Your search keyword '"Kaboli, Hasan"' showing total 5 results

1. Environmental filtering, predominance of strong competitor trees and exclusion of moderate-weak competitor trees shape species richness and biomass

Author

Ali, Arshad, Sanaei, Anvar, Nalivan, Omid Asadi, Ahmadaali, Khaled, Pour, Mohsen Javanmiri, Valipour, Ahmad, Karami, Jalil, Aminpour, Mohammad, Kaboli, Hasan, and Askari, Yousef

Published

2020

2. Impacts of climatic and edaphic factors on the diversity, structure and biomass of species-poor and structurally-complex forests

Author

Ali, Arshad, Sanaei, Anvar, Li, Mingshi, Nalivan, Omid Asadi, Ahmadaali, Khaled, Pour, Mohsen Javanmiri, Valipour, Ahmad, Karami, Jalil, Aminpour, Mohammad, Kaboli, Hasan, and Askari, Yousef

Published

2020

3. Grazing intensity alters the plant diversity–ecosystem carbon storage relationship in rangelands across topographic and climatic gradients.

Author

Sanaei, Anvar, Sayer, Emma J., Yuan, Zuoqiang, Saiz, Hugo, Delgado‐Baquerizo, Manuel, Sadeghinia, Majid, Ashouri, Parvaneh, Ghafari, Sahar, Kaboli, Hasan, Kargar, Mansoureh, Seabloom, Eric W., and Ali, Arshad

Subjects

PLANT diversity, RANGELANDS, GRAZING, STOCK prices, CARBON sequestration, SOIL topography

Abstract

Plant diversity supports multiple ecosystem functions, including carbon sequestration. Recent shifts in plant diversity in rangelands due to increased grazing pressure and climate changes have the potential to impact the sequestration of carbon in arid to semi‐humid regions worldwide. However, plant diversity, grazing intensity and carbon storage are also influenced by environmental factors such as nutrient availability, climate and topography. The complexity of these interactions limits our ability to fully assess the impacts of grazing on biodiversity–ecosystem function (BEF) relationships.We assessed how grazing intensity modifies BEF relationships by determining the links between plant diversity and ecosystem carbon stocks (plant and soil carbon) across broad environmental gradients and different plant growth forms. To achieve this, we surveyed 1493 quadrats across 10 rangelands, covering an area of 23,756 ha in northern Iran.We show that above‐ground carbon stocks increased with plant diversity across topographic, climatic and soil fertility gradients. The relationship between above‐ground carbon stocks and plant diversity was strongest for forbs, followed by shrubs and grasses. Soil carbon stocks increased strongly with soil fertility across sites, but aridity, grazing, plant diversity and topography were also important in explaining variation in soil carbon stocks. Importantly, above‐ground and soil carbon stocks declined at high grazing intensity, and grazing modified the relationship between plant diversity and carbon stocks regardless of differences in abiotic conditions across sites.Our study demonstrates that relationships between plant diversity and ecosystem carbon stocks persist across gradients of aridity, topography and soil fertility, but the relationships are modified by grazing intensity. Our findings suggest that potential losses in plant diversity under grazing intensification could reduce ecosystem carbon storage across wide areas of arid to semi‐humid rangelands. We discuss the potential mechanisms underpinning rangeland BEF relationships to stimulate future research. Read the free Plain Language Summary for this article on the Journal blog. [ABSTRACT FROM AUTHOR]

Published

2023

4. Big-trees – Energy mechanism underlies forest diversity and aboveground biomass.

Author

Ali, Arshad, Sanaei, Anvar, Li, Mingshi, Asadi Nalivan, Omid, Pour, Mohsen Javanmiri, Valipour, Ahmad, Karami, Jalil, Aminpour, Mohammad, Kaboli, Hasan, and Askari, Yousef

Subjects

PLANT biomass, BIOMASS, STRUCTURAL equation modeling, SOCIAL dominance, CLIMATE change, SPECIES diversity, FOREST biomass, FOREST plants

Abstract

• Ecological mechanisms underlying species diversity and productivity are not mutually exclusive. • Energy-related climatic factors increased large-diameter trees. • Ecogeographic gradients in large-diameter trees increased aboveground biomass. • Available energy promoted big-sized trees for higher forest functioning. • Sites variation shaped forest diversity – biomass relationship. The macro-ecological mechanisms underlying species diversity and productivity are not mutually exclusive, but our understanding is limited to the climatic variation in species richness and productivity along ecogeographical gradients. Yet, the ecogeographical gradients in a few large-diameter trees are not clearly tested on the linkage amongst forest diversity-structure attributes and aboveground biomass in natural forests. Here, we hypothesized that energy-related climatic factors (i.e. available energy) promote few big-sized trees compared to species or functional diversity or remaining-diameter trees, thereby explains the linkage between forest diversity-structure attributes and aboveground biomass (i.e. the 'big-trees – energy hypothesis'). We used a piecewise structural equation modelling on 238 forest plots from three different forest or vegetation types, i.e., moist temperate, semi-humid, and semi-arid, across 12 sites in Iran, in order to test the hypothesized causal relationships amongst geo-topographic, climatic factors, edaphic factors, top 1% large-diameter trees, forest diversity-structure attributes (stand density, species richness or functional diversity or 99% remaining-diameter trees, and functional dominance) and aboveground biomass. Energy-related climatic factors increased large-diameter trees and functional dominance, but not species richness, functional dispersion, remaining-diameter trees, and stand density. Climatic factors generally increased species richness, functional dispersion, stand density, and remaining-diameter trees via ecogeographic gradients in large-diameter trees. Ecogeographic gradients in large-diameter trees and functional dominance overruled the effects of species richness, functional dispersion and remaining-diameter trees on aboveground biomass, and hence providing support to the big-sized trees effect. Our results suggest that positive effects of energy-related climatic factors (i.e. available energy) promote big-sized trees which in turn enhance aboveground biomass, and hence forest functioning. However, all these underlying ecological mechanisms and drivers were highly dependent on sites variation, and hence context-dependent. We argue that the ecogeographic gradients and sites variation in big-sized trees should be included into the integrative ecological modeling for better understanding the species – energy mechanism as well as the diversity – functioning relationship in large-scale natural forests. [ABSTRACT FROM AUTHOR]

Published

2020

5. Tallo: A global tree allometry and crown architecture database.

Author

Jucker T, Fischer FJ, Chave J, Coomes DA, Caspersen J, Ali A, Loubota Panzou GJ, Feldpausch TR, Falster D, Usoltsev VA, Adu-Bredu S, Alves LF, Aminpour M, Angoboy IB, Anten NPR, Antin C, Askari Y, Muñoz R, Ayyappan N, Balvanera P, Banin L, Barbier N, Battles JJ, Beeckman H, Bocko YE, Bond-Lamberty B, Bongers F, Bowers S, Brade T, van Breugel M, Chantrain A, Chaudhary R, Dai J, Dalponte M, Dimobe K, Domec JC, Doucet JL, Duursma RA, Enríquez M, van Ewijk KY, Farfán-Rios W, Fayolle A, Forni E, Forrester DI, Gilani H, Godlee JL, Gourlet-Fleury S, Haeni M, Hall JS, He JK, Hemp A, Hernández-Stefanoni JL, Higgins SI, Holdaway RJ, Hussain K, Hutley LB, Ichie T, Iida Y, Jiang HS, Joshi PR, Kaboli H, Larsary MK, Kenzo T, Kloeppel BD, Kohyama T, Kunwar S, Kuyah S, Kvasnica J, Lin S, Lines ER, Liu H, Lorimer C, Loumeto JJ, Malhi Y, Marshall PL, Mattsson E, Matula R, Meave JA, Mensah S, Mi X, Momo S, Moncrieff GR, Mora F, Nissanka SP, O'Hara KL, Pearce S, Pelissier R, Peri PL, Ploton P, Poorter L, Pour MJ, Pourbabaei H, Dupuy-Rada JM, Ribeiro SC, Ryan C, Sanaei A, Sanger J, Schlund M, Sellan G, Shenkin A, Sonké B, Sterck FJ, Svátek M, Takagi K, Trugman AT, Ullah F, Vadeboncoeur MA, Valipour A, Vanderwel MC, Vovides AG, Wang W, Wang LQ, Wirth C, Woods M, Xiang W, Ximenes FA, Xu Y, Yamada T, and Zavala MA

Subjects

Biomass, Carbon metabolism, Carbon Cycle, Ecosystem, Forests, Trees physiology

Abstract

Data capturing multiple axes of tree size and shape, such as a tree's stem diameter, height and crown size, underpin a wide range of ecological research-from developing and testing theory on forest structure and dynamics, to estimating forest carbon stocks and their uncertainties, and integrating remote sensing imagery into forest monitoring programmes. However, these data can be surprisingly hard to come by, particularly for certain regions of the world and for specific taxonomic groups, posing a real barrier to progress in these fields. To overcome this challenge, we developed the Tallo database, a collection of 498,838 georeferenced and taxonomically standardized records of individual trees for which stem diameter, height and/or crown radius have been measured. These data were collected at 61,856 globally distributed sites, spanning all major forested and non-forested biomes. The majority of trees in the database are identified to species (88%), and collectively Tallo includes data for 5163 species distributed across 1453 genera and 187 plant families. The database is publicly archived under a CC-BY 4.0 licence and can be access from: https://doi.org/10.5281/zenodo.6637599. To demonstrate its value, here we present three case studies that highlight how the Tallo database can be used to address a range of theoretical and applied questions in ecology-from testing the predictions of metabolic scaling theory, to exploring the limits of tree allometric plasticity along environmental gradients and modelling global variation in maximum attainable tree height. In doing so, we provide a key resource for field ecologists, remote sensing researchers and the modelling community working together to better understand the role that trees play in regulating the terrestrial carbon cycle., (© 2022 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2022