Mathematical Modeling of the Solubility of Carbon Dioxide in Deep Eutectic Solvents

Diyala Journal of Engineering Sciences Pub Date : 2023-03-01 DOI:10.24237/djes.2023.16106

Shahla Z. Ahmad, Arkan J. Hadi, Shagull M. Ali

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Abstract

The increase in energy consumption, along with an increase in human population and industrial activities after the industrial revolution, has caused to increase in the consumption of fossil fuels. Carbon dioxide from fossil fuels has the most significant effect on the production of greenhouse gases and global warming. The absorption of CO2 emitted into the atmosphere is the most crucial method to reduce carbon dioxide in the air. Recently, a new solvent has been developed to absorb greenhouse gases under the name of deep eutectic solvents (DES). These solvents are biodegradable, non-toxic, or low-toxic compounds that are easily obtained. A mathematical model based on the Peng–Robinson (PR) equation of state (EOS) with three different mixing rules Modified van der Waal's (M1), Quadratic (M2) and Wong Sandler (M3) was developed to correlate the CO2 solubility in six types of DESs. The model was validated and compare with the obtained experimental data reported in the literature at temperatures (293.15 – 333.15) K and pressure (0.405 – 30.408) bar. The experimental and calculated data of PR EOS with three mixing rules were generally in a good agreement by obtaining % AARD a round (0.08 – 8.08), (0.05 – 7.58) and (0.09 – 6.56) for M1, M2 and M3 respectively, and the best results with less %AARD was obtained from Wong-Sandler mixing rule in the most of cases.

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二氧化碳在深共晶溶剂中溶解度的数学模型

能源消耗的增加，以及工业革命后人口和工业活动的增加，导致了化石燃料消耗的增加。化石燃料产生的二氧化碳对温室气体的产生和全球变暖的影响最为显著。吸收排放到大气中的二氧化碳是减少空气中二氧化碳的最关键的方法。近年来，一种新的吸收温室气体的溶剂被开发出来，称为深共晶溶剂(DES)。这些溶剂是可生物降解的、无毒的或低毒的化合物，很容易获得。基于3种不同混合规则的Peng-Robinson (PR)状态方程(EOS)(修正范德华(M1)、二次元(M2)和Wong Sandler (M3))，建立了6种DESs中CO2溶解度的数学模型。在温度(293.15 ~ 333.15)K和压力(0.405 ~ 30.408)bar条件下，对模型进行了验证，并与文献报道的实验数据进行了比较。3种混合规则下的PR - EOS实验数据与计算数据基本一致，M1、M2和M3分别获得了0.08 ~ 8.08、0.05 ~ 7.58和0.09 ~ 6.56 %的AARD，且大多数情况下以Wong-Sandler混合规则获得了较低AARD的最佳结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Diyala Journal of Engineering Sciences

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