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KAUST-7 Powder Metal Organic Frameworks (MOFs)

CAS: 1973399-07-3

KAUST-7 is also known as NbOFFIVE-1-Ni. KAUST-7 has longer Nb–O and Nb–F distances compared to Si–F (1.899 Å for Nb–F vs. 1.681 Å for Si–F). This resulted in larger anionic octahedra pillaring the square grid thus reducing the pore size. KAUST-7 have attracted widespread attention because of their high chemical stability and thermal stability, outstanding tolerance with water and H2S, and high CO2 adsorption selectivity over H2 and CH4

    Model Number

    KAR-F32

    Product Name

    KAUST-7

    Particle size

    0.6~1.1μm

    Specific surface area

    ≥200㎡/g

    Pore size

    0.3~0.5 nm

    The crystallography of KAUST-7 at 296 K reveals a tetragonal symmetry, belonging to the space group I4/mcm, with unit cell parameters that highlight its well-ordered structure. The unit cell dimensions, with 'a' and 'b' equaling 9.942(4) Å and 'c' measuring 15.764(6) Å, contribute to the material's distinctive pore architecture. This fine-tuning of the pore dimensions is pivotal for enhancing CO2 interaction, particularly in terms of the enthalpy of absorption, a critical factor for selective gas adsorption processes.

    KAUST-7 has garnered significant attention in the scientific community due to a multitude of desirable properties. Its high chemical and thermal stability, coupled with exceptional water and H2S tolerance, positions it as a robust candidate for applications in harsh environments. Moreover, the material's high CO2 adsorption selectivity over H2 and CH4 makes it an attractive option for carbon capture and storage initiatives, which are essential for mitigating the impact of greenhouse gas emissions.

    KAR-F32   KAUST-7

    In terms of physical attributes, KAUST-7 is available in a particle size range of 1000-5000 nm, offering a substantial specific surface area of at least 170 ㎡/g. The pore size of 0.3-0.5 nm is finely tuned for molecular sieving, enabling the selective adsorption of gases, which is vital for various separation processes in industrial applications.

    The development of KAUST-7 underscores the ongoing advancements in the field of MOFs, highlighting the potential for designing materials with tailored properties to address specific challenges in gas storage, separation, and environmental management. As research progresses, the unique characteristics of KAUST-7 are expected to play a significant role in the development of sustainable technologies that can contribute to a cleaner and more efficient future.

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