and BEEF-vdW initially yield mean absolute errors (MAEs) with respect to experiments in the range of 0.32-0.75 eV. After correcting the systematic errors, the overall MAEs decrease to~0.05 eV. Additionally, upon applying the corrections to three types of reaction enthalpies, the resulting MAEs are below 0.10 eV. These functional-group corrections can be used in (electro)catalysis to correct the gas-phase references necessary to evaluate equilibrium potentials and adsorption energies, predict error cancellation, and assess conflicting experimental data.

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Section: Introductionmentioning

confidence: 99%

Fast Correction of Errors in the DFT‐Calculated Energies of Gaseous Nitrogen‐Containing Species

2021

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“…55 Furthermore, the COSMO-SAC model has already been embedded into the latest version of Aspen Plus software because its program codes are open access (https://www.design.che.vt.edu). 56 2.2.1.1. COSMO-RS Model.…”

Section: Cosmo-based Modelsmentioning

confidence: 99%

“…Thus, in 2018 we proposed the COSMO-RS model, especially for ILs which was embedded into the Amsterdam Modeling Suite software as a separate module named after “ADF Lei 2018” to improve the predictive accuracy for the containing-ILs systems . Furthermore, the COSMO-SAC model has already been embedded into the latest version of Aspen Plus software because its program codes are open access () …”

Section: Predictive Molecular Thermodynamicsmentioning

confidence: 99%

Condensable Gases Capture with Ionic Liquids

Chen

Lei

et al. 2023

Chem. Rev.

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Condensable gases are the sum of condensable and volatile steam or organic compounds, including water vapor, which are discharged into the atmosphere in gaseous form at atmospheric pressure and room temperature. Condensable toxic and harmful gases emitted from petrochemical, chemical, packaging and printing, industrial coatings, and mineral mining activities seriously pollute the atmospheric environment and endanger human health. Meanwhile, these gases are necessary chemical raw materials; therefore, developing green and efficient capture technology is significant for efficiently utilizing condensed gas resources. To overcome the problems of pollution and corrosion existing in traditional organic solvent and alkali absorption methods, ionic liquids (ILs), known as “liquid molecular sieves”, have received unprecedented attention thanks to their excellent separation and regeneration performance and have gradually become green solvents used by scholars to replace traditional absorbents. This work reviews the research progress of ILs in separating condensate gas. As the basis of chemical engineering, this review first provides a detailed discussion of the origin of predictive molecular thermodynamics and its broad application in theory and industry. Afterward, this review focuses on the latest research results of ILs in the capture of several important typical condensable gases, including water vapor, aromatic VOCs (i.e., BTEX), chlorinated VOC, fluorinated refrigerant gas, low-carbon alcohols, ketones, ethers, ester vapors, etc. Using pure IL, mixed ILs, and IL + organic solvent mixtures as absorbents also briefly expanded the related reports of porous materials loaded with an IL as adsorbents. Finally, future development and research directions in this exciting field are remarked.

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“…The effects of solvents on CO 2 hydrogenation reaction have been widely investigated; however, the thermodynamic influence of solvent in condensed state on CO 2 hydrogenation to ethanol under various temperatures and pressures have not yet been well studied. Since calculating the properties of condensed fluid by ab initio methods require a high demand for computational resources, [23] in this work, we used Aspen Plus, which predicts the properties of condensed fluid using engineering thermodynamic models to illustrate the effects of solvents on the thermodynamics of ethanol synthesis by CO 2 hydrogenation under various temperatures and pressure. We found that the dielectric constant and the saturated vapor pressure of the solvent are of critical importance for ethanol synthesis by CO 2 hydrogenation.…”

Section: Introductionmentioning

confidence: 99%

Thermodynamic Analysis of CO₂ Hydrogenation to Ethanol: Solvent Effects

Tang

Liu

et al. 2023

ChemistrySelect

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CO 2 hydrogenation to ethanol presents an important way to reduce CO 2 emissions and mitigate global warming. Since the solvent plays a key role in this reaction (i. e. in a batch reactor), the thermodynamics is investigated herein using an RGibbs model in Aspen Plus to illustrate the effects of solvents with various dielectric constant and vapor pressure. Accordingly, it is found that the solvents possessing a high dielectric constant together with low vapor pressure favor ethanol synthesis thermodynamically. Furthermore, mixing a solvent having a high-dielectric-constant and high vapor pressure with another solvent having a low-dielectric-constant and low vapor pressure promotes ethanol synthesis thermodynamically.

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Integration of modern computational chemistry and ASPEN PLUS for chemical process design

Cited by 7 publications

References 47 publications

Fast Correction of Errors in the DFT‐Calculated Energies of Gaseous Nitrogen‐Containing Species

Fast Correction of Errors in the DFT‐Calculated Energies of Gaseous Nitrogen‐Containing Species

Condensable Gases Capture with Ionic Liquids

Thermodynamic Analysis of CO₂ Hydrogenation to Ethanol: Solvent Effects

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Integration of modern computational chemistry and ASPEN PLUS for chemical process design

Cited by 7 publications

References 47 publications

Fast Correction of Errors in the DFT‐Calculated Energies of Gaseous Nitrogen‐Containing Species

Fast Correction of Errors in the DFT‐Calculated Energies of Gaseous Nitrogen‐Containing Species

Condensable Gases Capture with Ionic Liquids

Thermodynamic Analysis of CO2 Hydrogenation to Ethanol: Solvent Effects

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Product

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Thermodynamic Analysis of CO₂ Hydrogenation to Ethanol: Solvent Effects