Interactions between all pairs of neighboring trees in 16 forests worldwide reveal details of unique ecological processes in each forest, and provide windows into their evolutionary histories

Wills, Christopher; Wang, Bin; Fang, Shuai; Wang, Yunquan; Jin, Yi; Lutz, James A.; Thompson, Jill; Harms, Kyle E.; Pulla, Sandeep; Pasion, Bonifacio O.; Germain, Sara J.; Liu, Heming; Smokey, Joseph; Su, Sheng‐Hsin; Chu, Chengjin; Chuyong, George B.; Chang‐Yang, Chia‐Hao; Dattaraja, H. S.; Davies, Stuart J.; Ediriweera, Sisira; Esufali, Shameema; Fletcher, Christine; Gunatilleke, Nimal; Gunatilleke, Savi; Hsieh, Chang‐Fu; He, Fangliang; Hubbell, Stephen P.; Hao, Zhanqing; Itoh, Akira; Kenfack, David; Li, Buhang; Li, Xiankun; Ma, Keping; Morecroft, Michael D.; Mi, Xiangcheng; Malhi, Yadvinder; Ong, Perry S.; Rodriguez, Lillian Jennifer; Suresh, H. S.; Sun, I-F; Sukumar, Raman; Tan, Sylvester; Thomas, Duncan W.; Uriarte, María; Wang, Xihua; Wang, Xugao; Yao, Tze Leong; Zimmermann, Jess

doi:10.1371/journal.pcbi.1008853

Cited by 2 publications

(1 citation statement)

References 47 publications

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“…Examples of how the values of partnership promote growth and resilience are evident in many functioning ecosystems. For example, the trees of forest communities lend mutual care when one is injured, by sending nutrients through underground mycorrhizal channels (Stobart & Piercy, 2023), and adjust their leaf canopies for sunlight to reach a sick stump (Wills et al, 2021). Rivers move fluidly across the earth, navigating around every obstacle that presents itself; the water adapts as needed, changes course, and maintains its interconnection with land.…”

Section: The Partnership Methodsmentioning

confidence: 99%

A Partnership Perspective on Ecosocial Reciprocity for Cultural Transformation

Walton,

Beese,

Chesak

et al. 2024

IJPS

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Eco social health is the impact of our biology by social, economic, and environmental influencers which inform how the psychosomatic body as a whole system functions. Social effects of dominative societies and structures lead to human disease through complex dimensions of physical, mental, emotional, and spiritual disconnection. Partnership practices are foundational for the innate biological human need for social connection in health. In a world burdened with the global phenomenon of disconnection, a paradigm shift which honors and respects the critical necessity of healthy biodiverse relationships of all members of the ecological community are needed for the development of sustainable cultures of reciprocity and wellness. Global partners demonstrate the impacts of valued education that exist in cultures of partnership systems. Education is the cornerstone reimagining a new world of pace and health. Applying the partnership qualities as foundation to the learning environment may serve as a framework for building safe and inclusive spaces that foster curiosity in order to transform sociocultural practices and empower global perspectives.

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Section: The Partnership Methodsmentioning

confidence: 99%

A Partnership Perspective on Ecosocial Reciprocity for Cultural Transformation

Walton,

Beese,

Chesak

et al. 2024

IJPS

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The importance of large-diameter trees to the creation of snag and deadwood biomass

et al. 2021

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Background Baseline levels of tree mortality can, over time, contribute to high snag densities and high levels of deadwood (down woody debris) if fire is infrequent and decomposition is slow. Deadwood can be important for tree recruitment, and it plays a major role in terrestrial carbon cycling, but deadwood is rarely examined in a spatially explicit context. Methods Between 2011 and 2019, we annually tracked all trees and snags ≥1 cm in diameter and mapped all pieces of deadwood ≥10 cm diameter and ≥1 m in length in 25.6 ha of Tsuga heterophylla / Pseudotsuga menziesii forest. We analyzed the amount, biomass, and spatial distribution of deadwood, and we assessed how various causes of mortality that contributed uniquely to deadwood creation. Results Compared to aboveground woody live biomass of 481 Mg ha−1 (from trees ≥10 cm diameter), snag biomass was 74 Mg ha−1 and deadwood biomass was 109 Mg ha−1 (from boles ≥10 cm diameter). Biomass from large-diameter trees (≥60 cm) accounted for 85%, 88%, and 58%, of trees, snags, and deadwood, respectively. Total aboveground woody live and dead biomass was 668 Mg ha−1. The annual production of downed wood (≥10 cm diameter) from tree boles averaged 4 Mg ha−1 yr−1. Woody debris was spatially heterogeneous, varying more than two orders of magnitude from 4 to 587 Mg ha−1 at the scale of 20 m × 20 m quadrats. Almost all causes of deadwood creation varied in importance between large-diameter trees and small-diameter trees. Biomass of standing stems and deadwood had weak inverse distributions, reflecting the long period of time required for trees to reach large diameters following antecedent tree mortalities and the centennial scale time required for deadwood decomposition. Conclusion Old-growth forests contain large stores of biomass in living trees, as well as in snag and deadwood biomass pools that are stable long after tree death. Ignoring biomass (or carbon) in deadwood pools can lead to substantial underestimations of sequestration and stability.

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Interactions between all pairs of neighboring trees in 16 forests worldwide reveal details of unique ecological processes in each forest, and provide windows into their evolutionary histories

Cited by 2 publications

References 47 publications

A Partnership Perspective on Ecosocial Reciprocity for Cultural Transformation

A Partnership Perspective on Ecosocial Reciprocity for Cultural Transformation

The importance of large-diameter trees to the creation of snag and deadwood biomass

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