Urban-induced changes in tree leaf litter accelerate decomposition

Dorendorf, Jens; Wilken, Anja; Eschenbach, Annette; Jensen, Kai

doi:10.1186/s13717-014-0026-5

Cited by 15 publications

(9 citation statements)

References 28 publications

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“…Q. robur leaf litter decomposition showed small but significant differences between the urban green spaces, and the decomposition of T. cordata leaf litter showed no significance between the types of green spaces. Our findings are consistent with the results of Dorendorf et al [38] that leaf litter decomposition for peri-urban forest is slower compared to the other urban green spaces for A. platanoides and B. pendula but not for Q. robur and T. cordata. The rate of leaf litter decomposition has been shown to be an indicator of leaf quality, with faster increased rates of decomposition indicating poorer quality (i.e., less nutrients) [39].…”

Section: Leaf Litter Decomposition In Different Urban Green Spacessupporting

confidence: 93%

Effects of Seasonality, Tree Species and Urban Green Space on Deciduous Leaf Litter Decomposition in Lithuania

2020

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Understanding ecological processes and environmental change in different urban green spaces is an important challenge to secure human well-being. The variety of urban green spaces provides a platform to generate knowledge on how urban environments affect tree leaf decomposition and quality. We measured the leaf litter decomposition of four dominant native deciduous tree species from five different urban green spaces over three time periods in Kaunas, Lithuania. Using the modified litter bag technique, we calculated the decomposition of 60 leaf litter samples for 4, 8, and 12 months respectively. For each leaf litter sample, we determined total N, total P, and organic C. Results indicated that the decomposition of leaf litter amongst tree species, urban green spaces and seasonality (time) were significantly different. The leaf litter of Betula pendula and Acer platanoides from street green spaces decomposed fastest during the spring-summer period. Quercus robur showed small but significant leaf litter loss differences between the green spaces, with the leaf litter from peri-urban forest decomposing the fastest. A decreased C:N ratio for Q. robur leaf litter showed accelerated leaf litter decay. In conclusion, our results show that the ecological processes of leaf litter decomposition, differs between tree species, type of urban green spaces and seasonality and thus must be considered in urban town planning to help maintain urban environments.

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Section: Leaf Litter Decomposition In Different Urban Green Spacessupporting

confidence: 93%

Effects of Seasonality, Tree Species and Urban Green Space on Deciduous Leaf Litter Decomposition in Lithuania

2020

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“…In this study, we chose litter decomposition as model ecosystem function, due to its importance in maintaining soil quality in urban gardens (Schram-Bijkerk et al, 2018) and because of the lack of studies analysing the effect of urbanisation on litter decomposition (Dorendorf et al, 2015). We investigated direct and indirect effects of environmental factors and management practices on litter decomposition along an urban intensity gradient, which was measured as the local temperature increase due to urban warming.…”

Section: Introductionmentioning

confidence: 99%

Litter decomposition driven by soil fauna, plant diversity and soil management in urban gardens

Tresch

Frey

Bayon

et al. 2019

Science of The Total Environment

117

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which should be cited to refer to this work. richness decreased, with the exception of gastropods, and soil fauna abundance increased with urban warming. Our data also show that plant species richness positively affected litter decomposition by increasing soil fauna species richness and microbial activity. A multivariate analysis of organic compounds in litter residues confirmed the importance of soil fauna species richness and garden management on litter decomposition processes. Overall, we showed, that also in intensively managed urban green spaces, such as gardens, biodiversity of plants and soil fauna drives key ecosystem processes. Urban planning strategies that integrate soil protecting management practices may help to maintain important ecosystem services in this heavily used urban environment.

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“…The contribution of litter and prunings to overall tree C sequestration appeared large for the still rather small case study trees. However, the literature-based decay factors may not have performed well under our conditions; the contradictory results concerning urban vs. rural litter decomposition rates (Pouyat et al, 1997;Pouyat and Carreiro, 2003;Nikula et al, 2010;Dorendorf et al, 2015) indicate that the processes related to urban litter are not yet well understood. When the soil surface is sealed, the aboveground litter is likely lost from the tree-soil system, warranting leaving it out of the C sequestration estimates.…”

Section: Tree C Sequestrationmentioning

confidence: 79%

High carbon losses from established growing sites delay the carbon sequestration benefits of street tree plantings – A case study in Helsinki, Finland

Riikonen

Pumpanen

Mäki

et al. 2017

Urban Forestry & Urban Greening

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We assessed the net carbon (C) sequestration dynamics of street tree plantings based on years of measurements at two case study sites each with different tree species in Helsinki, Finland. We assessed C loss from tree soils and tree C accumulation, tested the applicability of pre-existing growth and biomass equations against observations, and estimated the time point for the beginning of net C sequestration for the studied street tree plantings. The tree woody biomass C accumulation in the first 10 years after planting was 18-32 kg per tree. At the same time the C loss from the growth media was at least 170 kg per growth media volume (25 m 3) per tree. If this soil C loss was accounted for, the net C sequestration would begin, at best, approximately 30 years after planting. Biomass equations developed for traditional forests predicted more stem biomass and less leaf and branch biomass than measured for the species examined, but total aboveground biomass was generally well predicted. growth media organic matter may decompose quickly and lose C to the atmosphere (Bernal et al., 1998). Soil sealing (by e.g. asphalt or pavement), common in urban environments and predominantly used in combination with structural tree soils, impairs soil heat and soil water (SW) exchange (Scalenghe and Marsan, 2009) and limits the C input from above the ground, affecting biomass accumulation and decomposition. These effects may lead to overall C loss from street tree plantings unless the C sequestered * ln M = a + b (ln G), G = girth (cm) ** predicts volume; converted to mass with specific gravity of 0.40 (Alden, 1995).

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Urban-induced changes in tree leaf litter accelerate decomposition

Cited by 15 publications

References 28 publications

Effects of Seasonality, Tree Species and Urban Green Space on Deciduous Leaf Litter Decomposition in Lithuania

Effects of Seasonality, Tree Species and Urban Green Space on Deciduous Leaf Litter Decomposition in Lithuania

Litter decomposition driven by soil fauna, plant diversity and soil management in urban gardens

High carbon losses from established growing sites delay the carbon sequestration benefits of street tree plantings – A case study in Helsinki, Finland

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