A Review on Electro-spun Nanofibers for Air Pollution Control

[Nand Jee Kanu and Subodh Mahadev Kale] Volume 7: Issue 1, April 2020, pp  9 - 18

DOI: 10.26706/IJAEFEA.1.7.20200306

----------------------------------------------------------------------------------------------
Abstract These days air pollution has emerge as greater severe and commenced to have a dramatic impact at the fitness of people in many big towns. usually, out of doors personal protection, together with commercial masks cannot successfully save you the inhalation of many pollution. specific remember (PM) pollutants are specially a critical risk to human fitness. here we introduce a brand-new green air filtration materials and methodologies that can be used for outside in addition to in Indoor air filtration. Sub-microfibers and nanofibers membranes have an excessive surface to extent ratio which makes them suitable for diverse programs such as environmental remediation and filtration, strength production and garage, digital optical sensors, tissue engineering and drug shipping. the fast file affords an outline of cutting-edge situation of nanofibers produced using electro-spinning approach and the one-of-a-kind polymers used for the manufacturing of nanofibers and the improvement procedures.

Index terms - polyacrylonitrile (PAN):TiO2, polyacrylonitrile-Co-polyacrylate (PAN-Co-PMA):TiO2, ZIF-67@PAN filters
---------------------------------------------------------------------------------------------------------------------------------------------
REFERENCES


[1]    D. Ruan, L. Qin, R. Chen, and G. Xu,"Transparent PAN:TiO2 and PAN-coPMA:TiO2 nanofiber composite membranes with High Efficiency in Particulate Matter pollutants filtration", Nanoscale Research Letters, vol 15, pp. 1-8,January 2020.
[2]    P.M. Mannucci and M. Franchini,"Health effects of ambient air pollution in developing countries", International Journal of Environmental Research and Public Health., vol. 14, pp. 1-8, September 2017.
[3]    A. Bałazy, M. Toivola, and A. Adhikari, "Do N95 respirators provide 95% protection level against airborne viruses, and how adequate are surgical masks", Am J Infect Control, vol. 34, pp. 51-57, March 2006.
[4]    M. Loeb , N. Dafoe, J. Mahony,M.John, A.Sarabia, V.Glavin, R.Webby, M.Smieja, D.J. Earn, S. Chong, A. Webb and S.D. Walter, “Surgical mask vs N95 respirator for preventing influenza among health care workers: a randomized trial",JAMA, vol. 302, pp. 1865-1871, January 2009.
[5]    K.M. Sim, H.S. Park, G.N. Bae, and J.H. Jung,"Antimicrobial nanoparticle coated electrostatic air filter with high filtration efficiency and low pressure drop",Sci Total Environ, vol. 533, pp. 266–274, July 2015.
[6]    N. Wang, Y. Si, Wang, G. Sun, M. El-Newehy, S.S. Al-DeyabandB. Ding,"Multilevel structured polyacrylonitrile/silica nanofibrous membranes for high performance air filtration", Separation and Purification Technology, vol. 126, pp. 44–51. April 2014.
[7]    W.W.F. Leung, C.W.Y. Hau and H.F. Choy, "Microfiber-nanofiber composite filter for high-efficiency and low pressure drop under nano-aerosol loading", Separation and Purification Technology, vol. 206, pp. 26-38,  May2018.
[8]    R. Chen, Y. Wan and N. Si, et al,"Bubble rupture in Bubble electrospinning",Thermal Science, vol. 19, pp. 1141-1149, January 2015.
[9]    D. Li,Y. Xia, "Electrospinning of nanofibers: reinventing the wheel", Advanced Materials,  vol. 16, pp. 1151 – 1170. July 2004 .
[10]  R.X. Chen, Y. L and J.H. He,"Mini-review on Bubbfil spinning process for mass-production of nanofibers”, Matéria (Rio de Janeiro), vol. 19, pp. 325-343, October 2014.
[11]  D. H. Reneker,"Bending instability of electrically charged liquid jets of polymer solutions in electrospinning", Journal of Applied Physics, vol. 87 pp. 4531-4547, May 2000.
[12]  J. Hromadka,S. Korposh, M.C. Partridge, S.W. James, F.Davis,D. Crump and R.P. Tatam,"Multi-parameter measurements using optical fibre long period gratings for indoor air quality monitoring”, Sensors and Actuators B: Chemical, vol. 244, pp. 217–225, June 2017.
[13]  C.Liu, P.C. Hsu, H.W. Lee,M. Ye, G.Y. Zheng, N.Liu, W..Li and Y. Cui, "Transparent air filter for high-efficiency PM2.5 capture",Nature Communications, vol. 6, pp. 6205–6214, February 2015.
[14]  X. Liu, K.Gan, H. Liu, X. Song, T. Chen andC.Liu, "Antibacterial properties of nano-silver coated PEEK prepared through magnetron sputtering", Dental Mater vol. 33, pp. 348–360, September 2017.
[15]  B. Grabas, "An evaluation of the use of laser-vibration melting to increase the surface roughness of metalobjects",Archives of Metallurgy and Mateials, vol. 60, pp. 33–39, March 2015.
[16]  Ü. Özgür, Y.I. Alivov,C. Liu, A. Teke, M.A. Reshchikov, S. Doğan, V. Avrutin,S. Cho and H. Morkoç,"A comprehensive review of ZnO materials and devices" Journal of Applied Physics, vol. 98, pp. 1–11.August 2005.
[17]  G. Williams, B. Seger and P.V. Kamat,"TiO2-graphene nanocomposites. UV assisted photocatalytic reduction of graphene oxide", ACS Nano vol. 2, pp. 1487– 1491, August 2008.
[18]  D. Chen, L. Wei, L. Meng, D. Wang , Y. Chen, Y.Tian, S. Yan, L. Mei and J.  Jiao,"High-Performance Self-Powered UV Detector Based on SnO2-TiO2 Nanomace Arrays", Nanoscale Research Letters vol. 13,  pp. 1–7, April 2018.
[19]  R. Zhang, J. Jing, J. Tao, S.C. Hsu, G. Wang, J. Cao,C.S.L. Lee,L. Zhu, Z.Chen, Y.Zhao and Z. Shen,"Chemical characterization and source apportionment of PM2.5 in Beijing: seasonal perspective",Atmospheric Chemistry and Physics, vol. 13, pp. 7053–7074, July 2013.
[20]  H. Wang, Y. Zhuang, Y. Wang, Y. Sun, H.Yuan, G. Zhuang andZ. Hao,"Long-term monitoring and source apportionment of PM2.5/PM10 in Beijing, China", Journal of Environmental Sciences, vol. 20, pp. 1323–1327, April 2008.
[21]  X. Han andL.P. Naeher,"A review of traffic-related air pollution exposure assessment studies in the developing world", Environment International, vol. 32, pp. 106–120, January 2006.
[22]  M. M. Maricq, "Chemical characterization of particulate emissions from diesel engines: a review",Journal of Aerosol Science, vol. 38, pp. 1079–1118, November 2007.
[23]  J. C. Chow,"Health effects of fine particulate air pollution: lines that connect",Journal of the Air & Waste Management Association, vol. 56, pp. 707–708, February 2012.
[24]  M. Natalie,"Aerosol indirect effect on biogeochemical cycles and climate", Science, vol. 334, pp. 794–796, November 2011.
[25]  D.E.Horton, C.B.Skinner, D.Singh and N.S.Diffenbaugh “Occurrence and persistence of future atmospheric stagnation events.” Nature climate change, vol. 4, pp. 698–703, August 2014.
[26]  R.Betha, S.N.Behera and R.Balasubramanian “Southeast Asian smoke haze: fractionation of particulate-bound elements and associated health risk.” Environmental Science & Technology, vol. 48, pp. 4327–4335, March 2014.
[27]  R. D. Brook, S. Rajagopalan, Pope C. A. J. R. Brook, A. Bhatnagar, A, V, Diez-Roux, F, Holguin, Y, Hong, R. V. Luepker, M. A. Mittleman, A. Peters, D. Siscovick, Jr S. C. Smith, L. Whitsel and J. D. Kaufman, “A Metabolism, Particulate matter air pollution and cardiovascular disease: an update to the scientific statement from the American Heart Association.”National Library of Medicine, vol. 121, pp. 2331–2378, May 2010.
[28]  S. C. Anenberg, L. W. Horowitz, D. Q. Tong and J. J. West, “An estimate of the global burden of anthropogenic ozone and fine particulate matter on premature human mortality using atmospheric modeling.”Environmental health perspectives, vol.  118, pp. 1189–1195 Septemper 2010.
[29]  K. Timonen, E. Vanninen, J. de Hartog, A. Ibald-Mulli, A. Brunekreef, D. R. Gold, J. Heinrich, G. Hoek, T. Lanki, A. Peters, T. Tarkiainen, P. Tiittanen, W. Kreylingandand J.  Pekkanen, “Effects of ultrafine and fine particulate and gaseous air pollution on cardiac autonomic control in subjects with coronary artery disease: the ULTRA study.”Journal of exposure science & environmental epidemiology, vol. 16, pp. 332–341, October 2006.
[30]  S. Wu, F. Deng, H. Wei, J. Huang, X. Wang, Y. Hao, C. Zheng, Y. Qin, H. Lv, M. Shima andX. Guo,“Association of cardiopulmonary health effects with source appointed ambient fine particulate in Beijing, China: a combined analysis from the Healthy Volunteer Natural Relocation (HVNR) study.” Environmental science & technology, vol. 48, pp. 3438–3448, February 2014.
[31]  R.Zhang, C.Liu, P.C.Hsu, C.Zhang, N.Liu, J.Zhang, H.R. Lee, Y.Lu, Y.Qiu, S.Chu and Y.Cui “Nanofiber air filters with high-temperature stability for efficient PM2.5 removal from the pollution sources.”Nano letters, vol. 16, pp. 3642-3649, May 2016.
[32]  J.Xu, C.Liu, P.C.Hsu, K.Liu, R.Zhang, Y.Liu and Y.Cui “Roll-to-roll transfer of electro spun nanofiber film for high-efficiency transparent air filter.” Nano letters, vol. 16, pp. 1270–127, January 2016.
[33]  Y.Bian,R. Wang,S. Wang ,C. Yao and W. Ren “Metal-Organic Framework-Based Nanofiber Filters for Effective Indoor Air Quality Control”, Journal of Materials Chemistry A, vol. 6, pp. 15807-15814, July 2018.
[34]  C. A. Pope III, R. T. Burnett, M. J. Thun, E. E. Calle, D. Krewski and G. D. Thurston, J. Am. “Lung Cancer, Cardiopulmonary Mortality, and Long-Term Exposure to Fine Particulate Air Pollution”JAMA, vol. 287, pp. 1132–1141, March 2002.
[35]  F. Dominici, R. D. Peng, M. L. Bell, A. Mcdermott, S. L. Zeger and J. M. Samet, “Fine Particulate Air Pollution and Hospital Admission for Cardiovascular and Respiratory Diseases.”JAMA, vol. 295, pp. 1127–1134, January 2015.
[36]  J. Lelieveld, J. S. Evans, M. Fnais, D. Giannadaki and A. Pozzer, Nature, “The Contribution of Outdoor Air Pollution Sources to Premature Mortality on a Global Scale”Nature, vol. 525, pp. 367–371, September 2015.
[37]  C. Chen and B. Zhao, “Review of relationship between indoor and outdoor particles: I/O ratio, infiltration factor and penetration factor,”Atmospheric Environment,vol. 45, pp.  275–288,January 2011.
[38]  C. Chen, B. Zhao and C. J. Weschler, “Indoor Exposure to 'Outdoor PM₁₀": Assessing Its Influence on the Relationship Between PM₁₀ and Short-term Mortality in US Cities,” Epidemiology, vol. 23, pp. 870–878, November 2012.
[39]  N. E. Klepeis, W. C. Nelson, W. R. Ott, J. P. Robinson, A. M. Tsang, P. Switzer, J. V Behar, S. C. Hern and W. H. Engelmann, “The National human activity pattern survey (NHAPS): a resource for assessing exposure to environmental pollutants,” Journal of Exposure Analysis and Environmental Epidemiology, vol. 11, pp. 231–252,June 2001.
[40]  L. Hui, H.Jianying, M.Jiajun, C. Zhong and C.Guoqiang“Transparent antibacterial nanofiber air filters with highly efficient moisture resistance for sustainable particulate matter capture”, Science, vol. 19, pp. 214–223 September 2019.
[41]  Y.Chen, S.Zhang, S.Cao, S.Li, F.Chen, S.Yuan, C.Xu, J.Zhou, X.Feng, and X.Ma, “Roll-to-roll production of metal-organic framework coatings for particulate matter removal.”Advanced Materials, vol. 29, pp. 1-6, January 2017.
[42]  N.Bhattarai, D.Edmondson, O.Veiseh, F.A.Matsen, and M.Zhang, “Electro spun chitosan-based nanofibers and their cellular compatibility.” Biomaterials, vol. 26,pp. 6176– 6184, November 2005.
[43]  W.-R. Huang, Z.He, J.-L.Wang, J.-W.Liu, and S.-H.Yu, “Mass production of nanowirenylon flexible transparent smart windows for PM2.5” capture”, iScience, vol. 12, pp. 333–341, February 2019.
[44]  R.Huang, Y.Zhang, C.Bozzetti, K.Ho, J.Cao, Y.Han, K.Daellenbach, J.Slowik, S.Platt, and F.Canonaco, “High secondary aerosol contribution to particulate pollution during haze events in China.”Nature, vol. 514, pp. 218–222, September 2014.
[45]  D.E.Horton, C.B.Skinner, D.Singh, and N.S.Diffenbaugh, “Occurrence and persistence of future atmospheric stagnation events.”Natural Climatic Changes, vol. 4, pp.  698-703, June 2014.
[46]  G.Q. Gu, C.B.Han, J.J.Tian, T.Jiang, C.He, C.X.Lu, Y.Bai,  J.H.Nie,Z.Li and Z.L.Wang, “Tribo-electric nano-generator enhanced multilayered antibacterial nanofiber air filters for efficient removal of ultrafine particulate matter.”Nano Research, vol. 11, pp. 4090–4101, February 2018.
[47]  J.Lelieveld, J.S.Evans, M.Fnais, D.Giannadaki, and A.Pozzer, “The contribution of outdoor air pollution sources to premature mortality on a global scale.” Nature,vol. 525, pp. 367-371, September 2015.
[48]  B.Khalid, X.Bai, H.Wei, Y.Huang, H.Wu, and Y.Cui,  “Direct blow-spinning of nanofibers on a window screen for highly efficient PM2.5 removal”, Nano Letters, vol. 17, pp. 1140–1148, December 2016.
[49]  W.Jung, J.S.Lee, S. Han, S.H.Ko, T.Kim, and Y.H.Kim, “An efficient reduced grapheneoxide filter for PM 2.5 removal”, Journal of Materials Chemistry A, vol. 6, pp. 16975–16982, August 2018.
[50]  S.Jeong, H.Cho, S.Han, P.Won, H.Lee, S.Hong, J.Yeo, J.Kwon, and S.H.Ko, “High efficiency, transparent, reusable, and active PM2. 5 filters by hierarchical Ag nanowire percolation network.” Nano Letters, vol. 17, pp. 4339–4346, June 2017.
[51]  R. Zhang, C.Liu, P-C.Hsu, C.Zhang, N.Liu, J.Zhang, H.R.Lee, Y.Lu, Y.Qiu, and S.Chu, “Nanofiber air filters with high temperature stability for efficient PM2. 5 removal from the pollution sources.” Nano Letters, vol. 16, pp. 3642– 3649, May 2016.

[52] X. Zhao, Y. Li, T. Hua, P. Jiang, X.Yin, J.Yu, and B.Ding, “Low-resistance dualpurposeair filter releasing negative ions and effectively capturing PM2.5”, ACS Appied Material &Interfaces,vol. 9, pp. 12054–12063, March 2017.

----------------------------------------------------------------------------------------------------------------------------------------------



Popular Posts