Factors Determining Forest Diversity and Biomass on a Tropical Volcano, Mt. Rinjani, Lombok, Indonesia

Dossa, Gbadamassi G.O.; Paudel, Ekananda; Fujinuma, Junichi; Yu, Haiying; Chutipong, Wanlop; Yuan, Zuoqiang; Paz, Sherryl L.; Harrison, Rhett D.

doi:10.1371/journal.pone.0067720

Cited by 36 publications

(31 citation statements)

References 66 publications

(69 reference statements)

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“…Temperature stress at high altitudes could result in phylogenetic clustering, as reported for other taxa like birds, bees, butterflies, microbes (Qian et al, 2014 and references therein), and plants (e.g., Dossa et al, 2013). However, we found deep phylogenetic overdispersion in higher elevation forests.…”

Section: Distinct Causes Of Phylogenetic Overdispersionsupporting

confidence: 76%

Phylogenetic diversity in the Western Ghats biodiversity hotspot reflects environmental filtering and past niche diversification of trees

Bose

Ramesh

Pélissier

et al. 2018

Journal of Biogeography

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Aim We examined how contrasted climatic conditions influenced the ecological and phylogenetic diversity of tropical trees at the regional scale. Beyond the basic expectation of greater environmental filtering in currently stressful contexts, we addressed how biogeographic history and past climates contributed to shaping the distribution and diversity of extant taxa. Location Evergreen forests of Western Ghats, India. Methods We evaluated the relative importance of niche‐based, historical, and spatial processes on community phylogenetic structure and turnover in 297 plots including 459 species. If niche conservatism prevails, we expected greater phylogenetic clustering under harsher or historically less stable climates, and overdispersion in opposite conditions. To test the role of environmental filtering in shaping local communities, we assessed species’ climatic niches and congruence between niche and phylogenetic diversity. To assess the imprint of ancient versus recent evolutionary constraints, we calculated mean pair‐wise (MPD) and nearest‐taxon (MNTD) phylogenetic distances, respectively. Results We found non‐random phylogenetic structure depending on both current and past climatic variation. Basal community phylogenetic structure (MPD) was related to niche diversity and varied according to hydric stress: (a) northern environments filtered more closely related species, while (b) phylogenetic overdispersion suggested greater niche differentiation in stable, least‐seasonal southern habitats and at high elevations. Terminal phylogenetic structure (MNTD) did not show overdispersion. Phylogenetic turnover was driven by current abiotic factors, not space. Main conclusions The patterns of ecological and phylogenetic diversity likely reflect the Miocene climate shift to increasing seasonality northwards. Phylogenetic clustering under hydric stress or historical instability suggests the influence of functional conservatism, whereas overdispersion in southern forests supports the persistence of old lineages in an ancient rain forest refugium as an evolutionary museum. Overdispersion in fragmented montane forests reflects a mixture of biogeographically distinct species pools, both tropical and temperate, that characterise environmentally contrasted cores and fringes. Low phylogenetic turnover along the seasonality gradient suggests recent ecological diversification across forests with contrasted rainfall seasonality.

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Section: Distinct Causes Of Phylogenetic Overdispersionsupporting

confidence: 76%

Phylogenetic diversity in the Western Ghats biodiversity hotspot reflects environmental filtering and past niche diversification of trees

Bose

Ramesh

Pélissier

et al. 2018

Journal of Biogeography

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“…Compared with TMF outside Africa, our AGB estimates (which range from 117 to 612 Mg ha -1 , mean of all plots studied 276 Mg ha -1 ) seem high, particularly in Mt Nyiro. For example, AGB ranged between and 200 Mg ha -1 (1500-2500m) in Andean TMF (Girardin et al, 2014), between 100 and Mg ha -1 (1000 and 2200m) at Mt Rinjani in Indonesia (Dossa et al, 2013), while it was estimated at Mg ha -1 and 271 Mg ha -1 for submontane and montane Atlantic forest in Brazil (Alves et al, 2010). Interestingly, it has been reported that Asian and Neotropical TMFs have similar mean AGB (257 and 247 Mg ha −1 , n = 31 and 56, respectively) while that of African TMF is higher (527 Mg ha −1 n = 7) (Spracklen and Righelato, 2014).…”

Section: The Variable Agb Per Forest Typementioning

confidence: 99%

“…Generally, there is a decline in tree species richness with increasing altitude (e.g. Dossa et al, 2013;Sassen and Sheil, 2013;Girardin et al, 2014), because of a greater role of environmental filtering at higher elevations (e.g. cooler temperatures, fog, reduced light incidence and higher relative humidity).…”

Section: Introductionmentioning

confidence: 99%

New insights on above ground biomass and forest attributes in tropical montane forests

Cuní-Sanchez

Pfeifer

Marchant

et al. 2017

Forest Ecology and Management

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23Despite the potential of tropical montane forests to store and sequester substantial amounts of 24 carbon, little is known about the above ground biomass (AGB) and the factors affecting it in 25 these ecosystems, especially in Africa. We investigated the height-diameter allometry, AGB, 26 and related differences in AGB to taxonomic and structural forest attributes in three distinct 27 forest types (dry, mixed species and elfin) in three mountains of northern Kenya. We

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“…Recently, many researchers have found that forest diversity is positively linked with aboveground biomass [45][46][47][48][49]. However, the quantitative relationship between AGB and structure -species diversity is poorly understood.…”

Section: Novel Contributionmentioning

confidence: 99%

Retrieval of Tropical Peatland Forest Biomass From Polarimetric Features in Central Kalimantan, Indonesia

Waqar¹,

Sukmawati²,

Ji³

et al. 2020

PIER C

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In this research, the potential of L-band SAR data is evaluated for tropical peatland forest biomass estimation using polarimetric features and field data. For this, ALOS-2 full polarimetric data are acquired over central Kalimantan, Indonesia. Total 54 sampled plots (20 m × 20 m) were established in the study site; diameter at breast height (DBH) and tree species of every tree were collected in each plot. Locally developed allometric equations were used to convert field data to biomass and plot level biomass, and the upscaling factor was applied to upscale plot level biomass to standard tones per hectare scale. Backscattering coefficient (σ o) was computed for HH, HV, V H and V V polarization. Similarly, eigen decomposition was performed to extract: entropy (E), alpha (α), and anisotropy (A); also diversity indices were computed. Yamaguchi decomposition was performed to extract scattering behavior of forest in central Kalimantan. All polarimetric parameters were upscaled to one-hectare scale. Field data were divided into training plots (70 percent → 42 plots) and validation plots (30 percent → 12 plots). Nonlinear regression analysis was performed between polarimetric parameters and training plots. Perplexity, Shannon index, entropy, Gini Simpson index, index of qualitative inversion, Reyni entropy (order 2), σ HV , alpha, σ V V , and volumetric scattering component were found significantly correlated (ranging R 2 from 0.67 to 0.49) with the field data. The corresponding nonlinear model was inverted, and biomass maps were computed for the individual model. The resultant biomass maps were validated using a validation set of referenced measurements. Perplexity, Shannon index, entropy, Gini Simpson index, index of qualitative inversion, Reyni entropy (order 2), σ HV , alpha, σ V V , and volumetric scattering exhibited a significant correlation between field biomass and predicted biomass computed using developed model. R 2 for validation ranges from 0.95 to 0.81 with RMSE ranging from 13.59 Mgha −1 to 25.63 Mgha −1. The estimated biomass in study site ranges from 49.31 Mgha −1 to 290.60 Mgha −1 .

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Factors Determining Forest Diversity and Biomass on a Tropical Volcano, Mt. Rinjani, Lombok, Indonesia

Cited by 36 publications

References 66 publications

Phylogenetic diversity in the Western Ghats biodiversity hotspot reflects environmental filtering and past niche diversification of trees

Phylogenetic diversity in the Western Ghats biodiversity hotspot reflects environmental filtering and past niche diversification of trees

New insights on above ground biomass and forest attributes in tropical montane forests

Retrieval of Tropical Peatland Forest Biomass From Polarimetric Features in Central Kalimantan, Indonesia

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