Metal–organic frameworks (MOFs) are crystalline porous materials formed by the self-assembly of metal ions or clusters and organic ligands. With their tunable structure, high porosity, and large surface area, nano-MOFs are widely applied in gas storage, molecular separation, and heterogeneous catalysis.

J&K Scientific, in collaboration with Professor Yu Fang’s group at Hunan University, proudly provides a series of high-quality Nano MOFs featuring regular morphology, uniform size, and reproducible performance, ideal for advanced materials research and industrial R&D.

Advantages and Usage Guidelines

• Uniform Particle Size and Regular Morphology: ensures reproducibility and stable batch-to-batch quality.
• High Surface Area & Porosity: enables efficient adsorption and catalytic activity.
• Pre-Activation Required: activate at 120 °C for 12 hours before use to achieve optimal results.

These characteristics make Nano MOFs from Prof. Fang Yu’s group an excellent choice for researchers focused on precision, consistency, and high-performance materials.

Featured Products

• Cat. No.：993989  Nano UiO-66

particle size: 100 - 200 nm, surface area: 650 - 700 m²/g, standard-microcrystal

CAS：1072413-89-8

Nano UiO-66 is a type of crystalline porous material composed of Zr6 clusters as metal nodes and terephthalic acid. It is prepared using acetic acid as a modulator. 

Applications: Gas storage, molecular separation, heterogeneous catalysis

Figure 1 UiO-66  Applied to CO2 adsorption[1]         

• Cat. No.：913851  Nano UiO-66-NH2

particle size: 100 - 200 nm, surface area: 800 - 1075 m²/g, standard-microcrystal

CAS：1260119-00-3

Nano UiO-66-NH₂ It is a type of crystalline porous material composed of Zr6 clusters as metal nodes and p-2-amino-phthalic acid. It is prepared by using acetic acid as the modulator.

Applications: Gas storage, molecular separation, heterogeneous catalysis

Figure 2 UiO-66-NH2 is used to catalyze the oxidative desulfurization of dibenzothiophene (DBT) [2]

• Cat. No.：9108416  Nano UiO-67

particle size: 200 - 300 nm, surface area: 1700 - 2000 m²/g, pore volume : 0.8 - 1.0 cm³/g, standard-microcrystal

CAS：1072413-83-2

Nano UiO-67 is a type of crystalline porous material composed of Zr6 clusters as metal nodes and 4,4-biphenyldicarboxylic acid. It is prepared using acetic acid as the modulator.

Applications: Gas storage, molecular separation, heterogeneous catalysis

Figure 3 UiO-67 is applied to the adsorption separation of SF6/N2 mixture [3]

• Cat. No.：9335549  Nano MIL-101

particle size: 100 - 220 nm, surface area: 2800 - 3300 m²/g, pore volume: 2.0 - 2.4 cm³/g, standard-microcrystal

CAS：869288-09-5

Nano MIL-101 is a type of crystalline porous material composed of Cr3 clusters as metal nodes and terephthalic acid.

Applications: Gas storage, molecular separation, heterogeneous catalysis

Figure 4 MIL-101 is used to catalyze the Prince reaction of β-pinene and formaldehyde [4]

• Cat. No.：968382  Nano MOF-808

particle size: 200 - 300 nm, surface area: 1800 - 2000 m²/g, pore volume : 0.8 - 1.0 cm³/g, standard-microcrystal

CAS：1579984-19-2

Nano MOF-808 is a type of crystalline porous material composed of Zr6 clusters as metal nodes and trimesic acid. It is prepared using formic acid as a modulator.

Applications: Gas storage, molecular separation, heterogeneous catalysis

Figure 5 MOF-808 is applied to the adsorption of CO2 in flue gas [5]

• Cat. No.：9335550  Nano PCN-222

particle size: 200 - 300 nm, surface area: 1800 - 2000 m²/g, pore volume: 1.3 - 1.5 cm³/g, standard-microcrystal

CAS：1403461-06-2

Nano PCN-222 is a type of crystalline porous material composed of Zr6 clusters as metal nodes and tetrakis (4-carboxyphenyl) porphyrin.

Applications: Gas storage, molecular separation, heterogeneous catalysis

Figure 6 PCN-222 is used in the photocatalytic oxidation of thioanisole[6]

• Cat. No.：9393308 PCN-128, 99%

CAS：2230488-02-3

PCN-128 is a metal-organic framework material formed by self-assembly of ETTC ligands and Zr6 clusters through coordination bonds. It has two interconvertible configurations (PCN-128-W is white powder; PCN-128-Y is yellow Powder), stable in aqueous solutions, acidic and weak alkali solutions, with high thermal stability.

Applications: Catalysis, gas adsorption separation, sensing and drug loading

References

1. Ahmadijokani F, Ahmadipouya S, Molavi H, et al. Impact of scale, activation solvents, and aged conditions on gas adsorption properties of UiO-66. Journal of Environmental Management, 2020, 274: 111155.
2. Barghi B, Jürisoo M, Volokhova M, et al. Process optimization for catalytic oxidation of dibenzothiophene over UiO-66-NH2 by using a response surface methodology. ACS omega, 2022, 7(19): 16288-16297.
3. Kim M B, Kim T H, Yoon T U, et al. Efficient SF6/N2 separation at high pressures using a zirconium-based mesoporous metal–organic framework. Journal of Industrial and Engineering Chemistry, 2020, 84: 179-184.
4. Vallés-García C, Gkaniatsou E, Santiago-Portillo A, et al. Design of stable mixed-metal MIL-101 (Cr/Fe) materials with enhanced catalytic activity for the Prins reaction. Journal of Materials Chemistry A, 2020, 8(33): 17002-17011.
5. Lyu H, Chen O I F, Hanikel N, et al. Carbon dioxide capture chemistry of amino acid functionalized metal–organic frameworks in humid flue gas. Journal of the American Chemical Society, 2022, 144(5): 2387-2396
6. Zheng D Y, Chen E X, Ye C R, et al. High-efficiency photo-oxidation of thioethers over C 60@ PCN-222 under air. Journal of Materials Chemistry A, 2019, 7(38): 22084-22091.

About Professor Yu Fang

Professor Yu Fang currently serves at the School of Chemistry and Chemical Engineering, Hunan University. He obtained his master’s degree in chemistry from Shanghai Jiao Tong University in 2010 and earned his Ph.D. from the University of Tokyo, Japan, in 2014.

His research journey includes:

• 2014–2015: Postdoctoral research at the University of Tokyo, Japan.
• 2015–2019: Postdoctoral research at Texas A&M University, USA.

Throughout his graduate studies and postdoctoral work, Professor Fang focused on graded pore coordination materials (pore size: 2–50 nm). His work includes:

• Designing new porous coordination cages (PCCs) and mesoporous MOFs (mMOFs).
• Tuning pore structures to control the loading and assembly of guest molecules.
• Advancing energy gas conversion and cancer nanotherapy through precise material engineering.

His research has driven significant progress in MOF-based materials, contributing to more efficient, versatile applications in both energy storage and biomedical fields.