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2020.02.26 ³í¹® ÃÊ·Ï
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2020-02-27
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Weerakkody, Udeshika, et al. "Evaluating the impact of individual leaf traits on atmospheric particulate matter accumulation using natural and synthetic leaves." Urban forestry & urban greening 30 (2018): 98-107.


Muhammad, S., K. Wuyts, and R. Samson. "Atmospheric net particle accumulation on 96 plant species with contrasting morphological and anatomical leaf characteristics in a common garden experiment." Atmospheric environment 202 (2019): 328-344.


Shao, Feng, et al. "Study on different particulate matter retention capacities of the leaf surfaces of eight common garden plants in Hangzhou, China." Science of the Total Environment 652 (2019): 939-951.
 Ã·ºÎÆÄÀÏ:
Evaluating the impact of individual leaf traits on atmospheric particulate matter accumulation using natural and synthetic leaves.pdf (4.50MB)
Atmospheric net particle accumulation on 96 plant species with contrasting morphological and anatomical leaf characteristics in a common garden experiment.pdf (2.64MB)
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Pant, Pallavi, and Roy M. Harrison. "Estimation of the contribution of road traffic emissions to particulate matter concentrations from field measurements: a review."Atmospheric environment77 (2013): 78-97. Pierson, William R., and Wanda W. Brachaczek. "Particulate matter associa..
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2020.02.25 ³í¹® ÃÊ·Ï
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Park, Ju-Myon, et al. "Performance evaluation of six different aerosol samplers in a particulate matter generation chamber."Atmospheric Environment43.2 (2009): 280-289. Popek, Robert, et al. "Impact of particulate matter accumulation on the photosynthetic apparatus of roadside wo..