Experimental Measurements and Molecular Simulation of Carbon Dioxide Adsorption on Carbon Surface

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Ibrahim Gomaa, Javier Guerrero, Zoya Heidari, D. Nicolas Espinoza
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Abstract

Summary Geological sequestration of carbon dioxide (CO2) in depleted gas reservoirs represents a cost-effective solution to mitigate global carbon emissions. The surface chemistry of the reservoir rock, pressure, temperature, and moisture content are critical factors that determine the CO2 adsorption capacity and storage mechanisms. Shale-gas reservoirs are good candidates for this application. However, the interactions between CO2 and organic content still need further investigation. The objectives of this paper are to (i) experimentally evaluate the adsorption isotherm of CO2 on activated carbon, (ii) quantify the nanoscale interfacial interactions between CO2 and the activated carbon surface using Monte Carlo (MC) and molecular dynamic (MD) simulations, (iii) evaluate the modeling reliability using experimental measurements, and (iv) quantify the influence of temperature and geochemistry on the adsorption behavior of CO2 on the surface of activated carbon. These objectives aim at obtaining a better understanding of the behavior of CO2 injection and storage in the kerogen structure of shale-gas formations, where activated carbon is used as a proxy for thermally mature kerogen. We performed experimental measurements, grand canonical Monte Carlo (GCMC) simulations, and MD simulations of CO2 adsorption and diffusion on activated carbon. The experimental work involved measurements of the high-pressure adsorption capacity of activated carbon using pure CO2 gas at a temperature of 300 K. The simulation work started with modeling and validating an activated carbon structure by calibrating the GCMC simulations with experimental CO2 adsorption measurements. Then, we extended the simulation work to quantify the adsorption isotherms at a temperature range of 250–500 K and various surface chemistry conditions. Moreover, CO2 self-diffusion coefficients were quantified at gas pressures of 0.5 MPa, 1 MPa, and 2 MPa using MD simulations. The experimental results showed a typical CO2 excess adsorption trend for the nanoporous structures, with a density of the sorbed gas phase of 504.76 kg/m3. The simulation results were in agreement with experimental adsorption isotherms with a 10.6% average absolute relative difference. The self-diffusion results showed a decrease in gas diffusion with increasing pressure due to the increase in the adsorbed gas amount. Increasing the simulation temperature from 300 K to 400 K led to a decrease in the amount of adsorbed CO2 molecules by about 87% at 2 MPa pressure. Finally, the presence of charged functional groups (e.g., hydroxyl–OH and carboxyl–COOH) led to an increase in the adsorption of CO2 gas to the activated carbon surface. The outcomes of this paper provide new insights about the parameters affecting CO2 adsorption and sequestration in depleted shale-gas reservoirs. This in turn helps in screening the candidate shale-gas reservoirs for carbon capture, sequestration, and storage to maximize the CO2 storage capacity.
二氧化碳在碳表面吸附的实验测量与分子模拟
枯竭气藏中二氧化碳的地质封存是减少全球碳排放的一种经济有效的解决方案。储层岩石的表面化学性质、压力、温度和含水率是决定CO2吸附能力和储存机制的关键因素。页岩气储层是该应用的理想选择。然而,CO2与有机含量之间的相互作用仍需进一步研究。本文的目标是:(i)实验评估CO2在活性炭表面的吸附等温线,(ii)使用蒙特卡罗(MC)和分子动力学(MD)模拟量化CO2与活性炭表面之间的纳米级界面相互作用,(iii)使用实验测量评估建模的可靠性,以及(iv)量化温度和地球化学对活性炭表面CO2吸附行为的影响。这些目标旨在更好地了解页岩气地层干酪根结构中二氧化碳的注入和储存行为,其中活性炭被用作热成熟干酪根的代表。我们进行了实验测量、大规范蒙特卡罗(GCMC)模拟和MD模拟CO2在活性炭上的吸附和扩散。实验工作包括使用纯CO2气体在300 K温度下测量活性炭的高压吸附能力。模拟工作从建模和验证活性炭结构开始,通过校准GCMC模拟和实验二氧化碳吸附测量。然后,我们扩展了模拟工作,量化了250-500 K温度范围和不同表面化学条件下的吸附等温线。在0.5 MPa、1 MPa和2 MPa的气体压力下,利用MD模拟方法量化CO2自扩散系数。实验结果表明,纳米孔结构具有典型的CO2过量吸附趋势,吸附气相密度为504.76 kg/m3。模拟结果与实验吸附等温线基本一致,平均绝对相对差为10.6%。自扩散结果表明,随着压力的增加,气体的扩散减小,这是由于吸附气体量的增加。将模拟温度从300 K提高到400 K,在2 MPa压力下,吸附CO2分子的数量减少了约87%。最后,带电官能团(如羟基- oh和羧基- cooh)的存在导致二氧化碳气体在活性炭表面的吸附增加。研究结果对枯竭页岩气储层中影响CO2吸附和封存的参数提供了新的认识。这反过来又有助于筛选候选页岩气储层进行碳捕获、封存和储存,以最大限度地提高二氧化碳的储存能力。
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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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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