Comparative Evaluation of Fe-MOF, Cu-MOF, and Bimetallic Fe/Cu-MOF for Enhanced CO₂ Adsorption: Synthesis, Characterization, and Performance Analysis

Nor Khonisah binti Daud; Hamidah binti Abdullah; Nur Aminatulmimi binti Ismail

doi:10.9767/bcrec.20658

DOI: https://doi.org/10.9767/bcrec.20658

Comparative Evaluation of Fe-MOF, Cu-MOF, and Bimetallic Fe/Cu-MOF for Enhanced CO₂ Adsorption: Synthesis, Characterization, and Performance Analysis

Nor Khonisah binti Daud , Hamidah binti Abdullah, Nur Aminatulmimi binti Ismail

Faculty of Chemical & Process Engineering Technology, Universiti Malaysia Pahang Al-Sultan Abdullah, Lebuh Persiaran Tun Khalil Yaakob, 26300 Kuantan, Malaysia

Received: 28 Jan 2026; Revised: 25 Feb 2026; Accepted: 26 Feb 2026; Available online: 12 Mar 2026; Published: 30 Aug 2026.

Editor(s): Istadi Istadi

This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.

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@article{BCREC20658,
    author = {Nor Khonisah Daud and Hamidah Abdullah and Nur Aminatulmimi Ismail},
    title = {Comparative Evaluation of Fe-MOF, Cu-MOF, and Bimetallic Fe/Cu-MOF for Enhanced CO₂ Adsorption: Synthesis, Characterization, and Performance Analysis},
    journal = {Bulletin of Chemical Reaction Engineering & Catalysis},
  volume = {0},
    number = {0},
    year = {2026},
    keywords = {CO2 emission; Carbon capture; CO2 adsorption; Metal-Organic Frameworks adsorbents},
    abstract = { Rising atmospheric CO₂ concentrations necessitate the development of efficient and economically viable carbon capture materials. Metal-organic frameworks (MOFs) offer strong potential due to their tunable pore structures and accessible metal sites. In this work, Fe-MOF, Cu-MOF, and bimetallic Fe/Cu-MOF were synthesized via a solvothermal route and systematically evaluated for CO₂ adsorption performance. The materials were characterized using SEM-EDX, FTIR, XRD, BET, and TGA to establish correlations between structural properties and adsorption behavior. CO₂ uptake was investigated under varying pressure (1-5 bar), adsorbent dosage (0.2-0.5 g), and temperature (40-50 °C). Among the three adsorbents, Fe/Cu-MOF exhibited the highest adsorption capacity, reaching 3.22 mg g - ¹ at 5 bar, outperforming Fe-MOF (2.54 mg g - ¹) and Cu-MOF (2.35 mg g - ¹). Adsorption increased markedly with pressure, showed non-linear dependence on dosage due to site underutilization and diffusion limitations, and decreased with increasing temperature, indicating an exothermic physisorption-dominated process. BET analysis revealed that Fe/Cu-MOF possessed the highest surface area (19.4 m² g - ¹) and pore volume (0.0489 cm³ g - ¹), while XRD and FTIR confirmed successful incorporation of both metal centers, generating chemically heterogeneous adsorption sites. Kinetic analysis demonstrated that CO₂ uptake follows a pseudo-first-order model, consistent with surface-controlled physisorption. The enhanced performance of Fe/Cu-MOF is attributed to synergistic effects arising from dual-metal coordination, improved pore connectivity, and increased availability of active adsorption domains. These findings highlight the potential of bimetallic Fe/Cu-MOFs as promising candidates for pressurized CO₂ capture applications and provide insight into structure-performance relationships governing gas adsorption in defect-rich MOF systems. },
   issn = {1978-2993},   pages = {2--17}  doi = {10.9767/bcrec.20658},
    url = {https://journal.bcrec.id/index.php/bcrec/article/view/20658}
}

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Abstract

Rising atmospheric CO₂ concentrations necessitate the development of efficient and economically viable carbon capture materials. Metal-organic frameworks (MOFs) offer strong potential due to their tunable pore structures and accessible metal sites. In this work, Fe-MOF, Cu-MOF, and bimetallic Fe/Cu-MOF were synthesized via a solvothermal route and systematically evaluated for CO₂ adsorption performance. The materials were characterized using SEM-EDX, FTIR, XRD, BET, and TGA to establish correlations between structural properties and adsorption behavior. CO₂ uptake was investigated under varying pressure (1-5 bar), adsorbent dosage (0.2-0.5 g), and temperature (40-50 °C). Among the three adsorbents, Fe/Cu-MOF exhibited the highest adsorption capacity, reaching 3.22 mg g^-¹ at 5 bar, outperforming Fe-MOF (2.54 mg g^-¹) and Cu-MOF (2.35 mg g^-¹). Adsorption increased markedly with pressure, showed non-linear dependence on dosage due to site underutilization and diffusion limitations, and decreased with increasing temperature, indicating an exothermic physisorption-dominated process. BET analysis revealed that Fe/Cu-MOF possessed the highest surface area (19.4 m² g^-¹) and pore volume (0.0489 cm³ g^-¹), while XRD and FTIR confirmed successful incorporation of both metal centers, generating chemically heterogeneous adsorption sites. Kinetic analysis demonstrated that CO₂ uptake follows a pseudo-first-order model, consistent with surface-controlled physisorption. The enhanced performance of Fe/Cu-MOF is attributed to synergistic effects arising from dual-metal coordination, improved pore connectivity, and increased availability of active adsorption domains. These findings highlight the potential of bimetallic Fe/Cu-MOFs as promising candidates for pressurized CO₂ capture applications and provide insight into structure-performance relationships governing gas adsorption in defect-rich MOF systems.

Keywords: CO2 emission; Carbon capture; CO2 adsorption; Metal-Organic Frameworks adsorbents

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Section: 3rd International Symposium of Reaction Engineering, Catalysis and Sustainable Energy 2025 (RECASE 2025)

Language : EN

In 2026: Just Accepted Manuscript and Article In Press 2026

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