Ultramafic geoecology of South and Southeast Asia

Galey, Miranda; Ent, Antony van der; Iqbal, M. C. M.; Rajakaruna, Nishanta

doi:10.1186/s40529-017-0167-9

Cited by 116 publications

(100 citation statements)

References 188 publications

(269 reference statements)

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“…After c. 10 My of isolation, the Australian plate started to collide with the Southeast Asian plate and island arcs from several Pacific plates around the Oligocene‐Miocene boundary (c. 25–20 Ma). The exact geological processes involved were complex both in time and space but, together, caused extensive uplifting at the northern margin of the Sahul Shelf in what is today New Guinea, and shaped the young islands comprising Wallacea (Sulawesi, Maluku Islands, Lesser Sunda Islands) including some of the largest areas of ultramafic bedrock worldwide (Galey, van der Ent, Iqbal, & Rajakaruna, ; Hall, , ). At the same time, temperatures rose again and moist tropical habitats expanded in Australia until the mid‐Miocene climatic optimum.…”

Section: Discussionmentioning

confidence: 99%

“…Despite intervals of strong climatic oscillations, since the middle Eocene tropical rain forests have covered parts of Sundaland, especially in what today is the island of Borneo. Hence, since the large-scale onset of the MFI c. 23 Ma, there has been a large source population of plants adapted to tropical rainforest habitats in Sundaland (Hall, 2013;Morley, 2012 (Galey, van der Ent, Iqbal, & Rajakaruna, 2017;Hall, 2013Hall, , 2017 was offset in Australia by the continued rafting towards the equator, at least in the north but intensive aridification occurred, leading to an overall contraction of mesic biomes, which remained mostly in montane refugial areas along the eastern coast of the continent and in eastern New Guinea, where mountains had been present since the early Oligocene (Bryant & Krosch, 2016;Byrne et al, 2011;Macphail, 2007;Martin, 2006;Quarles van Ufford & Cloos, 2005).…”

Section: Plate Tectonics Climate and The Malesian Floristic Intercmentioning

confidence: 99%

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Predominant colonization of Malesian mountains by Australian tree lineages

Brambach

Leuschner

Tjoa

et al. 2019

Journal of Biogeography

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Aim Massive biota mixing due to plate‐tectonic movement has shaped the biogeography of Malesia and during the colonization process, Asian plant lineages have presumably been more successful than their Australian counterparts. We aim to gain a deeper understanding of this colonization asymmetry and its underlying mechanisms by analysing how species richness and abundance of Asian versus Australian tree lineages in three Malesian subregions change along environmental gradients. We hypothesize that differing environmental histories of Asia and Australia, and their relation to habitats in Malesia, have been important factors driving assembly patterns of the Malesian flora. Location Malesia, particularly Sundaland, the Philippines and Wallacea. Taxon Seed plants (trees). Methods We compiled plot‐level data of environmental variables and tree abundances from three Malesian subregions. For each species, we inferred its geographical ancestry (Asian or Australian) based on published phylogenetic studies and the fossil record. We used proportions of Australian versus Asian species and individuals per plot to test how they are related to environmental parameters and geographical position using logistic regression models. Results Proportionally more Australian (and fewer Asian) tree species and individuals occurred (a) at higher elevations, (b) on sites over ultramafic parent material and (c) closer to their source region Australia with a significant increase of Australian elements east of Wallace's line. The trend was stronger for individuals than for species. Main conclusions Long‐term environmental similarities between source and sink habitats have shaped the assembly of the Malesian flora: Tree lineages from tropical Southeast Asia predominantly colonized the Malesian lowlands and rich soils, whereas trees from montane refuges in Australia were more successful in the newly emerging Malesian mountains and on poorer soils. The biogeographical patterns caused by the Malesian Floristic Interchange point to the importance of phylogenetic biome conservatism in biotic interchanges and resemble those resulting from the Great American Biotic Interchange in the Neotropics.

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Section: Discussionmentioning

confidence: 99%

Section: Plate Tectonics Climate and The Malesian Floristic Intercmentioning

confidence: 99%

Predominant colonization of Malesian mountains by Australian tree lineages

Brambach

Leuschner

Tjoa

et al. 2019

Journal of Biogeography

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“…Unlike P. rufuschaneyi, which is restricted to only two localities in Sabah, Rinorea cf. bengalensis is widespread in Southeast Asia (Brooks and Wither, 1977;Galey et al, 2017). It occurs on both ultramafic and non-ultramafic soils, with only the populations on ultramafic soils hyperaccumulating Ni, making it a facultative hyperaccumulator (Brooks and Wither, 1977).…”

Section: Plant Speciesmentioning

confidence: 99%

Growth effects in tropical nickel‐agromining ‘metal crops' in response to nutrient dosing

Nkrumah

Echevarria

Erskine

et al. 2019

J. Plant Nutr. Soil Sci.

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Agromining is an emerging technology that utilizes selected ‘metal crops' (= hyperaccumulator plants) to extract valuable target metals from unconventional resources for profit from mineralised soils. Growth characteristics, shoot metal concentrations, and agrominable locations are important considerations in economic agromining. Globally, the greatest potential for nickel (Ni) agromining exists in the tropics. However, the agronomic systems of tropical ‘metal crops' have not been previously tested. Furthermore, it is currently unknown whether nutrient dosing of prospective tropical agromining Ni ‘metal crops’ could possibly cause a shoot Ni‐dilution effect which may ultimately limit economically viable Ni yields. We undertook a pioneering study on Ni uptake and growth responses to nutrient dosing in two promising tropical ‘metal crops' (Phyllanthus rufuschaneyi and Rinorea cf. bengalensis). The experiment consisted of a large randomised block growth trial in large pots over 12 months in Sabah (Malaysia). At 3‐month intervals, the plants were exposed to soluble treatments that altered available concentrations of nitrogen (N), phosphorus (P), and potassium (K). We found strong positive growth responses to N and P additions in P. rufuschaneyi, whereas K additions had negative growth effects. In R. cf. bengalensis, all treatments had positive growth effects. The increases in biomass in response to nutrient dosing did not significantly reduce shoot Ni concentrations in both species, with the exception of N addition in P. rufuschaneyi. This study reveals that Ni uptake and growth responses to nutrient dosing are species‐dependent, primarily influenced by the ecophysiology of the species. Inorganic fertilization could possibly be an important component of the management of local ‘metal crops' to be used in viable commercial agromining in the tropics, but this needs to be tested in the field with different formulations of N, P, and K.

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“…Whittaker 1954;Main 1974;Main 1981;Galey et al 2017;Gonneau et al 2017;Van der Ent et al 2017;Van der Ent et al 2018). Although knowledge about relationships between metals with other elements or factors in plants is broad, it is still difficult to final identify the causes of differences in Ni, Cr, and Co content in plants from Polish ultramafic soils.…”

Section: Accumulation Of Metals By Plantsmentioning

confidence: 99%

Rock-type control of Ni, Cr, and Co phytoavailability in ultramafic soils

et al. 2017

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Background and aims Ultramafic soils constitute an extreme environment for plants because of specific physico-chemical properties and the presence of Ni, Cr, and Co. We hypothesized that type of ultramafic parent rock depending on their origin affects the composition of soils and plants. Therefore, phytoavailability of metals would be higher in soil derived from serpentinized peridotite compared to serpentinite because of differences in susceptibility of minerals to weathering. Results Based on DTPA-CaCl 2 extractions, we noted that soil derived from the serpentinized peridotite is characterized by a higher phytoavailability of Ni compared to soil derived from the serpentinite. On the contrary, plant species growing on soil derived from the serpentinite contain higher concentrations of metals. Conclusions Our study suggests that the metal uptake by plants is controlled by the mineral composition of parent rocks, which results from both their original magmatic composition and later metamorphic processes. Chemical extractions show that the phytoavailability of Ni and Co is higher in soil derived from the serpentinized peridotite than the serpentinite. Surprisingly, plants growing on the soil derived from the serpentinite contain higher levels of metals compared to these from the serpentinized peridotite derived soil. This contrasting behavior is due to higher abundances of Ca and Mg, not only Ni and Co, in soil derived from the serpentinized peridotite as compared to those in the soil derived from the serpentinite. Calcium and Mg are favored by plants and preferably fill the available sites, resulting in low Ni and Co intake despite their higher abundances.

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Ultramafic geoecology of South and Southeast Asia

Cited by 116 publications

References 188 publications

Predominant colonization of Malesian mountains by Australian tree lineages

Predominant colonization of Malesian mountains by Australian tree lineages

Growth effects in tropical nickel‐agromining ‘metal crops' in response to nutrient dosing

Rock-type control of Ni, Cr, and Co phytoavailability in ultramafic soils

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