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Decoding local framework dynamics in the ultra-small pore MOF MIL-120(Al) CO2 adsorbent using machine-learning

Dong Fan1,2, Felipe Lopes Oliveira2, Satyanarayana Bonakala2

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|February 26, 2026
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Summary
This summary is machine-generated.

Ultra-small pore metal-organic frameworks (MOFs) show dynamic behavior crucial for CO2 capture. Accurately modeling hydroxyl group dynamics improves predictions of gas adsorption in these materials.

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Area of Science:

  • Materials Science
  • Computational Chemistry
  • Chemical Engineering

Background:

  • Metal-organic frameworks (MOFs) with ultra-small pores are promising for gas capture, particularly CO2.
  • The local dynamics of MOF frameworks, including functional groups and nodes, significantly influence gas sorption properties.
  • Understanding these dynamics is essential for designing efficient MOF-based capture systems.

Purpose of the Study:

  • To investigate the local dynamics of bridging hydroxyl groups (μ2-OH) in the ultra-small pore MOF MIL-120(Al).
  • To assess the impact of these dynamics on CO2 adsorption behavior using advanced computational methods.
  • To establish the importance of local structural dynamics for accurate MOF performance prediction.

Main Methods:

  • Density Functional Theory (DFT) calculations were employed.
  • A purpose-trained machine-learning potential (MLP) was developed and utilized.
  • Grand canonical Monte Carlo (GCMC) and GCMC-Molecular Dynamics (GCMC-MD) simulations were performed.

Main Results:

  • Six distinct μ2-OH configurations with low interconversion barriers were identified, indicating significant room-temperature dynamics.
  • Adsorption isotherms and low-pressure behavior were found to be sensitive to μ2-OH ordering and framework relaxation.
  • MLP-driven GCMC-MD simulations accurately captured framework relaxation and dynamic μ2-OH reorientation under CO2 loading, unlike rigid force-field methods.

Conclusions:

  • Local structural dynamics, specifically the reorientation of bridging hydroxyl groups, are critical for accurately describing guest molecule locations and energetics in ultra-small pore MOFs.
  • Accurate modeling of MOF dynamics is essential for reliable predictions of CO2 capture performance.
  • This study highlights the necessity of incorporating framework flexibility and local dynamics into simulations for advanced materials design.