Evaluating Carbon Sequestration and PM2.5 Removal of Urban Street Trees Using Mobile Laser Scanning Data

Street trees are an important part of urban facilities, and they can provide both aesthetic benefits and ecological benefits for urban environments. Ecological benefits of street trees now are attracting more attention because of environmental deterioration in cities. Conventional methods of evaluat...

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Bibliographic Details
Published in:Remote sensing (Basel, Switzerland) Switzerland), 2018-11, Vol.10 (11), p.1759
Main Authors: Zhao, Yingyi, Hu, Qingwu, Li, Haidong, Wang, Shaohua, Ai, Mingyao
Format: Article
Language:English
Subjects:
Air pollution
Biomass
Carbon
Carbon dioxide
Carbon sequestration
Climate change
Clouds
ecological benefits
Ecological effects
Ecological monitoring
Ecosystems
Environmental degradation
Feasibility studies
Global positioning systems
GPS
i-Tree Eco model
Lasers
LiDAR
Methods
MLS
morphological parameters
Parameters
Particulate matter
Plant species
Pollutants
Remote sensing
Scanners
Scanning
Species
street trees extraction
Trees
Unmanned aerial vehicles
Urban areas
Urban environments
Urban forests
Vegetation
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Summary:Street trees are an important part of urban facilities, and they can provide both aesthetic benefits and ecological benefits for urban environments. Ecological benefits of street trees now are attracting more attention because of environmental deterioration in cities. Conventional methods of evaluating ecological benefits require a lot of labor and time, and establishing an efficient and effective evaluating method is challenging. In this study, we investigated the feasibility to use mobile laser scanning (MLS) data to evaluate carbon sequestration and fine particulate matter (PM2.5) removal of street trees. We explored the approach to extract individual street trees from MLS data, and street trees of three streets in Nantong City were extracted. The correctness rates and completeness rates of extraction results were both over 92%. Morphological parameters, including tree height, crown width, and diameter at breast height (DBH), were measured for extracted street trees, and parameters derived from MLS data were in a good agreement with field-measured parameters. Necessary information about street trees, including tree height, DBH, and tree species, meteorological data and PM2.5 deposition velocities were imported into i-Tree Eco model to estimate carbon sequestration and PM2.5 removal. The estimation results indicated that ecological benefits generated by different tree species were considerably varied and the differences for trees of the same species were mainly caused by the differences in morphological parameters (tree height and DBH). This study succeeds in estimating the amount of carbon sequestration and PM2.5 removal of individual street trees with MLS data, and provides researchers with a novel and efficient way to investigate ecological benefits of urban street trees or urban forests.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs10111759