TY - JOUR
T1 - A systematic analysis and review of soil organic carbon stocks in urban greenspaces
AU - Guo, Yang
AU - Han, Jiatong
AU - Bao, Haijun
AU - Wu, Yuzhe
AU - Shen, Liyin
AU - Xu, Xiangrui
AU - Chen, Ziwei
AU - Smith, Pete
AU - Abdalla, Mohamed
PY - 2024/7/26
Y1 - 2024/7/26
N2 - Urban greenspaces typically refer to urban wetland, urban forest and urban turfgrass. They play a critical role in carbon sequestration by absorbing carbon from the atmosphere; however, their capacity to retain and store carbon in the form of soil organic carbon (SOC) varies significantly. This study provides a systematic analysis and review on the capacity of different urban greenspace types in retaining and storing SOC in 30 cm soil depth on a global scale. Data came from 78 publications on the subject of SOC stocks, covering different countries and climate zones. Overall, urban greenspace types exerted significant influences on the spatial pattern of SOC stocks, with the highest value of 18.86 ± 11.57 kg m
−2 (mean ± standard deviation) in urban wetland, followed by urban forest (6.50 ± 3.65 kg m
−2), while the lowest mean value of 4.24 ± 3.28 kg m
−2 was recorded in urban turfgrass soil. Soil organic carbon stocks in each urban greenspace type were significantly affected by climate zones, management/environmental settings, and selected soil properties (i.e. soil bulk density, pH and clay content). Furthermore, our analysis showed a significantly negative correlation between SOC stocks and human footprint in urban wetland, but a significantly positive relationship in urban forest and urban turfgrass. A positive correlation between SOC stocks and human footprint indicates that increased human activity and development can enhance SOC stocks through effective management and green infrastructure. Conversely, a negative correlation suggests that improper management of human activities can degrade SOC stocks. This highlights the need for sustainable practices to maintain or enhance SOC accumulation in urban greenspaces.
AB - Urban greenspaces typically refer to urban wetland, urban forest and urban turfgrass. They play a critical role in carbon sequestration by absorbing carbon from the atmosphere; however, their capacity to retain and store carbon in the form of soil organic carbon (SOC) varies significantly. This study provides a systematic analysis and review on the capacity of different urban greenspace types in retaining and storing SOC in 30 cm soil depth on a global scale. Data came from 78 publications on the subject of SOC stocks, covering different countries and climate zones. Overall, urban greenspace types exerted significant influences on the spatial pattern of SOC stocks, with the highest value of 18.86 ± 11.57 kg m
−2 (mean ± standard deviation) in urban wetland, followed by urban forest (6.50 ± 3.65 kg m
−2), while the lowest mean value of 4.24 ± 3.28 kg m
−2 was recorded in urban turfgrass soil. Soil organic carbon stocks in each urban greenspace type were significantly affected by climate zones, management/environmental settings, and selected soil properties (i.e. soil bulk density, pH and clay content). Furthermore, our analysis showed a significantly negative correlation between SOC stocks and human footprint in urban wetland, but a significantly positive relationship in urban forest and urban turfgrass. A positive correlation between SOC stocks and human footprint indicates that increased human activity and development can enhance SOC stocks through effective management and green infrastructure. Conversely, a negative correlation suggests that improper management of human activities can degrade SOC stocks. This highlights the need for sustainable practices to maintain or enhance SOC accumulation in urban greenspaces.
KW - Soil organic carbon
KW - Vegetation type
KW - Human footprint
KW - Climate
KW - Selected soil properties
KW - Management and environmental setting
UR - http://www.scopus.com/inward/record.url?scp=85199422622&partnerID=8YFLogxK
U2 - 10.1016/j.scitotenv.2024.174788
DO - 10.1016/j.scitotenv.2024.174788
M3 - Article
C2 - 39019284
SN - 0048-9697
VL - 948
JO - Science of the Total Environment
JF - Science of the Total Environment
M1 - 174788
ER -