Abstract
Air pollutants are of public concern due to their adverse health effects. Biological air filters have shown great promise for the bioremediation of air pollutants. Different plant species have previously been shown to significantly influence pollutant removal capacities, although the number of species tested to date is small. The aims of this paper were to determine the pollutant removal capacity of different Australian native species for their effect on active biowall particulate matter, volatile organic compounds and carbon dioxide removal, and to compare removal rates with previously tested ornamental species. The single-pass removal efficiency for PM and VOCs of native planted biofilters was determined with a flow-through chamber. CO2 removal was tested by a static chamber pull down study. The results indicated that the native species were not effective for CO2 removal likely due to their high light level requirements in conjunction with substrate respiration. Additionally, the native species had lower PM removal efficiencies compared to ornamental species, with this potentially being due to the ornamental species possessing advantageous leaf traits for increased PM accumulation. Lastly, the native species were found to have similar benzene removal efficiencies to ornamental species. As such, whilst the native species showed a capacity to phytoremediate air pollutants, ornamental species have a comparatively greater capacity to do so and are more appropriate for air filtration purposes in indoor circumstances. However, as Australian native plants have structural and metabolic adaptations that enhance their ability to tolerate harsh environments, they may find use in botanical biofilters in situations where common ornamental plants may be suitable, especially in the outdoor environment.
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References
Abbass OA, Sailor DJ, Gall ET (2017) Effectiveness of indoor plants for passive removal of indoor ozone. Build Environ 119:62–70. https://doi.org/10.1016/j.buildenv.2017.04.007
Abdo P, Huynh BP, Avakian V, Nguyen T, Torpy FR, Irga PJ (2016) Measurement of air flow through a green-wall module. Australasian Fluid Mechanics Conference, 5-8 December 2016 Perth, Australia.
ASHRAE (2011) GreenGuide: the design, construction, and operation of sustainable buildings, 3rd edn. ASHRAE, Atlanta
Australia SW (2011) Managing the work environment and facilities: code of practice. Safe Work Australia, Canberra https://www.safeworkaustralia.gov.au/system/files/documents/1702/managing_work_environment_and_facilities2.pdf
Aydogan A, Montoya LD (2011) Formaldehyde removal by common indoor plant species and various growing media. Atmos Environ 45:2675–2682. https://doi.org/10.1016/j.atmosenv.2011.02.062
Beckett P, Free-Smith P, Taylor G (2000) Effective tree species for local air-quality management. J Arboric 26:12–19
Beecham S, Razzaghmanesh M, Bustami R, Ward J (2019) The role of green roofs and living walls as WSUD approaches in a dry climate. In: Sharma, A.K., Gardner, T. and Begbie, D. (eds) Approaches to water sensitive urban design, Woodhead publishing, pp. 409-430.
Bell DT (1993) Germination responses to variations in light quality of eight species from sandy habitats in Western Australia. Aust J Bot 41:321–326
Borthwick HA, Hendricks SB, Parker MW, Toole EH, Toole VK (1952) A reversible photoreaction controlling seed germination. Proc Natl Acad Sci, USA 28:662–666
Brodribb T, Hill RS (1993) A physiological comparison of leaves and phyllodes in Acacia melanoxylon. Aust J Bot 41:293–305
Chen W, Zhang JS, Zhang Z (2005) Performance of air cleaners for removing multiple volatile organic compounds in indoor air. ASHRAE Trans 111:1101–1104
Chen L, Liu C, Zou R, Yang M, Zhang Z (2016) Experimental examination of effectiveness of vegetation as bio-filter of particulate matters in the urban environment. Environ Pollut 208:198–208
Chen L, Liu C, Zhang L, Zou R, Zhang Z (2017) Variation in tree species ability to capture and retain airborne fine particulate matter (PM2.5). Sci Rep 7:3206. https://doi.org/10.1038/s41598-017-03360-1
Coelho LFM, Ribeiro MC, Pereira RAS (2014) Water availability determines the richness and density of fig trees within Brazilian semideciduous forest landscapes. Acta Oecol 57:109–116
Darlington A, Dat J, Dixon M (2001) The biofiltration of indoor air: air flux and temperature influences the removal of toluene, ethylbenzene, and xylene. Environ Sci Technol 35:240–246
Deng L, Deng Q (2018) The basic roles of indoor plants in human health and comfort. Environ Sci Pollut Res 25:36087–36101. https://doi.org/10.1007/s11356-018-3554-1
Dong X, Wang H, Gu J, Wang Y, Wang Z (2015) Root morphology, histology and chemistry of nine fern species (pteridophyta) in a temperate forest. Plant Soil 393:215–227
Fowler D (2002) Pollutant deposition and uptake by vegetation. In: Bell JNB, Treshow M. (Eds.). Air Pollution and Plant Life. Second Edition, p 43
Gawrońska H, Bakera B (2015) Phytoremediation of particulate matter from indoor air by Chlorophytum comosum L. plants. Air Qual Atmos Health 8:265–272
Gkorezis P, Daghio M, Franzetti A, Van Hamme JD, Sillen W, Vangronsveld J (2016) The interaction between plants and bacteria in the remediation of petroleum hydrocarbons: an environmental perspective. Front Microbiol 7:1836
Godish T, Guindon C (1989) An assessment of botanical air purification as a formaldehyde mitigation measure under dynamic laboratory chamber conditions. Environ Pollut 62:13–20
Gubb C, Blanusa T, Griffiths A, Pfrang C (2019) Interaction between plant species and substrate type in the removal of CO2 indoors. Air Qual Atmos Health:1–10. https://doi.org/10.1007/s11869-019-00736-2
Hosker RP, Lindberg SE (1982) Review: atmospheric deposition and plant assimilation of gases and particles. Atmos Environ 16:889–910
Hwang SH, Park WM (2017) Concentrations of PM 10 and airborne bacteria in daycare centers in Seoul relative to indoor environmental factors and daycare center characteristics. Air Qual Atmos Health 1:139–145
Irga PJ, Torpy FR, Burchett MD (2013) Can hydroculture be used to enhance the performance of indoor plants for the removal of air pollutants? Atmos Environ 77:267–271
Irga PJ, Paull NJ, Abdo P, Torpy FR (2017) An assessment of the atmospheric particle removal efficiency of an in-room botanical biofilter system. Build Environ 115:281–290
Irga PJ, Pettit T, Irga RF, Paull NJ, Douglas ANJ, Torpy FR (2019) Does plant species selection in functional active green walls influence VOC phytoremediation efficiency? Environ Sci Pollut Res 26:12851–12858
Jindachot W, Treesubsuntorn C, Thiravetyan P (2018) Effect of individual/co-culture of native phyllosphere organisms to enhance Dracaena sanderiana for benzene phytoremediation. Water Air Soil Pollut 229:80–11. https://doi.org/10.1007/s11270-018-3735-z
Kim KJ, Il Jeong M, Lee DW, Song JS, Kim HD, Yoo EH, Jeong SJ, Han SW, Kays SJ, Lim YW, HH K. (2010) Variation in formaldehyde removal efficiency among indoor plant species. Hortic Sci 45:1489–1495
Kim KJ, Kim HJ, Khalekuzzaman M, Yoo EH, Jung HH, Jang HS (2016) Removal ratio of gaseous toluene and xylene transported from air to root zone via the stem by indoor plants. Environ Sci Pollut Res 23:6149–6158
Kim KJ, Khalekuzzaman M, Suh JN, Kim HJ, Shagol C, Kim H-H, Kim HJ (2018) Phytoremediation of volatile organic compounds by indoor plants: a review. Hortic Environ Biotechnol 59:143–157. https://doi.org/10.1007/s13580-018-0032-0
Kooyman RM, Laffan SW, Westoby M (2017) The incidence of low phosphorus soils in Australia. Plant Soil 412:143–150. https://doi.org/10.1007/s11104-016-3057-0
Large M, Farrington L (2016) The Nephrolepis Boston fern complex (including Nephrolepis exaltata [L.] Schott), Nephrolepidaceae, naturalised in New Zealand. Unitec ePress Perspectives in Biosecurity Research Series (2). Retrieved from https://hdl.handle.net/10652/3614
Lee C, Choi B, Chun M (2015) Stabilization of soil moisture and improvement of indoor air quality by a plant-biofilter integration system. Korean J Horticult Sci Technol 33:751–762
Leonard RJ, McArthur C, Hochuli DF (2016) Particulate matter deposition on roadside plants and the importance of leaf trait combinations. Urban For Urban Green 20:249–253. https://doi.org/10.1016/j.ufug.2016.09.008
Lin MW, Chen LY, Chuah YK (2017) Investigation of a potted plant (Hedera helix) with photo-regulation to remove volatile formaldehyde for improving indoor air quality. Aerosol Air Qual Res 17:2543–2554
Litschke T, Kuttler WJ (2008) On the reduction of urban particle concentration by vegetation—a review. Meteorol Z 17:229–240
Llewellyn D, Dixon M (2011) Can plants really improve indoor air quality? In: M.-Y. Editor-in-Chief: Murray (ed.) Comprehensive biotechnology (Second Edition). Academic Press, Burlington, pp. 331-8.
Massa GD, Kim H-H, Wheeler RM, Mitchell CA (2008) Plant productivity in response to LED lighting. Hortic Sci 43:1951–1956
Montgomery JF, Green SI, Rogak SN, Bartlett K (2012) Predicting the energy use and operation cost of HVAC air filters. Energy and Buildings 47:643–650. https://doi.org/10.1016/j.enbuild.2012.01.001
Ng CWW, Ni JJ, Leung AK, Zhou C, Wang ZJ (2016) Effects of planting density on tree growth and induced soil suction. Géotechnique 66:711–724. https://doi.org/10.1680/jgeot.15.P.196
Orwell RL, Wood RA, Tarran J, Torpy F, Burchett MD (2004) Removal of benzene by the indoor plant/substrate microcosm and implications for air quality. Water Air Soil Pollut 157:193–207
Ottelé M, van Bohemen HD, Fraaij A (2010) Quantifying the deposition of particulate matter on climber vegetation on living walls. Ecol Eng 36:154–162
Parseh I, Teiri H, Hajizadeh Y, Ebrahimpour K (2018) Phytoremediation of benzene vapors from indoor air by Schefflera arboricola and Spathiphyllum wallisii plants. Atmos Pollut Res 9:1083–1087
Pasquet-Kok J, Creese C, Sack L (2010) Turning over a new ‘leaf’: multiple functional significances of leaves versus phyllodes in Hawaiian Acacia koa. Plant Cell Environ 33:2084–2100
Pennisi SV, van Iersel MW (2012) Quantification of carbon assimilation of plants in simulated and in situ interiorscapes. Hortscience 47:468–476
Petroff A, Mailliat A, Amielh M, Anselmet FJ (2008) Aerosol dry deposition on vegetative canopies. Part II: a new modelling approach and applications. Atmos Environ 42:3654–3683
Pettit T, Irga PJ, Abdo P, Torpy FR (2017) Do the plants in functional green walls contribute to their ability to filter particulate matter? Build Environ 125:299–307. https://doi.org/10.1016/j.buildenv.2017.09.004
Pettit T, Irga PJ, Torpy FR (2019) The in situ pilot-scale phytoremediation of airborne VOCs and particulate matter with an active green wall. Air Qual Atmos Health 12(1):33–44
Ram SS, Majumder S, Chaudhuri P, Chanda S, Santra SC, Maiti PK, Sudarshan M, Chakraborty A (2014) Plant canopies: bio-monitor and trap for re-suspended dust particulates contaminated with heavy metals. Mitig Adapt Strateg Glob Chang 19:499–508. https://doi.org/10.1007/s11027-012-9445-8
Redlich C, Sparer J, Cullen M (1997) Sick-building syndrome. Lancet 349:1013–1016
Sæbø A, Popek R, Nawrot B, Hanslin HM, Gawronska H, Gawronski SW (2012) Plant species differences in particulate matter accumulation on leaf surfaces. Science of The Total Environment 427–428:347-354 doi:https://doi.org/10.1016/j.scitotenv.2012.03.084
Schenk HJ, Jackson R (2002) The global biogeography of roots. Monographs 72:311–328
Setsungnern A, Treesubsuntorn C, Thiravetyan P, biochemistry (2017) The influence of different light quality and benzene on gene expression and benzene degradation of Chlorophytum comosum. Plant Physiol Biochem 120:95-102
Singh S, Verma A (2007) Phytoremediation of air pollutants: a review. In: Environmental bioremediation technologies. Springer, Berlin, Heidelberg, pp 293–314
Somova LA, Pechurkin NS (2001) Functional, regulatory and indicator features of microorganisms in man-made ecosystems. Adv Space Res 27:1563–1570
Soreanu G, Dixon M, Darlington A (2013) Botanical biofiltration of indoor gaseous pollutants—a mini-review. Chem Eng J 229:585–594
Sprent JI, Ardley J, James EK (2017) Biogeography of nodulated legumes and their nitrogen-fixing symbionts. New Phytol 215:40–56
Sternberg T, Viles H, Cathersides A, Edwards M (2010) Dust particulate absorption by ivy (Hedera helix L.) on historic walls in urban environments. Sci Total Environ 409:162–168
Su YM, Lin CH (2015) Removal of indoor carbon dioxide and formaldehyde using green walls by bird nest fern. Journal of Horticulture 84:69–76
Sulpice R et al (2014) Low levels of ribosomal RNA partly account for the very high photosynthetic phosphorus-use efficiency of P roteaceae species. Plant Cell Environ 37:1276–1298
Thompson JD (2005) Plant evolution in the Mediterranean. Oxford University Press, Oxford, UK
Tong X, Wang B, Dai WT, Cao JJ, Ho SS, Kwok TC, Lui KH, Lo CM, Ho KF (2018) Indoor air pollutant exposure and determinant factors controlling household air quality for elderly people in Hong Kong. Air Qual Atmos Health 1:695–704
Toole EH, Toole VK, Borthwick HA, Hendricks SB (1955) Interaction of temperature and light on germination of seeds. Plant Physiol 30:473–478
Torpy FR, Irga PJ, Moldovan D, Tarran J, Burchett MD (2013) Characterization and biostimulation of benzene biodegradation in the potting-mix of indoor plants. J Appl Hortic 15:10–15
Torpy FR, Irga PJ, Burchett MD (2014) Profiling indoor plants for the amelioration of high CO2 concentrations. Urban For Urban Green 13:227–233. https://doi.org/10.1016/j.ufug.2013.12.004
Torpy FR, Irga PJ, Burchett MD (2015) Reducing indoor air pollutants through biotechnology. In: Labrincha JA, Diamanti MV, Yu CP, Lee HK (eds) Pacheco Torgal F. Springer International Publishing, Biotechnologies and biomimetics for civil engineering, pp 181–210. https://doi.org/10.1007/978-3-319-09287-4_8
Torpy FR, Zavattaro M, Irga PJ (2017) Green wall technology for the phytoremediation of indoor air: a system for the reduction of high CO2 concentrations. Air Qual Atmos Health 10:575–585. https://doi.org/10.1007/s11869-016-0452-x
Torpy FR, Clements N, Pollinger M, Dengel A, Mulvihill I, He C, Irga P (2018) Testing the single-pass VOC removal efficiency of an active green wall using methyl ethyl ketone (MEK). Air Qual Atmos Health 11(2):163–170
Ullmann I (1989) Stomatal conductance and transpiration of Acacia under field conditions: similarities and differences between leaves and phyllodes. Structure and Function of Trees 3:45–56
Wang Z, Zhang JS (2011) Characterization and performance evaluation of a full-scale activated carbon-based dynamic botanical air filtration system for improving indoor air quality. Build Environ 46:758–768. https://doi.org/10.1016/j.buildenv.2010.10.008
Wang Z, Pei J, Zhang JS (2014) Experimental investigation of the formaldehyde removal mechanisms in a dynamic botanical filtration system for indoor air purification. J Hazard Mater 280:235–243. https://doi.org/10.1016/j.jhazmat.2014.07.059
Wei X, Lyu S, Yu Y, Wang Z, Liu H, Pan D, Chen J (2017) Phylloremediation of air pollutants: exploiting the potential of plant leaves and leaf-associated microbes. Front Plant Sci 28:1318. https://doi.org/10.3389/fpls.2017.01318
Willis AJ, Groves RH (1991) Temperature and light effects on the germination of seven native forbs. Aust J Bot 39:219–228
Wolverton BD, Wolverton JD (1993) Plants and soil microorganisms: removal of formaldehyde, xylene and ammonia from the indoor environment. J Mississippi Acad Sci 38:11–15
Wolverton BC, McDonald RC, Watkins EA Jr (1984) Foliage plants for removing indoor air pollutants from energy-efficient homes. Econ Bot 38:224–228
Wood RA, Orwell RL, Tarran J, Torpy F (2002) Potted plant-growth media: interactions and capacities in removal of volatiles from indoor air. J Environ Horticult Biotechnol 77:120–129
Wood RA, Burchett MD, Alquezar R, Orwell RL, Tarran J, Torpy F (2006) The potted-plant microcosm substantially reduces indoor air VOC pollution: I. Office field-study. Water Air Soil Pollut 175:163–180
Wright IJ, Reich P, Westoby M (2001) Strategy shifts in leaf physiology, structure and nutrient content between species of high-and low-rainfall and high-and low-nutrient habitats. Journal of Functional Ecology 15:423–434
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Paull, N.J., Irga, P.J. & Torpy, F.R. Active botanical biofiltration of air pollutants using Australian native plants. Air Qual Atmos Health 12, 1427–1439 (2019). https://doi.org/10.1007/s11869-019-00758-w
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DOI: https://doi.org/10.1007/s11869-019-00758-w