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Preparation of a Cu-BTC/pan electrospun film with a good air filtration performance

Copper-1,3,5-benzoic acid (Cu BTC) was synthesized by the hydrothermal method, which had regular octahedral morphology. Cu-BTC particles were used as additives in the polyacrylonitrile (PAN) solution to fabricate Cu-BTC/PAN membrane by the electrostatic spinning method, its good filtration performance was witnessed experimentally.
PAPER REVISED: 2020-05-28
PAPER ACCEPTED: 2020-05-28
  1. Fisher, J.E., et al. Physical Activity, Air Pollution and the Risk of Asthma and Chronic Obstructive Pulmonary Disease. American Journal of Respiratory and Critical Care Medicine, 194(2016), 7, pp.855-865.
  2. Thavasi, V., et al. Electrospun nanofibers in energy and environmental applications. Energy & Environmental Science, 1(2008), 2, pp.205-221.
  3. Lee, E.S., et al. Evaluation of a High Efficiency Cabin Air (HECA) Filtration System for Reducing Particulate Pollutants Inside School Buses. Environmental Science & Technology; 49(2015), 6, pp. 3358-3365.
  4. Novoselov, K.S., et al. Two-dimensional gas of massless Dirac fermions in graphene. Nature; 438(2005), 7065, pp. 197-200.
  5. Novoselov, K.S., et al. Unconventional quantum Hall effect and Berry's phase of 2π in bilayer graphene. Nature Physics; 2(2006), 3, pp. 177-180.
  6. Li, X.X. & He, J.H. Bubble electrospinning with an auxiliary electrode and an auxiliary air flow. Recent Patents on Nanotechnology; 14(2020), 1, pp. 42-45
  7. Li, Y., & He, J.-H. Fabrication and characterization of ZrO2 nanofibers by critical bubble electrospinning for high-temperature-resistant adsorption and separation. Adsorption Science & Technology; 37(2019), 5-6, pp. 425-437
  8. Cheng, T.T., et al. Effect of surface-active agent on bubble-electrospun polyacrylonitrile nanofibers. Thermal Science; 23(2019), 4, pp. 2481-2487.
  9. Li, X.X., et al. The effect of sonic vibration on electrospun fiber mats. Journal of Low Frequency Noise Vibration and Active Control; 38(2019), 3-4, pp. 1246-1251.
  10. He, C.H., et al. Taylor series solution for fractal Bratu-type equation arising in electrospinning process. Fractals; 28(2020), 1, pp. 2189-2193.
  11. Xu, G.J., et al. Accurate fabrication of aligned nanofibers via a double-nozzle near-field electrospinning. Thermal Science; 23(2019), 4, pp.2143-2150.
  12. Yu, D.N, et al. Wetting and supercontraction properties of spider-based nanofibers. Thermal Science; 23(2019), 4, pp. 2189-2193.
  13. Tian, D., et al. Sea-silk based nanofibers and their diameter prediction. Thermal Science; 23(2019), 4, pp.2253-2256.
  14. He, C.H., et al. Effect of concentration of metal inorganic salt on fiber diameter in electrospinning process mathematical model and experimental verification. Thermal Science; 22(2018), 6, pp.2565-2570.
  15. Li, X.X., et al. Thermal property of rock powder-based nanofibers for high temperature filtration and adsorption. Thermal Science; 23(2019), 4, pp. 2501-2507.
  16. He, J.H. Advances in Bubble Electrospinning. Recent Patents on Nanotechnology; 13(2019), 3, pp.162-163
  17. He JH. From Micro to Nano and from Science to Technology: Nano Age Makes the Impossible Possible. Micro and Nanosystems; 12(2020), 1, pp. 2-3.
  18. Jin, C., et al. Deriving carbon atomic chains from graphene. Physical Review Letters; 102(2009), 20, Article number. 205501
  19. Chui, S.S. A Chemically Functionalizable Nanoporous Material
  20. Kuppler, R.J., et al. Potential applications of metal-organic frameworks. Coordination Chemistry Reviews; 253(2009), 23-24, pp. 3042-3066.
  21. Hoskins, B.F., & Robson, R. Infinite polymeric frameworks consisting of three dimensionally linked rod-like segments. Journal of the American Chemical Society; 111(1989), 15, pp.5962-5964.
  22. Liang, Z., et al. CO2 Adsorption-Based Separation by Metal Organic Framework (Cu-BTC) versus Zeolite (13X). Energy & Fuels; 23(2009), 5, pp. 2785-2789.
  23. Luz, I., et al. Bridging homogeneous and heterogeneous catalysis with MOFs: Cu-MOFs as solid catalysts for three-component coupling and cyclization reactions for the synthesis of propargylamines, indoles and imidazopyridines. Journal of Catalysis; 285(2012), 1, pp.285-291.
  24. Zhang, H., et al. A thermodynamic tank model for studying the effect of higher hydrocarbons on natural gas storage in metal-organic frameworks. Energy Environ. Sci.; 8(2015), 5, pp.1501-1510.
  25. Davydovskaya, P., et al. Work function based gas sensing with Cu-BTC metal-organic framework for selective aldehyde detection. Sensors and Actuators B: Chemical; 187(2013), pp. 142-146.
  26. Li, R., et al. Integration of an Inorganic Semiconductor with a Metal-Organic Framework: A Platform for Enhanced Gaseous Photocatalytic Reactions. Advanced Materials; 26(2014), 28, pp. 4783-4788.
  27. Choi, K.M., et al. Supercapacitors of Nanocrystalline Metal-Organic Frameworks. ACS Nano; 8(2014), 7, pp.7451-7457.
  28. Yang, C.F., et al. Existence Criterion of Three-Dimensional Regular Copper-1,3,5-Phenyltricarboxylate (Cu-BTC) Microparticles. Journal of Donghua University; 37(2020), 2, pp.116-120.
  29. Yin, J., et al. Numerical approach to high-throughput of nanofibers by a modified bubble-electrospinning. Thermal Science; 24(2020), 4, pp. 2367-2375.
  30. Ahmed, A., Xu, L. Numerical analysis of the electrospinning process for fabrication of composite fibers. Thermal Science; 24(2020), 4, pp.2377-2383.
  31. Li, X.X., et al. Nanofibers membrane for detecting heavy metal ions. Thermal Science; 24(2020), 4, pp.2463-2468.
  32. Wu, Y.K., Liu, Y. Fractal-like multiple jets in electrospinning process. Thermal Science; 24(2020), 4, pp. 2499-2505.
  33. He, C.H., et al. Taylor series solution for fractal Bratu-type equation arising in electrospinning process. Fractals; 28(2020), 1, 2050011
  34. He JH. On the height of Taylor cone in electrospinning. Results in Physics; 17(2020), June, Article 103096
  35. Zhang, H., et al. A thermodynamic tank model for studying the effect of higher hydrocarbons on natural gas storage in metal-organic frameworks. Energy & Environmental Science; 8(2015), 5, pp. 1501-1510.
  36. Caudo, S., et al. Cu-MOF: a new highly active catalyst for WHPCO of waste water from agro-food production. Studies in Surface Science and Catalysis; 170(2007): 2054-2059.
  37. Szanyi, J., et al. Well-studied Cu-BTC still serves surprises: evidence for facile Cu2+/Cu+ interchange. Physical Chemistry Chemical Physics; 14(2012), 13, Article Number: 4383.
  38. Ameloot R, Pandey L, Alaerts L, et al. Patterned film growth of metal-organic frameworks based on galvanic displacement. Chemical Communications 2010; 46(21): 3735.
  39. Hartmann, M., et al. Adsorptive Separation of Isobutene and Isobutane on Cu3(BTC)2. Langmuir; 24(2008), 16, pp. 8634-8642.