Parametric Study on the Performance of Amino Silica Hollow Fiber-Based Rapid Temperature Swing Adsorption Cycle for CO<sub>2</sub> Capture: A Multiobjective Optimization

Hosseini, Seyedeh Fatemeh; Khademi, Mohammad Hasan; Talaie, Mohammad Reza; Aghamiri, Seyedfoad

doi:10.1021/acs.energyfuels.3c03987

Energy Fuels

2024

DOI: 10.1021/acs.energyfuels.3c03987

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Parametric Study on the Performance of Amino Silica Hollow Fiber-Based Rapid Temperature Swing Adsorption Cycle for CO₂ Capture: A Multiobjective Optimization

Seyedeh Fatemeh Hosseini,

Mohammad Hasan Khademi,

Mohammad Reza Talaie

et al.

Abstract: Recently, CO 2 capture has been given attention as an effective way to mitigate the impacts of global warming. However, CO 2 capture through adsorption technology is restricted by the cost of energy consumption, and the optimization of this technology deserves to be noted. Rigorous mathematical models along with optimization algorithms result in significant savings in both time and cost of the experiment. In this paper, a purposeful optimization for the rapid temperature swing adsorption (RTSA) cycle using ami… Show more

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Humidity Effects on Sub-Ambient Direct Air Capture of CO₂ with Amine Functionalized Mg-Al LDHs and MMOs

Rim,

Song,

Proaño

et al. 2024

ACS EST Eng.

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Supported amine-based CO 2 capture materials are promising direct air capture (DAC) sorbents due to their high CO 2 uptake capacity, tolerance to varied humidities, and acceptable energy requirements for sorbent regeneration. For the large-scale deployment of supported amine adsorbents for DAC, support materials must be cost-effective and readily available on a large scale. In this study, amine-impregnated Mg x Al-CO 3 layered double hydroxides (LDHs) and Mg x Al-O mixed metal oxides (MMOs) that can be produced with commercially available, earth-abundant chemicals are prepared, and their DAC performance is evaluated under a wide range of temperature (−20 to 25 °C) and humidity (0−85% RH) conditions. Although the 30 wt % poly(ethylenimine) (PEI)-impregnated LDHs and MMOs show moderate 400 ppm CO 2 uptakes (≤1 mmol/g) under dry conditions, impressive adsorption capacities are observed under humid conditions (70% RH) at −20 (3.2 mmol/g) and 25 °C (2.0 mmol/g). Furthermore, the sorbent materials demonstrate promising regenerability during 10 humid DAC cycles at a 25 °C adsorption temperature with a <10% decrease in working capacity. However, a dramatic decrease in working capacity (∼40%) is observed after 10 humid DAC cycles at cold temperatures (−20 °C) due to reduced CO 2 capture kinetics, attributed to amine redistribution. Overall, this study demonstrates the complex behavior that can be observed for an adsorbent over widely varying humidity and temperature conditions, reinforcing the notion that practical adsorbents must be carefully selected for operation in specific climatic zones.

show abstract

Humidity Effects on Sub-Ambient Direct Air Capture of CO₂ with Amine Functionalized Mg-Al LDHs and MMOs

Rim,

Song,

Proaño

et al. 2024

ACS EST Eng.

View full text Add to dashboard Cite

show abstract

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Parametric Study on the Performance of Amino Silica Hollow Fiber-Based Rapid Temperature Swing Adsorption Cycle for CO₂ Capture: A Multiobjective Optimization

Cited by 1 publication

References 58 publications

Humidity Effects on Sub-Ambient Direct Air Capture of CO₂ with Amine Functionalized Mg-Al LDHs and MMOs

Humidity Effects on Sub-Ambient Direct Air Capture of CO₂ with Amine Functionalized Mg-Al LDHs and MMOs

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Parametric Study on the Performance of Amino Silica Hollow Fiber-Based Rapid Temperature Swing Adsorption Cycle for CO2 Capture: A Multiobjective Optimization

Cited by 1 publication

References 58 publications

Humidity Effects on Sub-Ambient Direct Air Capture of CO2 with Amine Functionalized Mg-Al LDHs and MMOs

Humidity Effects on Sub-Ambient Direct Air Capture of CO2 with Amine Functionalized Mg-Al LDHs and MMOs

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Parametric Study on the Performance of Amino Silica Hollow Fiber-Based Rapid Temperature Swing Adsorption Cycle for CO₂ Capture: A Multiobjective Optimization

Humidity Effects on Sub-Ambient Direct Air Capture of CO₂ with Amine Functionalized Mg-Al LDHs and MMOs

Humidity Effects on Sub-Ambient Direct Air Capture of CO₂ with Amine Functionalized Mg-Al LDHs and MMOs