Showing total 2 results

1. Tree Germination Sensitivity to Increasing Temperatures: A Global Meta‐Analysis Across Biomes, Species and Populations.

Author

Vicente, Eduardo and Benito Garzón, Marta

Subjects

*BODY temperature regulation, *COMMUNITY forests, *GERMINATION, *CLIMATE change, *PHENOLOGY

Abstract

ABSTRACT Aim Location Time Period Major Taxa Studied Methods Results Main Conclusions Climate change is altering forest communities at an unprecedented pace. Current knowledge on trees' responses to climate shifts is based mostly on adults. Yet, germination traits and intraspecific variation can notably modulate species niches. This paper provides a quantitative review about warming effects on tree species' germination, the role of population effects and its implications under future climate.Global; covering boreal, temperate, Mediterranean and tropical–subtropical biomes.1996–2024.Tree species.We reviewed 50 papers addressing 63 species and 250 populations. Then, we conducted a meta‐analysis to assess warming effects on germination percentage and time, and how germination is modulated by climate at seed origin. We further evaluated populations' adaptation to local temperature on 27 species. Finally, we estimated population‐based germination niches in eight of these species under current climate conditions and a 2080 climate scenario (SSP5‐8.5).Warming induced more consistent shifts in germination time than in percentage across biomes, hastening germination. Temperature at seed origin shaped responses to warming in boreal and temperate species. In Mediterranean and tropical–subtropical species, different responses were associated with variation in precipitation‐related variables. Local adaptation was more frequent in species from the tropics, while adaptation lags towards warmer‐than‐today conditions observed in the other biomes. Simulation of germination niches yielded slight although extensive germination reductions in tropical–subtropical species under future climate, whereas the temperate and boreal ones showed overall increases.Population‐level adjustments are key moderators of germination percentage and phenology response to warming. Their roles vary depending on the prevailing climate in each biome. Temperature at seed origin is an important factor modulating temperate and boreal species' responses, while precipitation‐related variables are more relevant in Mediterranean and tropical–subtropical ones. Local adaptation in the tropical species increases their vulnerability to warming. [ABSTRACT FROM AUTHOR]

Published

2024

2. Microbial traits dictate soil necromass accumulation coefficient: A global synthesis.

Author

Han, Bingbing, Yao, Yanzhong, Wang, Yini, Su, Xiaoxuan, Ma, Lihua, Chen, Xinping, and Li, Zhaolei

Subjects

*STRUCTURAL equation modeling, *CARBON sequestration, *SOIL microbiology, *SOILS, *CARBON in soils

Abstract

Aim: The accumulation of microbial necromass carbon has gained increasing attention due to its slow decomposition. However, it remains unclear what induces the accumulation of microbial necromass carbon via reiterated community turnover on large spatial scales. This study explores the characteristics of soil necromass carbon accumulation in terrestrial ecosystems. Location: Global. Time Period: Contemporary (1999–2022). Major Taxa Studied: Soil microorganisms. Methods: A dataset was compiled using 993 observations from 82 peer‐reviewed papers on the effects of coefficients of microbial necromass accumulation (hereafter NAC) in equilibrium. Linear mixed‐effect models and structural equation models were used to ascertain the controlling factors of the NAC. Results: The average NAC was higher in croplands (28.2) and forests (26.8) than in grasslands (21.1). Edaphic factors seemingly affected the NAC, which was lower in soils with high pH and clay content on a global scale. Biotic factors, particularly those related to living microorganism abundance and microbial biomass nitrogen content, were the pivotal drivers of NAC and accounted for approximately 43.6% of its geographic variability. More organic carbon was likely to be preserved in soil with a higher NAC, regardless of ecosystem type. Conclusions: Novel findings regarding the overriding controls for the living microorganism abundance and microbial biomass nitrogen that drive the NAC highlight an urgent need for viable strategies to manipulate microbial attributes for enhancing carbon sequestration. [ABSTRACT FROM AUTHOR]

Published

2024