Highly Efficient, Dual-Functional Self-Assembled Electrospun Nanofiber Filters for Simultaneous PM Removal and On-Site Eye-Readable Formaldehyde Sensing

Jin Yeong Song , Seongmin Kim , Jaeseong Park , Sang Min Park

Advanced Fiber Materials ›› 2023, Vol. 5 ›› Issue (3) : 1088 -1103.

PDF
Advanced Fiber Materials ›› 2023, Vol. 5 ›› Issue (3) : 1088 -1103. DOI: 10.1007/s42765-023-00279-3
Research Article

Highly Efficient, Dual-Functional Self-Assembled Electrospun Nanofiber Filters for Simultaneous PM Removal and On-Site Eye-Readable Formaldehyde Sensing

Author information +
History +
PDF

Abstract

Air pollution containing particulate matter (PM) and volatile organic compounds has caused magnificent burdens on individual health and global economy. Although advances in highly efficient or multifunctional nanofiber filters have been achieved, many existing filters can only deal with one type of air pollutant, such as capturing PM or absorbing and detecting toxic gas. Here, highly efficient, dual-functional, self-assembled electrospun nanofiber (SAEN) filters were developed for simultaneous PM removal and onsite eye-readable formaldehyde sensing fabricated on a commercial fabric mask. With the use of an electrolyte solution containing a formaldehyde-sensitive colorimetric agent as a collector during electrospinning, the one-step fabrication of the dual-functional SAEN filter on commercial masks, such as a fabric mask and a daily disposable mask, was achieved. The electrolyte solution also allowed the uniform deposition of electrospun nanofibers, thereby achieving the high efficiency of PM filtration with an increased quality factor up to twice that of commercial masks. The SAEN filter enabled onsite and eye-readable formaldehyde gas detection by changing its color from yellow to red under a 5 ppm concentrated formaldehyde gas atmosphere. The repetitive fabrication and detachment of the SAEN filter on a fabric mask minimized the waste of the mask while maintaining high filtration efficiency by replenishing the SAEN filters and reusing the fabric mask. Given the dual functionality of SAEN filters, this process could provide new insights into designing and developing high performance and dual-functional electrospun nanofiber filters for various applications, including individual protection and indoor purification applications.

Graphical Abstract

Keywords

Electrospinning / Nanofiber / Self-assembly / PM removal / Formaldehyde sensing

Cite this article

Download citation ▾
Jin Yeong Song, Seongmin Kim, Jaeseong Park, Sang Min Park. Highly Efficient, Dual-Functional Self-Assembled Electrospun Nanofiber Filters for Simultaneous PM Removal and On-Site Eye-Readable Formaldehyde Sensing. Advanced Fiber Materials, 2023, 5(3): 1088-1103 DOI:10.1007/s42765-023-00279-3

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

BrunekreefB, HolgateST. Air pollution and health. The Lancet, 2002, 360: 1233.

[2]

KampaM, CastanasE. Human health effects of air pollution. Environ Pollut, 2008, 151: 362.

[3]

Van de VeldeM, SchepersR, BerendsN, VandermeerschE, De BuckF. Ten years of experience with accidental dural puncture and post-dural puncture headache in a tertiary obstetric anaesthesia department. Int J Obstet Anesth, 2008, 17: 329.

[4]

SnyderEG, WatkinsTH, SolomonPA, ThomaED, WilliamsRW, HaglerGSW, ShelowD, HindinDA, KilaruVJ, PreussPW. The changing paradigm of air pollution monitoring. Environ Sci Technol, 2013, 47: 11369.

[5]

GlencrossDA, HoTR, CaminaN, HawrylowiczCM, PfefferPE. Air pollution and its effects on the immune system. Free Radic Biol Med, 2020, 151: 56.

[6]

Gonzalez-MartinJ, KraakmanNJR, PerezC, LebreroR, MunozR. A state-of-the-art review on indoor air pollution and strategies for indoor air pollution control. Chemosphere, 2021, 262. 128376
[7]

HamanakaRB, MutluGM. Particulate matter air pollution: effects on the cardiovascular system. Front Endocrinol, 2018, 9: 680.

[8]

DaellenbachKR, UzuG, JiangJ, CassagnesLE, LeniZ, VlachouA, StefenelliG, CanonacoF, WeberS, SegersA, KuenenJJP, SchaapM, FavezO, AlbinetA, AksoyogluS, DommenJ, BaltenspergerU, GeiserM, HaddadIE, JaffrezoJL, PrevotASH. Sources of particulate-matter air pollution and its oxidative potential in Europe. Nature, 2020, 587: 414.

[9]

LeeBJ, KimB, LeeK. Air pollution exposure and cardiovascular disease. Toxicol Res, 2014, 30: 71.

[10]

MølhaveL. Organic compounds as indicators of air pollution. Indoor Air, 2002, 13: 12.

[11]

SalthammerT. Very volatile organic compounds: an understudied class of indoor air pollutants. Indoor Air, 2016, 26: 25.

[12]

DominiciF, GreenstoneM, SunsteinCR. Particulate Matter Matters. Science, 2014, 334: 257.

[13]

ZhangR, WangG, GuoS, ZamoraML, YingQ, LinY, WangW, HuM, WangY. Formation of urban fine particulate matter. Chem Rev, 2015, 115: 3803.

[14]

MukherjeeA, AgrawalM. World air particulate matter: sources, distribution and health effects. Environ Chem Lett, 2017, 15: 283.

[15]

AtkinsonR, AreyJ. Atmospheric degradation of volatile organic compounds. Chem Rev, 2003, 103: 4605.

[16]

KamalMS, RazzakSA, HossainMM. Catalytic oxidation of volatile organic compounds (VOCs)—a review. Atmos Environ, 2016, 140: 117.

[17]

LiuH, CaoC, HuangJ, ChenZ, ChenG, LaiY. Progress on particulate matter filtration technology: basic concepts, advanced materials, and performances. Nanoscale, 2020, 12: 437.

[18]

Valencia-OsorioLM, Álvarez-LáinezML. Global view and trends in electrospun nanofiber membranes for particulate matter filtration: a review. Macromol Mater Eng, 2021, 306: 2100278.

[19]

Ji X, Huang J, Teng L, Li S, Li X, Cai W, Chen Z, Lai Y. Advances in particulate matter filtration: materials, performance, and application. Green Energy Environ. 2022(in press).
[20]

IranpourR, CoxHHJ, DeshussesMA, SchroederED. Literature review of air pollution control biofilters and biotrickling filters for odor and volatile organic compound removal. Environ Prog, 2005, 24: 254.

[21]

BerenjianA, ChanN, MalmiriHJ. Volatile organic compounds removal methods: a review. Am J Biochem Biotechnol, 2012, 8: 220.

[22]

McGinnCK, LamportZA, KymissisI. Review of gravimetric sensing of volatile organic compounds. ACS Sens, 2020, 5: 1514.

[23]

MatuschekC, MollF, FangerauH, FischerJC, ZankerK, van GriensvenM, SchneiderM, Kindgen-MillesD, KnoefelWT, LichtenbergA, TamaskovicsB, Djiepmo-NjanangFJ, BudachW, CorradiniS, HaussingerD, FeldtT, JensenB, PelkaR, OrthK, PeiperM, GrebeO, MaasK, BolkeE, HaussmannJ. The history and value of face masks. Eur J Med Res, 2020, 25: 23.

[24]

AdanurS, JayswalA. Filtration mechanisms and manufacturing methods of face masks: an overview. J Ind Text, 2020, 51: 3683S.

[25]

BognitzkiM, CzadoW, FreseT, SchaperA, HellwigM, SteinhartM, GreinerA, WendorffJH. Nanostructured fibers via electrospinning. Adv Mater, 2001, 13: 70.

[26]

LiD, XiaY. Electrospinning of nanofibers: reinventing the wheel?. Adv Mater, 2004, 16: 1151.

[27]

RyuHI, KooMS, KimS, KimS, ParkYA, ParkSM. Uniform-thickness electrospun nanofiber mat production system based on real-time thickness measurement. Sci Rep, 2020, 10: 20847.

[28]

SongJY, RyuHI, LeeJM, BaeSH, LeeJW, YiCC, ParkSM. Conformal fabrication of an electrospun nanofiber mat on a 3D ear cartilage-shaped hydrogel collector based on hydrogel-assisted electrospinning. Nanoscale Res Lett, 2021, 16: 116.

[29]

HanKS, LeeS, KimM, ParkP, LeeMH, NahJ. Electrically activated ultrathin PVDF-TrFE air filter for high-efficiency PM1.0 filtration. Adv Funct Mater, 2019, 29: 1903633.

[30]

LakshmananA, GavaliDS, VenkataprasannaKS, ThapaR, SarkarD. Low-basis weight polyacrylonitrile/polyvinylpyrrolidone blend nanofiber membranes for efficient particulate matter capture. ACS Appl Polym Mater, 2022, 4: 3971.

[31]

ReddyMV, JulienCM, MaugerA, ZaghibK. Sulfide and oxide inorganic solid electrolytes for all-solid-state li batteries: a review. Nanomaterials, 2020, 10: 1606.

[32]

ZhangR, LiuC, HsuPC, ZhangC, LiuN, ZhangJ, LeeHR, LuY, QiuY, ChuS, CuiY. Nanofiber air filters with high-temperature stability for efficient PM2.5 removal from the pollution sources. Nano Lett, 2016, 16: 3642.

[33]

SouzandehH, ScudieroL, WangY, ZhongWH. A disposable multi-functional air filter: paper towel/protein nanofibers with gradient porous structures for capturing pollutants of broad species and sizes. ACS Sustain Chem Eng, 2017, 5: 6209.

[34]

ZhangR, LiuB, YangA, ZhuY, LiuC, ZhouG, SunJ, HsuPC, ZhaoW, LinD, LiuY, PeiA, XieJ, ChenW, XuJ, JinY, WuT, HuangX, CuiY. In situ investigation on the nanoscale capture and evolution of aerosols on nanofibers. Nano Lett, 2018, 18: 1130.

[35]

ZhangS, LiuH, TangN, AliN, YuJ, DingB. Highly efficient, transparent, and multifunctional air filters using self-assembled 2D nanoarchitectured fibrous networks. ACS Nano, 2019, 13: 13501.

[36]

LeeS, ChoAR, ParkD, KimJK, HanKS, YoonIJ, LeeMH, NahJ. Reusable polybenzimidazole nanofiber membrane filter for highly breathable PM2.5 dust proof mask. ACS Appl Mater Interfaces, 2019, 11: 2750.

[37]

BianY, WangS, ZhangL, ChenC. Influence of fiber diameter, filter thickness, and packing density on PM2.5 removal efficiency of electrospun nanofiber air filters for indoor applications. Build Environ, 2020, 170: 106628.

[38]

ZhangS, LiuH, TangN, ZhouS, YuJ, LiB, DingB. Spider-web-inspired PM0.3 filters based on self-sustained electrostatic nanostructured networks. Adv Mater, 2020, 32: 2002361.

[39]

CuiJ, WangY, LuT, LiuK, HuangC. High performance, environmentally friendly and sustainable nanofiber membrane filter for removal of particulate matter 1.0. J Colloid Interface Sci, 2021, 597: 48.

[40]

XuJ, LiuC, HsuPC, LiuK, ZhangR, LiuY, CuiY. Roll-to-roll transfer of electrospun nanofiber film for high-efficiency transparent air filter. Nano Lett, 2016, 16: 1270.

[41]

ZuoF, ZhangS, LiuH, FongH, YinX, YuJ, DingB. Free-standing polyurethane nanofiber/nets air filters for effective PM capture. Small, 2017, 13: 1702139.

[42]

ChengZ, CaoJ, KangL, LuoY, LiT, LiuW. Novel transparent nano-pattern window screen for effective air filtration by electrospinning. Mater Lett, 2018, 221: 157.

[43]

WangX, XiangH, SongC, ZhuD, SuiJ, LiuQ, LongY. Highly efficient transparent air filter prepared by collecting-electrode-free bipolar electrospinning apparatus. J Hazard Mater, 2020, 385. 121535
[44]

XiongJ, ShaoW, WangL, CuiC, GaoY, JinY, YuH, HanP, LiuF, HeJ. High-performance anti-haze window screen based on multiscale structured polyvinylidene fluoride nanofibers. J Colloid Interface Sci, 2022, 607: 711.

[45]

ZhangS, LiuH, TangN, GeJ, YuJ, DingB. Direct electronetting of high-performance membranes based on self-assembled 2D nanoarchitectured networks. Nat Commun, 2019, 10: 1458.

[46]

ParkSM, KimDS. Electrolyte-assisted electrospinning for a self-assembled, free-standing nanofiber membrane on a curved surface. Adv Mater, 2015, 27: 1682.

[47]

ParkSM, EomS, KimW, KimDS. Role of grounded liquid collectors in precise patterning of electrospun nanofiber mats. Langmuir, 2018, 34: 284.

[48]

ParkSM, EomS, ChoiD, HanSJ, ParkSJ, KimDS. Direct fabrication of spatially patterned or aligned electrospun nanofiber mats on dielectric polymer surfaces. Chem Eng J, 2018, 335: 712.

[49]

LiCC. Aerodynamic behavior of a gas mask canister containing two porous media. Chem Eng Sci, 1832, 2009: 64
[50]

SuYC, LiCC. Computational fluid dynamics simulations and tests for improving industrial-grade gas mask canisters. Adv Mech Eng, 2015, 7: 1687814015596297.

[51]

TcharkhtchiA, AbbasnezhadN, Zarbini SeydaniM, ZirakN, FarzanehS, ShirinbayanM. An overview of filtration efficiency through the masks: mechanisms of the aerosols penetration. Bioact Mater, 2021, 6: 106.

[52]

FloydEL, HenryJB, JohnsonDL. Influence of facial hair length, coarseness, and areal density on seal leakage of a tight-fitting half-face respirator. J Occup Environ Hyg, 2018, 15: 334.

[53]

RegliA, SommerfieldA, von Ungern-SternbergBS. The role of fit testing N95/FFP2/FFP3 masks: a narrative review. Anaesthesia, 2021, 76: 91.

[54]

BollingerNNIOSH respirator selection logic, 2004CincinnatiDHHS (NIOSH)2-15
[55]

HodgkinsonJ, TatamRP. Optical gas sensing: a review. Meas Sci Technol, 2013, 24. 012004
[56]

FengS, FarhaF, LiQ, WanY, XuY, ZhangT, NingH. Review on smart gas sensing technology. Sensors, 2019, 19: 3670.

[57]

JiH, ZengW, LiY. Gas sensing mechanisms of metal oxide semiconductors: a focus review. Nanoscale, 2019, 11: 22664.

[58]

ReddyK, GuoY, LiuJ, LeeW, Khaing OoMK, FanX. Rapid, sensitive, and multiplexed on-chip optical sensors for micro-gas chromatography. Lab Chip, 2012, 12: 901.

[59]

OhSY. Fast gas chromatography–surface acoustic wave sensor: an effective tool for discrimination and quality control of Lavandula species. Sens Actuator B-Chem, 2013, 182: 223.

[60]

van den BroekJ, AbeggS, PratsinisSE, GuntnerAT. Highly selective detection of methanol over ethanol by a handheld gas sensor. Nat Commun, 2019, 10: 4220.

[61]

KimYK, HwangSH, JeongSM, SonKY, LimSK. Colorimetric hydrogen gas sensor based on PdO/metal oxides hybrid nanoparticles. Talanta, 2018, 188: 356.

[62]

KangK, ParkJ, KimB, NaK, ChoI, RhoJ, YangD, LeeJY, ParkI. Self-powered gas sensor based on a photovoltaic cell and a colorimetric film with hierarchical micro/nanostructures. ACS Appl Mater Interfaces, 2020, 12: 39024.

[63]

ChoSH, SuhJM, EomTH, KimT, JangHW. Colorimetric sensors for toxic and hazardous gas detection: a review. Electron Mater Lett, 2020, 17: 1.

[64]

NakanoN, IshikawaM, KooabayashiY, NagashimaK. Development of a monitoring tape for formaldehyde using hydroxylamine sulfate and methyl yellow. Anal Sci, 1994, 10: 641.

[65]

WangX, SiY, WangJ, DingB, YuJ, Al-DeyabSS. A facile and highly sensitive colorimetric sensor for the detection of formaldehyde based on electro-spinning/netting nano-fiber/nets. Sens Actuator B-Chem, 2012, 163: 186.

[66]

KimDH, ChaJH, LimJY, BaeJ, LeeW, YoonKR, KimC, JangJS, HwangW, KimID. Colorimetric dye-loaded nanofiber yarn: eye-readable and weavable gas sensing platform. ACS Nano, 2020, 14: 16907.

[67]

SongJY, OhJH, ChoiD, ParkSM. Highly efficient patterning technique for silver nanowire electrodes by electrospray deposition and its application to self-powered triboelectric tactile sensor. Sci Rep, 2021, 11: 21437.

[68]

JeongS, ChoH, HanS, WonP, LeeH, HongS, YeoJ, KwonJ, KoSH. High efficiency, transparent, reusable, and active PM2.5 filters by hierarchical ag nanowire percolation network. Nano Lett, 2017, 17: 4339.

[69]

DingB, WangM, WangX, YuJ, SunG. Electrospun nanomaterials for ultrasensitive sensors. Mater Today, 2010, 13: 16.

[70]

WangX, DingB, YuJ, WangM, PanF. A highly sensitive humidity sensor based on a nanofibrous membrane coated quartz crystal microbalance. Nanotechnology, 2010, 21. 055502
[71]

WangX, DingB, YuJ, SiY, YangS, SunG. Electro-netting: fabrication of two-dimensional nano-nets for highly sensitive trimethylamine sensing. Nanoscale, 2011, 3: 911.

[72]

ZhaoS, ZhouQ, LongYZ, SunGH, ZhangY. Nanofibrous patterns by direct electrospinning of nanofibers onto topographically structured non-conductive substrates. Nanoscale, 2013, 5: 4993.

[73]

JiaC, YuD, LamarreM, LeopoldPL, TengYD, WangH. Patterned electrospun nanofiber matrices via localized dissolution: potential for guided tissue formation. Adv Mater, 2014, 26: 8192.

[74]

LiD, OuyangG, McCannJT, XiaY. Collecting electrospun nanofibers with patterned electrodes. Nano Lett, 2005, 5: 913.

[75]

WuY, DongZ, WilsonS, ClarkRL. Template-assisted assembly of electrospun fibers. Polymer, 2010, 51: 3244.

[76]

KolářováK, VosmanskáV, RimpelováS, ŠvorčíkV. Effect of plasma treatment on cellulose fiber. Cellulose, 2013, 20: 953.

[77]

FasthIM, UlrichNH, JohansenJD. Ten-year trends in contact allergy to formaldehyde and formaldehyde-releasers. Contact Dermatitis, 2018, 79: 263.

[78]

LiuC, MiaoX, LiJ. Outdoor formaldehyde matters and substantially impacts indoor formaldehyde concentrations. Build Environ, 2019, 158: 145.

[79]

HorzumN, TasciogluD, ÖzbekC, OkurS, DemirMM. VOC sensors based on a metal oxide nanofibrous membrane/QCM system prepared by electrospinning. New J Chem, 2014, 38: 5761.

Funding

National Research Foundation of Korea(2020R1C1C100944311)

Pusan National University

Chung Mong-Koo Foundation

RIGHTS & PERMISSIONS

Donghua University, Shanghai, China

AI Summary AI Mindmap
PDF

154

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/