Your search keyword '"Roger L Kitching"' showing total 5 results

1. Editorial: Understanding patterns and mechanisms of forest canopy diversity and ecosystem functions in a changing world

Author

Akihiro Nakamura, Louise A. Ashton, Brett R. Scheffers, and Roger L. Kitching

Subjects

arboreality, forest canopy, vertical stratification, elevation, anthropogenic disturbance, biodiversity, Forestry, SD1-669.5, Environmental sciences, GE1-350

Published

2022

2. Stochastic dispersal assembly dominates tropical invertebrate community assembly regardless of land use intensity

Author

Natasha R. Granville, Maxwell V. L. Barclay, Michael J. W. Boyle, Arthur Y. C. Chung, Tom M. Fayle, Huai En Hah, Jane L. Hardwick, Lois Kinneen, Roger L. Kitching, Sarah C. Maunsell, Jeremy A. Miller, Adam C. Sharp, Nigel E. Stork, Leona Wai, Kalsum M. Yusah, and Robert M. Ewers

Abstract

Understanding how community assembly processes drive biodiversity patterns is a central goal of community ecology. While it is generally accepted that ecological communities are assembled by both stochastic and deterministic processes, quantifying their relative importance remains challenging. Few studies have investigated how the relative importance of stochastic and deterministic community assembly processes vary among taxa and along gradients of habitat degradation. Using data on 1,645 arthropod species across seven taxonomic groups in Malaysian Borneo, we quantified the importance of stochastic and deterministic assembly processes across a gradient of logging intensity. Dispersal limitation was the dominant process for most taxa at all levels of logging intensity. The relationship between logging and community assembly varied depending on the specific combination of taxa and stochasticity metric used, but, in general, the processes that govern invertebrate community assembly were remarkably robust to changes in land use intensity.

Published

2023

3. Different environmental factors drive tree species diversity along elevation gradients in three climatic zones in Yunnan, southern China

Author

Yong Tang, Zhenhua Sun, Akihiro Nakamura, Jie Yang, Melinda J. Laidlaw, Min Cao, Xiaoyang Song, Jieqiong Li, Roger L. Kitching, and Wenfu Zhang

Subjects

0106 biological sciences, QH301-705.5, Seedling, Plant Science, Subtropics, 010603 evolutionary biology, 01 natural sciences, Air temperature, Tree species distribution, Tree diversity, Biology (General), Transect, Climate zones, Ecology, Evolution, Behavior and Systematics, Ecology, Elevation, Botany, Species diversity, Understory, Montane forest, Southern china, QK1-989, Soil moisture, Tree species, Research Paper, 010606 plant biology & botany

Abstract

Elevational patterns of tree diversity are well studied worldwide. However, few studies have examined how seedlings respond to elevational gradients and whether their responses vary across climatic zones. In this study, we established three elevational transects in tropical, subtropical and subalpine mountain forests in Yunnan Province, southern China, to examine the responses of tree species and their seedlings to elevational gradients. Within each transect, we calculated species diversity indices and composition of both adult trees and seedlings at different elevations. For both adult trees and seedlings, we found that species diversity decreased with increasing elevation in both tropical and subalpine transects. Species composition showed significant elevational separation within all three transects. Many species had specific elevational preferences, but abundant tree species that occurred at specific elevations tended to have very limited recruitment in the understory. Our results highlight that the major factors that determine elevational distributions of tree species vary across climatic zones. Specifically, we found that the contribution of air temperature to tree species composition increased from tropical to subalpine transects, whereas the contribution of soil moisture decreased across these transects., Highlights • Species richness and diversity decreased with increasing elevation in tropical and subalpine transects. • Species similarity between adult trees and seedlings decreased with increasing elevation in the tropical transect. • Species similarity between adult trees and seedlings increased with increasing elevation in the subalpine transect. • Effect of temperature on species distribution increased from tropical to subalpine zones. • The effect of soil moisture on species distribution decreased from tropical to subalpine zones. • Abundant tree species at each elevation often had very limited seedlings.

Published

2021

4. Ecological patterns and processes in the vertical dimension of terrestrial ecosystems

Author

Shuang Xing, Lily Leahy, Louise A. Ashton, Roger L. Kitching, Timothy C. Bonebrake, and Brett R. Scheffers

Subjects

Animal Science and Zoology, Ecology, Evolution, Behavior and Systematics

Abstract

Climatic gradients such as latitude and elevation are considered primary drivers of global biogeography. Yet, alongside these macro-gradients, the vertical space and structure generated by terrestrial plants form comparable climatic gradients but at a fraction of the distance. These vertical gradients provide a spectrum of ecological space for species to occur and co-exist, increasing biodiversity. Further, vertical gradients can serve as pathways for evolutionary adaptation of species traits, leading to a range of ecological specialisations. In this review, we explore the ecological evidence supporting the proposition that the vertical gradient serves as an engine driving the ecology and evolution of species and shaping larger biogeographic patterns in space and time akin to elevation and latitude. Focusing on vertebrate and invertebrate taxa, we synthesised how ecological patterns within the vertical dimension shape species composition, distribution, and biotic interactions. We identify three key ecological mechanisms associated with species traits that facilitate persistence within the vertical environment and draw on empirical examples from the literature to explore these processes. Looking forward, we propose that the vertical dimension provides an excellent study template to explore timely ecological and evolutionary questions. We encourage future research to also consider how the vertical dimension will influence the resilience and response of animal taxa to global change.

Published

2022

5. Different environmental factors drive tree species diversity along elevation gradients in three climatic zones in Yunnan, southern China

Author

Xiaoyang Song, Min Cao, Jieqiong Li, Roger L. Kitching, Akihiro Nakamura, Melinda J. Laidlaw, Yong Tang, Zhenhua Sun, Wenfu Zhang, and Jie Yang

Subjects

Air temperature, Climate zones, Montane forest, Soil moisture, Seedling, Tree species distribution, Biology (General), QH301-705.5, Botany, QK1-989

Abstract

Elevational patterns of tree diversity are well studied worldwide. However, few studies have examined how seedlings respond to elevational gradients and whether their responses vary across climatic zones. In this study, we established three elevational transects in tropical, subtropical and subalpine mountain forests in Yunnan Province, southern China, to examine the responses of tree species and their seedlings to elevational gradients. Within each transect, we calculated species diversity indices and composition of both adult trees and seedlings at different elevations. For both adult trees and seedlings, we found that species diversity decreased with increasing elevation in both tropical and subalpine transects. Species composition showed significant elevational separation within all three transects. Many species had specific elevational preferences, but abundant tree species that occurred at specific elevations tended to have very limited recruitment in the understory. Our results highlight that the major factors that determine elevational distributions of tree species vary across climatic zones. Specifically, we found that the contribution of air temperature to tree species composition increased from tropical to subalpine transects, whereas the contribution of soil moisture decreased across these transects.

Published

2021