Contrasting long‐term records of biomass burning in wet and dry savannas of equatorial East Africa

Colombaroli, Danièle; Ssemmanda, Immaculate; Gelorini, Vanessa; Verschuren, Dirk

doi:10.1111/gcb.12583

Cited by 49 publications

(45 citation statements)

References 59 publications

(97 reference statements)

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“…Indeed, a reduction in macroscopic‐CHAR was also observed in New Zealand following pyrophobic forest removal, where there was a decline in biomass availability following burning and deforestation after the Maori (McWethy et al, ). Further afield, our data showing high charcoal accumulation in line with high forest cover are analogous to studies from Kenya (Colombaroli et al, ), Spain (Gil‐Romera et al, ), and Arizona (Brunelle et al, ), where biomass limitation was indicated as the most plausible explanation for the link between high forest cover and high charcoal influx. Nevertheless, the hypothesis of biomass‐limited fire occurrence is unlikely in the generally high biomass environments of western Tasmania (McWethy et al, ); thus, it is more likely that a variation in the fuel type, from rainforest to sclerophyll vegetation, would have modulated charcoal influx in the Dove Lake record.…”

Section: Discussionsupporting

confidence: 89%

Biogeochemical Responses to Holocene Catchment‐Lake Dynamics in the Tasmanian World Heritage Area, Australia

et al. 2018

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Environmental changes such as climate, land use, and fire activity affect terrestrial and aquatic ecosystems at multiple scales of space and time. Due to the nature of the interactions between terrestrial and aquatic dynamics, an integrated study using multiple proxies is critical for a better understanding of climate‐ and fire‐driven impacts on environmental change. Here we present a synthesis of biological and geochemical data (pollen, spores, diatoms, micro X‐ray fluorescence scanning, CN content, and stable isotopes) from Dove Lake, Tasmania, allowing us to disentangle long‐term terrestrial‐aquatic dynamics through the last 12 kyear. We found that aquatic dynamics at Dove Lake are tightly linked to vegetation shifts dictated by regional hydroclimatic variability in western Tasmania. A major shift in the diatom composition was detected at ca. 6 ka, and it was likely mediated by changes in regional terrestrial vegetation, charcoal, and iron accumulation. High rainforest abundance prior ca. 6 ka is linked to increased terrestrially derived organic matter delivery into the lake, higher dystrophy, anoxic bottom conditions, and lower light penetration depths. The shift to a landscape with a higher proportion of sclerophyll species following the intensification of El Niño‐Southern Oscillation since ca. 6 ka corresponds to a decline in terrestrial organic matter input into Dove Lake, lower dystrophy levels, higher oxygen availability, and higher light availability for algae and littoral macrophytes. This record provides new insights on terrestrial‐aquatic dynamics that could contribute to the conservation management plans in the Tasmanian World Heritage Area and in temperate high‐altitude dystrophic systems elsewhere.

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Section: Discussionsupporting

confidence: 89%

Biogeochemical Responses to Holocene Catchment‐Lake Dynamics in the Tasmanian World Heritage Area, Australia

et al. 2018

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“…Macroscopic charcoal particles were estimated under a stereomicroscope at 40Â magnification. We distinguished different types of charcoal morphotypes as in Colombaroli et al (2014). Grass cuticles usually occur in flat sheets, and epidermal cells are arranged in parallel rows, with stomata within the rows (Jensen et al, 2007), and mostly have a length to width ratio !…”

Section: Methodsmentioning

confidence: 99%

“…Leaf fragments can be separated from other charred material due to the presence of leaf veins, which are characterized by a divergence of the branches from a node (Jensen et al, 2007). Further details can be found in Beffa (2012) and Colombaroli et al (2014).…”

Section: Methodsmentioning

confidence: 99%

Combining charcoal sediment and molecular markers to infer a Holocene fire history in the Maya Lowlands of Petén, Guatemala

Schüpbach

Kirchgeorg

Colombaroli

et al. 2015

Quaternary Science Reviews

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a b s t r a c tVegetation changes in the Maya Lowlands during the Holocene are a result of changing climate conditions, solely anthropogenic activities, or interactions of both factors. As a consequence, it is difficult to assess how tropical ecosystems will cope with projected changes in precipitation and land-use intensification over the next decades. We investigated the role of fire during the Holocene by combining macroscopic charcoal and the molecular fire proxies levoglucosan, mannosan and galactosan. Combining these two different fire proxies allows a more robust understanding of the complex history of fire regimes at different spatial scales during the Holocene. In order to infer changes in past biomass burning, we analysed a lake sediment core from Lake Pet en Itz a, Guatemala, and compared our results with millennial-scale vegetation and climate change available in the area. We detected three periods of high fire activity during the Holocene: 9500e6000 cal yr BP, 3700 cal yr BP and 2700 cal yr BP. We attribute the first maximum mostly to climate conditions and the last maximum to human activities. The rapid change between burned vegetation types at the 3700 cal yr BP fire maximum may result from human activity.

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“…The sediment samples were wet sieved in a 150 µm mesh sieve. The residue was then soaked in 5 % metaphosphate solution followed by soaking in 8 % hydrogen peroxide solution for 12 hrs to concentrate charcoal particles and bleach all non-charcoal organic matter in the sediment (Stevenson and Haberle, 2005;Schlachter and Horn, 2010;Colombaroli et al, 2014). Washed samples were then scanned under a stereomicroscope at a magnification of 15x to identify and count the charcoal particles.…”

Section: Macro-charcoal Analysismentioning

confidence: 99%

“…An investigation from a South African savanna region reveals that these ecosystems historically alternated between grassland phases maintained by lower levels of water availability, herbivory and less frequent fire events and woody-savanna vegetation phases maintained by increased water availability, herbivore browsing of tree communities, and more frequent/ intense fires (Gillson and Ekblom, 2009). Such studies, which use multiple paleoecological and paleoclimatic proxies like stable isotope ratios of carbon and oxygen (Lisiecki and Raymo, 2005;West et al, 2006), charcoal (Gavin et al, 2007;Colombaroli et al, 2014) and herbivore dung fungal spores (Ekblom and Gillson, 2010;Baker et al, 2012) establish clear links between past climate, disturbance regimes and vegetation changes. However, the timing and magnitude of climatic and disturbance factors are variable across tropical grasslands globally, and further, the effects of these factors on vegetation are also variable, depending on whether systems are mesic or arid (Veldman et al, 2015).…”

mentioning

confidence: 99%

Mid-late Holocene vegetation response to climatic drivers and biotic disturbances in the Banni grasslands of western India

Pillai

Anoop

Sankaran

et al. 2017

Palaeogeography, Palaeoclimatology, Palaeoecology

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Citation:Pillai AAS, Anoop A, Sankaran M, Sanyal P, Jha DK and Ratnam J (2017) AbstractTropical grasslands and savannas are globally extensive, and are of significant environmental, economic, and ecological importance. These ecosystems are anticipated to be particularly sensitive to future changes in climate, and understanding how these systems have responded to climatic changes in the past can provide us with insights into their potential responses to future global change. In this study, the temporal dynamics of C3-C4 vegetation changes in response to changes in moisture availability, local fire events and changing levels of herbivory in a summer-rainfall region of Western India are reconstructed for the past ~4600 cal yr BP. Paleodata such as stable carbon isotope of bulk organic matter ( 13 Corg), oxygen isotope from carbonate shells ( 18 Oshell), macro-charcoal and herbivore dung fungal spores are reported from the retrieved cores of two wetland sites located in the Banni grasslands of Western India. Results show that vegetation in the Banni was composed mostly of C3 vegetation from ~4600 to ~2500 cal yr BP, after which there was a decline in C3vegetation. From the late-Holocene to the present, there was a mix of both C3 and C4 vegetation, with C4 grasses being more abundant in the ecosystem. These shifts were coincident with rainfall changes from more mesic conditions during ~4600 to ~2500 cal yr BP to more arid conditions towards the present as indicated by 18 Oshell isotope data. The period of increase in C4 vegetation also coincides with a period of increased biotic disturbances in the ecosystem, particularly fire. Given the current scenarios of global warming, recurrent drought events and increased anthropogenic use of similar ecosystems, such studies can provide us insights into potential future trajectories of these ecosystems.3

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Contrasting long‐term records of biomass burning in wet and dry savannas of equatorial East Africa

Cited by 49 publications

References 59 publications

Biogeochemical Responses to Holocene Catchment‐Lake Dynamics in the Tasmanian World Heritage Area, Australia

Biogeochemical Responses to Holocene Catchment‐Lake Dynamics in the Tasmanian World Heritage Area, Australia

Combining charcoal sediment and molecular markers to infer a Holocene fire history in the Maya Lowlands of Petén, Guatemala

Mid-late Holocene vegetation response to climatic drivers and biotic disturbances in the Banni grasslands of western India

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