Your search keyword '"Lehmann, Caroline"' showing total 8 results

1. Underground trees inhabit varied environmental extremes across the Afrotropics.

Author

Courtenay, Anya P, Moonlight, Peter W, Pennington, R Toby, and Lehmann, Caroline E R

Subjects

WOODY plants, EXTREME environments, TREES, CONVERGENT evolution, ECOLOGICAL niche, SYZYGIUM, FUNCTIONAL groups

Abstract

Background and Aims Geoxyles, a distinctive feature of Afrotropical savannas and grasslands, survive recurrent disturbances by resprouting subshrub branches from large below-ground woody structures. Underground trees are a type of geoxyle that independently evolved within woody genera of at least 40 plant families in Africa. The environmental limits and determinants of underground tree biogeography are poorly understood, with the relative influence of frost and fire debated in particular. We aim to quantify variability in the niche of underground tree species relative to their taller, woody tree/shrub congeners. Methods Using occurrence records of four Afrotropical genera, Parinari (Chrysobalanaceae), Ozoroa (Anacardiaceae), Syzygium (Myrtaceae) and Lannea (Anacardiaceae), and environmental data of nine climate and disturbance variables, the biogeography and niche of underground trees are compared with their open and closed ecosystem congeners. Key Results Along multiple environmental gradients and in a multidimensional environmental space, underground trees inhabit significantly distinct and extreme environments relative to open and closed ecosystem congeners. Niche overlap is low among underground trees and their congeners, and also among underground trees of the four genera. Of the study taxa, Parinari underground trees inhabit hotter, drier and more seasonal environments where herbivory pressure is greatest. Ozoroa underground trees occupy relatively more fire-prone environments, while Syzygium underground trees sustain the highest frost frequency and occur in relatively wetter conditions with seasonal waterlogging. Lannea underground trees are associated with the lowest temperatures, highest precipitation, and varying exposure to disturbance. Conclusions While underground trees exhibit repeated convergent evolution, varied environments shape the ecology and biogeography of this iconic plant functional group. The multiplicity of extreme environments related to fire, frost, herbivory and waterlogging that different underground tree taxa occupy, and the distinctiveness of these environments, should be recognized in the management of African grassy ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

2. Complex evolutionary history of two ecologically significant grass genera, Themeda and Heteropogon (Poaceae: Panicoideae: Andropogoneae).

Author

Arthan, Watchara, Dunning, Luke T, Besnard, Guillaume, Manzi, Sophie, Kellogg, Elizabeth A, Hackel, Jan, Lehmann, Caroline E R, Mitchley, Jonathan, and Vorontsova, Maria S

Subjects

PLEISTOCENE Epoch, CYMBOPOGON, MIOCENE Epoch, GRASSLANDS, SPECIES hybridization

Abstract

Themeda and Heteropogon are closely related grass genera frequently dominant in tropical C4 grasslands. Relationships between them are poorly resolved, impeding ecological study, especially of T. triandra with a broad distribution from Africa to East Asia, and H. contortus with a pantropical distribution. Our analyses of plastome and nuclear genomes with comprehensive sampling of Themeda and Heteropogon demonstrate that neither genus is monophyletic as currently circumscribed. Plastome and nuclear data place H. melanocarpus and H. ritchiei in Themeda. Nested in T. triandra are T. quadrivalvis and T. unica , demonstrating that this widespread species is more morphologically diverse than previously recognized. Heteropogon fischerianus is nested in H. contortus. The picture is more complex for H. triticeus that is sister to H. contortus in the nuclear analysis and to Cymbopogon in the plastome analysis. This incongruence between nuclear and plastid phylogenetic trees suggests hybridization between Cymbopogon -related genome donors and H. contortus. Plastome dating estimates the Themeda–Heteropogon crown age at c. 7.6 Myr, consistent with the Miocene C4 grassland expansion. Themeda triandra and H. contortus diversified 1–2 Mya in the Pleistocene. These results establish a foundation for studying the history of these ecologically significant widespread grasses and the ecosystems they form. [ABSTRACT FROM AUTHOR]

Published

2021

3. Human impacts in African savannas are mediated by plant functional traits.

Author

Osborne, Colin P., Charles‐Dominique, Tristan, Stevens, Nicola, Midgley, Guy, Bond, William J., and Lehmann, Caroline E. R.

Subjects

ANTHROPOGENIC effects on nature, SAVANNAS, FUNCTIONAL analysis, HERBIVORES, WOODY plants

Abstract

Summary: Tropical savannas have a ground cover dominated by C4 grasses, with fire and herbivory constraining woody cover below a rainfall‐based potential. The savanna biome covers 50% of the African continent, encompassing diverse ecosystems that include densely wooded Miombo woodlands and Serengeti grasslands with scattered trees. African savannas provide water, grazing and browsing, food and fuel for tens of millions of people, and have a unique biodiversity that supports wildlife tourism. However, human impacts are causing widespread and accelerating degradation of savannas. The primary threats are land cover‐change and transformation, landscape fragmentation that disrupts herbivore communities and fire regimes, climate change and rising atmospheric CO2. The interactions among these threats are poorly understood, with unknown consequences for ecosystem health and human livelihoods. We argue that the unique combinations of plant functional traits characterizing the major floristic assemblages of African savannas make them differentially susceptible and resilient to anthropogenic drivers of ecosystem change. Research must address how this functional diversity among African savannas differentially influences their vulnerability to global change and elucidate the mechanisms responsible. This knowledge will permit appropriate management strategies to be developed to maintain ecosystem integrity, biodiversity and livelihoods. [ABSTRACT FROM AUTHOR]

Published

2018

4. Pre-rain green-up is ubiquitous across southern tropical Africa: implications for temporal niche separation and model representation.

Author

Ryan, Casey M., Williams, Mathew, Grace, John, Woollen, Emily, and Lehmann, Caroline E. R.

Subjects

PHENOLOGY, BIOCLIMATOLOGY, MIOMBO, FORESTS & forestry, MOPANE tree

Abstract

Tree phenology mediates land-atmosphere mass and energy exchange and is a determinant of ecosystem structure and function. In the dry tropics, including African savannas, many trees grow new leaves during the dry season - weeks or months before the rains typically start. This syndrome of pre-rain green-up has long been recognized at small scales, but the high spatial and interspecific variability in leaf phenology has precluded regional generalizations., We used remote sensing data to show that this precocious phenology is ubiquitous across the woodlands and savannas of southern tropical Africa., In 70% of the study area, green-up preceded rain onset by > 20 d (42% > 40 d). All the main vegetation formations exhibited pre-rain green-up, by as much as 53 ± 18 d (in the wet miombo). Green-up showed low interannual variability (SD between years = 11 d), and high spatial variability (> 100 d)., These results are consistent with a high degree of local phenological adaptation, and an insolation trigger of green-up. Tree-tree competition and niche separation may explain the ubiquity of this precocious phenology. The ubiquity of pre-rain green-up described here challenges existing model representations and suggests resistance (but not necessarily resilience) to the delay in rain onset predicted under climate change. [ABSTRACT FROM AUTHOR]

Published

2017

5. Ecosystem services from southern African woodlands and their future under global change.

Author

Ryan, Casey M., Pritchard, Rose, McNicol, Iain, Owen, Matthew, Fisher, Janet A., and Lehmann, Caroline

Subjects

MIOMBO, FUELWOOD, ECOSYSTEMS, MOPANE tree, FORESTS & forestry, GLOBAL environmental change

Abstract

Miombo and mopane woodlands are the dominant land cover in southern Africa. Ecosystem services from these woodlands support the livelihoods of 100 M rural people and 50 M urban dwellers, and others beyond the region. Provisioning services contribute $9+2 billion yr-1 to rural livelihoods; 76% of energy used in the region is derived from woodlands; and traded woodfuels have an annual value of $780 M.Woodlands supportmuch of the region's agriculture through transfers of nutrients to fields and shifting cultivation. Woodlands store 18-24 PgC carbon, and harbour a unique and diverse flora and fauna that provides spiritual succour and attracts tourists. Longstanding processes that will impact service provision are the expansion of croplands (0.1 M km2; 2000-2014), harvesting ofwoodfuels (93 M tonnes yr-1) and changing access arrangements. Novel, exogenous changes include large-scale land acquisitions (0.07M km2; 2000-2015), climate change and rising CO2. The net ecological response to these changes is poorly constrained, as they act in different directions, and differentially on trees and grasses, leading to uncertainty in future service provision. Land-use change and socio-political dynamics are likely to be dominant forces of change in the short term, but important land-use dynamics remain unquantified. [ABSTRACT FROM AUTHOR]

Published

2016

6. Savanna Vegetation-Fire-Climate Relationships Differ Among Continents.

Author

Lehmann, Caroline E. R., Anderson, T. Michael, Sankaran, Mahesh, Higgins, Steven I., Archibald, Sally, Hoffmann, William A., Hanan, Niall P., Williams, Richard J., Fensham, Roderick J., Felfili, Jeanine, Hutley, Lindsay B., Ratnam, Jayashree, San Jose, Jose, Montes, Ruben, Franklin, Don, Russell-Smith, Jeremy, Ryan, Casey M., Durigan, Giselda, Hiernaux, Pierre, and Haidar, Ricardo

Subjects

*SAVANNA ecology, *VEGETATION & climate, *SAVANNA plants, *RAINFALL, *AGRICULTURAL climatology, *BIOCLIMATOLOGY research, *WILDFIRES & the environment

Abstract

Ecologists have long sought to understand the factors controlling the structure of savanna vegetation. Using data from 2154 sites in savannas across Africa, Australia, and South America, we found that increasing moisture availability drives increases in fire and tree basal area, whereas fire reduces tree basal area. However, among continents, the magnitude of these effects varied substantially, so that a single model cannot adequately represent savanna woody biomass across these regions. Historical and environmental differences drive the regional variation in the functional relationships between woody vegetation, fire, and climate. These same differences will determine the regional responses of vegetation to future climates, with implications for global carbon stocks. [ABSTRACT FROM AUTHOR]

Published

2014

7. Deciphering the distribution of the savanna biome.

Author

Lehmann, Caroline E. R., Archibald, Sally A., Hoffmann, William A., and Bond, William J.

Subjects

*SAVANNAS, *SAVANNA ecology, *VEGETATION & climate, *RAINFALL

Abstract

The article presents a research study regarding the limits of savanna on the continents of Africa, Australia, and South America. The effects of rainfall, seasonality, and soil fertility on the growth and distribution of savanna are examined, as well as the interaction of these factors with natural disturbances.

Published

2011

8. The Trouble with Trees: Afforestation Plans for Africa.

Author

Bond, William J., Stevens, Nicola, Midgley, Guy F., and Lehmann, Caroline E.R.

Subjects

*AFFORESTATION, *FOSSIL fuels, *CARBON sequestration, *TREES, *TREE planting

Abstract

Extensive tree planting is widely promoted for reducing atmospheric CO 2. In Africa, 1 million km2, mostly of grassy biomes, have been targeted for 'restoration' by 2030. The target is based on the erroneous assumption that these biomes are deforested and degraded. We discuss the pros and cons of exporting fossil fuel emission problems to Africa. [ABSTRACT FROM AUTHOR]

Published

2019