Your search keyword '"Allometric equation"' showing total 496 results

1. A general allometric model for urban vines to estimate above-ground biomass

Author

Tao, Qiuyu, Sun, Han, Fan, Dayong, and Wang, Xiangping

Published

2025

2. Development of allometric equations for grafted sapota (Manilkara zapota) through destructive tree sampling for non-destructive estimation of tree biomass.

Author

Ganeshamurthy, A. N., Rupa, T. R., Alivelu, Karusala, Rajendran, S., Laxman, R. H., Ramanandan, G., Mohapatra, S., and Aruna, B.

Subjects

*ALLOMETRIC equations, *BIOMASS estimation, *MANGO, *FRUIT trees, *TREE age, *TREE branches, *TREES

Abstract

Sapota fruit tree biomass cannot be estimated using general forest tree allometric equations involving measurement of diameter at breast height (DBH) as grafted sapota tree branches below this height. Therefore grafted sapota trees of commercial orchards require an independent allometric equation for nondestructive estimation of tree biomass. Sapota allometric equations were hence developed with a destructive sampling of grafted sapota trees using parameters other than DBH and compared with other equations developed for grafted mangoes. The selected allometric parameters were significantly related to the age of the trees. The root-to-shoot ratio also differed from those reported for forest trees. The biomass expansion factor by and large attained stability beyond 16 years of tree age. The equations so developed generally fitted the data well, and in most cases, more than 50% of the observed variation in biomass was explained by primary branch girth x number of primary branches. There was a good agreement between the observed and the predicted biomass using both multiple linear regression and power model equations. Further, our purpose was to see if the grafted mango tree equation can predict sapota tree biomass. The results of this study confirmed that the mango equation equally predicts sapota tree biomass and hence the mango tree allometric equation can also be used for estimating sapota tree biomass efficiently. [ABSTRACT FROM AUTHOR]

Published

2024

3. Evaluation of biomass, carbon storage capability, tree-ring and cork-ring growth of <italic>Quercus suber</italic>: a review.

Author

Mechergui, Kaouther, Jaoaudi, Wahbi, Bello-Rodríguez, Víctor, Achour, Hammadi, and Ammari, Youssef

Subjects

*CORK oak, *ALLOMETRIC equations, *BIOMASS production, *FORESTS & forestry, *BIODIVERSITY conservation

Abstract

BackgroundAimsMethodsResultsConclusionCork oak (Quercus suber) forests and woodlands cover an area of ca. 2.1 M ha in the Mediterranean Basin. Cork oak stands are important for biodiversity conservation, and ecosystem services (carbon storage and the provision of cork, timber, and firewood). Their sustainable management is essential for their continued multifunctional existence and for providing ecosystem services.The aims of this study were to estimate the biomass production of the species and quantify its potential carbon storage capacity in the Mediterranean Basin and to make management recommendations.We used a literature survey of allometric equations and cork annual total tree-ring growth data and applied them to determine the productivity of the species. Estimate biomass by using regression models and dendrometric characteristics is very important for cork oak in the Mediterranean region.The studies reported a wide-ranging above-ground biomass for cork oak: 42 Mg ha−1 for Italy, 64–120 Mg ha−1 for Morocco, 41–50 Mg ha−1 for Portugal, 29–328 Mg ha−1 for Spain, and 80–312 Mg ha−1 for Tunisia. The radial wood increment ranged from 0.78 to 8.01 mm yr−1. The annual increment of cork-ring growth was between 0.8 mm yr−1 (northern Algeria) and 5.25 mm yr−1 (Spain), with most values being between 2 and 4.4 mm yr−1. In dry years, major reductions (10−15%) in the growth of Quercus suber were observed.Most studies showed stand-specific growth responses to climate variables, with the radial growth of cork oak being greater in relatively mesic and cool conditions. [ABSTRACT FROM AUTHOR]

Published

2024

4. Productivity of hybrid sweetgum (Liquidambar formosana x styraciflua) plantations compared to native sweetgum (L. Styraciflua) in the Western Gulf Region of south-central U.S.

Author

Lewis, Jacob, Will, Rodney, Zhai, Lu, Murray, Bryan, Blazier, Michael, and Joshi, Omkar

Subjects

ALLOMETRIC equations, SPECIFIC gravity, BIOMASS, WOOD, WOOD quality

Abstract

Sweetgum (Liquidambar styraciflua) is an excellent short-rotation woody crop species for producing hardwood pulp and biofuel feedstock on marginal sites. A recent development which may improve growth is the production of hybrid sweetgum (L. formosana x styraciflua) clones. We compared the productivity and attributes, e.g., wood specific gravity and stand growth, of operational plantations of hybrid sweetgum clones to improved native sweetgum half-sib families in 36 stands in Oklahoma, Texas, and Louisiana, U.S. The least square means (LSMean) of wood specific gravity was significantly greater for hybrids clones than the half-sibs (0.49 vs. 0.46 g/cm3), and the hybrid clones had less taper which necessitated developing genotype-specific volume and biomass equations. Despite having less fertilizer inputs on average, the hybrids had greater standing green stem biomass than the half-sibs at an age of 8.5 years (LSMean of 73.3 vs. 51.9 Mg/ha). The hybrids as a group also exhibited greater green biomass growth during the 2022 growing season when compared to the half-sibs at 8.5 years (LSMean of 15.8 vs. 11.4 Mg/ha/y). Therefore, the hybrids provide growth and wood quality advantages that may provide an opportunity to increase productivity and profitability of hardwood SRWC plantings. [ABSTRACT FROM AUTHOR]

Published

2024

5. Sleet damage to branches and crowns of street camphor trees (Cinnamomum camphora) in a central China mega-city: damage statistics, modelling, and implications.

Author

Yichen Liu, Junru Zhang, Shanshan Rao, and Kun Xu

Subjects

URBAN trees, EXTREME weather, ALLOMETRIC equations, TREE size, RANDOM forest algorithms, FOREST biomass

Abstract

Introduction: Extreme weather becomes increasingly frequent and severe under climate change, causing unexpected damage to trees. Among them, sleet damage is particularly harmful to evergreen trees in subtropical area. Camphor trees (Cinnamomum camphora), as dominant street trees in central China, are prone to sleet damage, resulting in loss of valuable ecosystem functions. Methods: By measuring tree size characteristics of 118 camphor trees before and after a record-breaking sleet event in Wuhan, a mega-city in central China, we built allometric equations between size and volume of broken branches and used the random forest regression to model sleet damage to camphor trees. Results: We identified that larger trees with intermediate bole height suffered more than smaller trees with tall bole height from the sleet event. We estimated the volume of broken branches of a camphor tree with DBH at 35.0 cm as 106.4 dm3, equivalent to 55.3 kg biomass loss, from the sleet event. Discussion: We suggest that pruning the branches instead of topping the main stems of small camphor trees would reduce the sleet hazard. To mitigate the negative impacts of climate change, regular pruning should be practiced on street camphor trees to protect them from future heavy sleet events. [ABSTRACT FROM AUTHOR]

Published

2024

6. Development of site-specific allometric equation and predicting aboveground biomass of natural and plantation forests of Oxytenathera abyssinica (A. Rich.) Munro, Northwestern Ethiopia

Author

Habtamu Achenef Tesema, Beyene Belay, and Asabeneh Alemayehu

Subjects

Allometric equation, Carbon sequestration, Carbon trade, Oxytenanthera abyssinica, Ethiopia, Forestry, SD1-669.5

Abstract

Bamboo is an ideal plant for commercial production due to its rapid growth rate, high biomass production, low cost of production and environmental friendliness. Although Ethiopia has the highest bamboo cover in Africa, allometric equations for estimating its biomass are scarce. Most allometric models developed to date have been largely concerned with trees and shrubs. The objective of this study was to generate species- and site-specific allometric models that could be used to estimate the total aboveground dry biomass and culm dry biomass of lowland bamboo in northwest Ethiopia. Three power form-based allometric models were created using diameter at breast height (DBH) and culm height (H) as independent variables. One hundred and eight Oxytenathera abyssinica culms were used to predict the total aboveground biomass and culm biomass. Model one (M1) was the best model to predict the culm and total aboveground biomass of the species, regardless of forest type. The allometric models may provide useful information about aboveground biomass and culm biomass estimation methods to forestry professionals, bamboo producers and other stakeholders, and could help in the calculation of the country’s contribution to global carbon sequestration and trade.

Published

2024

7. The Application of the Classical Assumption Test in Multiple Linear Regression Analysis (a Case Study of the Preparation of the Allometric Equations of Young Makila)

Author

Gun Mardiatmoko

Subjects

allometric equation, classicalassumption test, biomass, sapling, climate change., Mathematics, QA1-939

Abstract

The preparation of allometric equations generally uses multiple linear regression equations. The use of this regression equation is usually not carried out through various tests but goes directly to the t test and F test stages. Therefore, this paper aims to provide an example of determining the regression equation through the classical assumption test stages. Makila (Litsea angulata BI) was chosen as an example because it provides environmental services, especially in dealing with climate change and has not been widely studied. The research method used is a quantitative method. Destructive sampling was taken and the material used consisted of 40 young Makila plants planted in polybags next to the greenhouse at the Faculty of Agriculture, Pattimura University, Ambon. The diameter of each sample was measured from the ground surface to a height of 5 cm and numbered 1 to 40. After being coded, the plant samples were cut down and all young trees were divided into stem segments, branches, twigs, leaves and roots. The root segments were collected carefully to facilitate their separation from the soil in polybags. The parts of the roots that still contain soil are cleaned with a machete and brush until they are free of soil and other dirt. Next, each segment was weighed for its wet weight (in g) and dry weight, thus enabling the determination of the biomass content (in g) for each segment. Data analysis was carried out using the Multiple Linear Regression Equation method. The regression model was examined for normality and suitability in predicting independent variables, ensuring there were no issues with multicollinearity, heteroscedasticity, and autocorrelation. The results of the normality test showed that the significance value for the remaining data was 0.813 > 0.05, indicating normal distribution. TThe results of the multicollinearity test show that there is no multicollinearity problem, this is indicated by the VIF value of the two independent variables (tree diameter and tree height each 1.049) < 10 and the Tolerance value (tree diameter and tree height 0.953 each) > 0.100. The results of the heteroscedasticity test show that the two independent variables have a significance value of more than 0.05. The results of the autocorrelation test show the Durbin Watson (DW) value = 1.956 with a range of 1.65 – 2.35 which means there is no correlation problem. The results yielded a multiple linear regression: Y = -1131.146 + 684.799X1 + 4.276X2, where Y is biomass, X1 is the diameter, and X2 is the tree height. Based on the results of the t-test: variable X1 partially affected Y while variable X2 partially had no effect on Y. The F-test indicated that variables X1 and X2 jointly affected Y with R Square: 0.919 or 91.9% and the rest was influenced by other unexplored factors. To simplify biomass prediction and field measurement, a regression equation that used only 1 independent variable, namely tree diameter, was used for the experiment. Allometric equation only used 1 variable, Y = - 1,084,626 + 675,090 X1, where X1 = tree diameter, Y = Total biomass with R = 0.957, and R square = 0.915. The regression equation for young Makila plant provides assurance that the regression equation obtained is accurate in estimation, unbiased and consistent. This is because in data processing classical assumptions have been tested. This equation can save time, costs and energy, as well as make measurements easier in the field so that future researchers can develop allometric equations in other plants for efficiency.

Published

2024

8. Aboveground Biomass and Carbon Storage in Mangrove Forests in Southeastern Mexico.

Author

Ávila-Acosta, Carlos Roberto, Domínguez-Domínguez, Marivel, Vázquez-Navarrete, César Jesús, Acosta-Pech, Rocío Guadalupe, and Martínez-Zurimendi, Pablo

Subjects

CARBON sequestration in forests, MANGROVE plants, MANGROVE forests, BIOMASS, CARBON sequestration, CLIMATE change mitigation

Abstract

The aboveground contributions of mangroves to global carbon sequestration reinforce the need to estimate biomass in these systems. The objective was to determine the aboveground biomass storage and quantify the carbon and CO2e content in Rhizophora mangle, Avicennia germinans, and Laguncularia racemosa present in southeastern Mexico. Based on the Forest Protocol for Mexico Version 2.0 methodology, published by Climate Action Reserve, 130 circular plots were randomly selected and established in an area of 930 ha of mangrove vegetation, and the aboveground biomass and stored carbon were determined. The mangrove had a density of 3515 ± 428.5 individuals per hectare. The aboveground biomass of the three species was 120.5 Mg ha−1. The biomass of L. racemosa was 99.5 Mg ha−1, which represents 82.6% of the total biomass. The biomass of R. mangle was 20.33 Mg ha−1, and that of A. germinans was 0.32 Mg ha−1. The total carbon retained in the trees was 60.25 Mg C ha−1 and 221.1 Mg CO2e ha−1. Laguncularia racemosa generated the highest contributions of CO2e. The area of mangroves accumulated 112,065 Mg of aboveground biomass. The carbon contained in this biomass corresponds to 205,623 Mg CO2e. This mangrove contributes to mitigating the effects of climate change globally through the reduction in greenhouse gases. [ABSTRACT FROM AUTHOR]

Published

2024

9. Remote sensing, allometry, and carbon stocks of Phyllostachys aurea in the Western Highlands of Cameroon

Author

Rene Kaam, Martin Tchamba, Barnabas Neba Nfornkah, and Cédric Chimi Djomo

Subjects

Bamboo, Allometric equation, Remote sensing, Bamboo distribution, Phyllostachys aurea, Carbon stocks, Forestry, SD1-669.5

Abstract

The fight against climate change is one of the major concerns of the international community and has led to a search to identify cost-effective ways to manage ecosystems in a way that removes atmospheric carbon-dioxide while providing essential societal benefits. As bamboo ecosystems in Cameroon are poorly known, this study sought to evaluate the distribution of bamboo, develop allometric equations for it and estimate carbon stocks associated with bamboo in the Western Highlands of Cameroon. Landsat 8 OLI imagery was used to increase data on the distribution and carbon stocks of Phyllostachys aurea Carrière ex Rivière & C. Rivière in the study area. P. aurea is reportedly the most exploited species for ecological, socioeconomic and cultural activities in the region, posing a challenge for the sustainability of the species. Twelve circular plots were established in P. aurea stands in the Western Highlands. Five per cent of the bamboo stems were harvested. Every stem was sorted into leaves, branches, and culms. These were weighed, and sub-samples taken to the laboratory. Sub-samples were oven-dried for biomass estimation. Regression analysis was used to develop the allometric equations. The best equation was used to estimate the carbon stocks. The Western Highlands region of Cameroon is estimated to have 241,296 ha of bamboos. The dominant bamboo species identified in the study area include Oldeania alpina (K.Schum.) Stapleton (syn. Yushania alpina K.Schum.), Bambusa vulgaris Schrad. ex J.C.Wendl. and P. aurea. Focusing on P. aurea the best fit equation with a bias of − 6.98%, Adj.R² = 0.711, AIC = 17 and RSE = 0.262, was selected. The mean density of P. aurea was 38,017 ± 4510 culms.ha−1. The mean culm aboveground biomass was 3.15 ± 0.94 kg. The AGB of P. aurea was estimated at 119.05 ± 3.63 t.ha−1, mean AGC was 55.95 ± 5.81 t C.ha−1 and mean aboveground carbon dioxide equivalence (AGCO2eq) was 205.35 ± 58.01.22 t CO2.ha−1. P. aurea constitutes a significant carbon sink in the Western Highlands of Cameroon. Policymakers and development planners should therefore recommend this species for carbon markets, international initiatives such as AFR100, and the Nationally Determined Contribution addressing the United Nations Sustainable Development Goal 13 (SDG13) to combat climate change.

Published

2024

10. Individual Tree-Scale Aboveground Biomass Estimation of Woody Vegetation in a Semi-Arid Savanna Using 3D Data.

Author

Muumbe, Tasiyiwa Priscilla, Singh, Jenia, Baade, Jussi, Raumonen, Pasi, Coetsee, Corli, Thau, Christian, and Schmullius, Christiane

Subjects

*BIOMASS estimation, *SAVANNAS, *ALLOMETRIC equations, *SAVANNA ecology, WOOD density

Abstract

Allometric equations are the most common way of assessing Aboveground biomass (AGB) but few exist for savanna ecosystems. The need for the accurate estimation of AGB has triggered an increase in the amount of research towards the 3D quantification of tree architecture through Terrestrial Laser Scanning (TLS). Quantitative Structure Models (QSMs) of trees have been described as the most accurate way. However, the accuracy of using QSMs has yet to be established for the savanna. We implemented a non-destructive method based on TLS and QSMs. Leaf-off multi scan TLS point clouds were acquired in 2015 in Kruger National Park, South Africa using a Riegl VZ1000. The 3D data covered 80.8 ha with an average point density of 315.3 points/m2. Individual tree segmentation was applied using the comparative shortest-path algorithm, resulting in 1000 trees. As 31 trees failed to be reconstructed, we reconstructed optimized QSMs for 969 trees and the computed tree volume was converted to AGB using a wood density of 0.9. The TLS-derived AGB was compared with AGB from three allometric equations. The best modelling results had an RMSE of 348.75 kg (mean = 416.4 kg) and a Concordance Correlation Coefficient (CCC) of 0.91. Optimized QSMs and model repetition gave robust estimates as given by the low coefficient of variation (CoV = 19.9% to 27.5%). The limitations of allometric equations can be addressed by the application of QSMs on high-density TLS data. Our study shows that the AGB of savanna vegetation can be modelled using QSMs and TLS point clouds. The results of this study are key in understanding savanna ecology, given its complex and dynamic nature. [ABSTRACT FROM AUTHOR]

Published

2024

11. DEVELOPMENT OF A CARBON IN ABOVEGROUND BIOMASS FORECAST MODEL FOR UNDERUTILISED SPECIES IN QUIRINO FOREST LANDSCAPE PROJECT, PHILIPPINES.

Author

G. B., Orpiano, R. P., Manuel, E. T., Carig, and J. G., Carig

Subjects

*CLIMATE change mitigation, *BIOLOGICAL extinction, *SECONDARY forests, *BIOMASS, *FOREST management, *FOREST biomass, *CLIMATE change denial

Abstract

Sustaining forest carbon sinks is a priority in climate change mitigation and forest management strategies. However, several issues confront the role of Philippine forests in climate change mitigation. These include the loss of old-growth cover, unsustainable forest landuse practices, and lack of site-specific modelling. These are the realities in the Quirino Forest Landscape Project (QFLP), a semi-contiguous collection of secondary forests in four municipalities of Quirino Province. This study was undertaken to develop a forecast model for carbon in aboveground of underutilised trees in QFLP. Data were collected through field inventory, the National Mapping and Resource Information Authority Land Cover Databases, and secondary sources. Multiple linear regression, principal components analysis, and biodiversity indices were used to analyse the data collected from different sampling areas to develop a forecast model. Findings suggest that the QFLP forest was secondary, as evidenced by the fact that > 60% of the trees were underutilised. With the ongoing decline in forest cover due to resource use and lack of forestry policy enforcement, it is worth noting that the carbon sequestration potential of underutilised species is not dependent on ecological dominance; that is, species that are more vulnerable to local extinction have higher potential to gain carbon. Given all the variables and their high forecasting power, the study demonstrated that the developed model was precise enough to provide future carbon capture values for QFLP. [ABSTRACT FROM AUTHOR]

Published

2024

12. Ecosystem carbon sequestration of Zanthoxylum bungeanum plantations under the farmland conversion in the arid valley of the upper reaches of Yangtze River, China.

Author

Lv, Chen, Saba, Tahseen, Wang, Jingyan, Hui, Wenkai, and Gong, Wei

Subjects

*LAND degradation, *CARBON sequestration, *ZANTHOXYLUM, *PLANT biomass, *PLANTATIONS, *ECOSYSTEMS

Abstract

Aims: Vegetation restoration has been widely implemented to achieve carbon (C) sequestration and prevent land degradation, and this study aims to evaluate the ecosystem C pools and C sequestration effectiveness of different land-use types. Methods: In this study, the plant biomass C stock, litter C stock, soil organic C (SOC) stock and ecosystem C sequestration in Zanthoxylum bungeanum plantations (with stand ages of 28, 20, 15 and 8 years, abbreviated as ZB28, ZB20, ZB15 and ZB8, respectively), abandoned land (AL) and farmland (FL) were estimated. Results: (1) the plant biomass and biomass C stock of above-and below-ground increased after farmland conversion, and all of them ranked as ZB28 > ZB20 > ZB15 > AL > ZB8 > FL; (2) the litter stock and C stock, and SOC concentration and stock of different land-use types ranked as AL > Z. bungeanum plantations > FL, and these indices increased with the stand age; (3) the C stock of the ecosystem in FL was 115.4 Mg C ha−1, and the C stock of the ecosystem increased by 8.9–66.6 Mg C ha−1 and 52.4 Mg C ha−1 after the conversion of FL to Z. bungeanum plantations and AL, respectively; (4) and soil C sequestration accounts for 55.6–83.6% of ecosystem C sequestration after farmland conversion. Conclusions: This implies that the conversion of farmland to Z. bungeanum plantations was the best approach in the arid valley area when the ecosystem C sequestration and economic benefits were considered. [ABSTRACT FROM AUTHOR]

Published

2024

13. Investigating the biomass and carbon stock of the tree layer in the Marivan forests (Case study: Garan and Dolah Naw forest stands).

Author

Haidari, Maziar, Iranmanesh, Yaghoub, and Pourhashemi, Mehdi

Abstract

Background and objectives: The Zagros forests vegetation area, with an area of more than 5 million hectares and providing more than 40% of the country's water, is ecologically very important. The forest covers 256,000 hectares of Kurdistan province (8.8% of the province) and makes a significant contribution to carbon sequestration. Atmospheric carbon dioxide has increased significantly in recent decades. In reducing atmospheric carbon dioxide, vegetation and the soil beneath it play a very important role. The aerial parts of trees (the ground layer) contribute greatly to biomass production and carbon sequestration. The purpose of this research was to investigate the carbon sequestration of the tree layer in two sample plots: Garan (Gargh and protected stands) and Dolah Naw (typical forests of the province). Methodology: In order to carry out this research, two samples from Garan and Dolah Naw in Marivan County were selected. In each region, a square sample plot of one hectare was established, and with 100% statistical inventory, quantitative characteristics, including tree species, breast diameter, tree height, crown height, and crown area, were recorded. In both sample plots, the trunks and top branches of the trees were sampled, and for this purpose, three trees were selected for each species in each plot. Samples were taken from the trunk, main branches, and secondary branches of the trees. In the laboratory, the wet weight, dry weight, and carbon percentage of wood samples were calculated by burning the dried samples in an electric furnace. Then, the above-ground biomass of trees was calculated using allometric equations, and finally, the carbon stock of all trees was estimated. The quantitative parameters and the average of the above-ground biomass and carbon stock were compared. An independent t-test was used to compare quantitative parameters and carbon storage in the two sample plots of Garan and Dolah Naw. Results: The findings of the research showed that the amount of biomass on the ground in Dolah Naw and Garan sample plots was 45.3 and 41.4 tons per hectare, respectively. In the Dolah Naw sample plot, two species, Quercus brantii and Q. infectoria, with a total of 24.68 tons per hectare, accounted for 54.5% of the biomass of the tree layer. The carbon stock of the tree layer in Dolah Naw and Garan samples was calculated as 22.4 and 20.3 tons per hectare, respectively, and the results of the independent t-test showed a significant difference between the quantitative characteristics of diameter at breast height, total height, tree crown area, biomass, and carbon storage in the two sample plots. The contribution of the Q. infectoria species to carbon sequestration in Dolah Naw and Garan samples was 6.48 and 9.13 tons per hectare, respectively. On the other hand, the averages of quantitative characteristics, including tree height (3.7 meters), diameter at breast height (15.79 cm), and crown area (6.77 square meters), in the Dolah Naw sample plot were greater than those in the Garan sample plot. Conclusion: The general results showed that the carbon storage of Dolah Naw stands (wood biomass with slightly higher forest characteristics) was greater than that of Garan forest. To optimally manage these forests and increase carbon dioxide storage, it is essential to manage and control the factors of forest destruction (such as the development of agriculture under the forest canopy, intensive grazing, excess livestock capacity, fire management and control, coal mining, and other factors) and take action in degraded areas to promote reforestation and afforestation using native species (Quercus brantii, Quercus infectoria, Quercus libani, and Pistacia atlantica) in the destroyed stands [ABSTRACT FROM AUTHOR]

Published

2024

14. Predicting aboveground biomass yield for moso bamboo (Phyllostachys pubescens) plantations based on the diameter distribution model.

Author

Yen, Tian-Ming

Subjects

*BAMBOO, *PHYLLOSTACHYS, *ALLOMETRIC equations, *PLANTATIONS, *BIOMASS, *FOREST management

Abstract

Biomass accumulation is an important stand characteristic because it provides critical information for bamboo forest management. The purpose of this study was to predict aboveground biomass (AGB) for moso bamboo (Phyllostachys pubescens) plantations based on the diameter distribution model (DDM). The study was conducted on 24 stands, with intensive management (IM) and extensive management (EM), located in the lower mountain area of central Taiwan. Quantifying stand diameter distribution is a critical step in the process of the DDM. The Weibull function effectively quantified stand diameter distribution in this study. The AGB of each diameter at breast height (DBH) class was predicted based on a combination of the Weibull function and an allometric equation. The AGB of the whole stand was obtained from the summation of the numbers obtained from each DBH class and was predicted to be 87.53 ± 23.06 and 74.62 ± 5.76 Mg ha−1 for the IM and EM stands, respectively. To assess this model, the same data predicted by the allometric model were compared to the DDM. The results showed a difference of less than ± 1% in the predicted AGB between these 2 methods, regardless of stand type. Therefore, the DDM is recommended for use in predicting AGB for bamboo forests because it shows AGB yield at both the DBH class and stand levels. However, the DDM requires stand diameter distribution to be quantified. If stand diameter distribution is not quantified, the DDM will not be suitable for predicting AGB. It provided detailed information of AGB for moso bamboo plantations. [ABSTRACT FROM AUTHOR]

Published

2023

15. برآورد زی توده روی زمینی توده های جنگلی دست کاشت عرب داغ استان گلستان با استفاده از داده های ماهواره ای سنتینل ۲.

Author

حسان علی and جهانگیر محمدی

Abstract

Background and Objectives: Reforested stands are recognized as crucial contributors to forest carbon storage and play a significant role in mitigating the destruction of natural areas. Aboveground biomass (AGB) serves as a vital component in sustainable forest management, contributing to the reduction of global warming, and provides valuable information. Allometric equations represent a valuable tool for quantifying AGB in forests. In recent years, non-parametric remote sensing techniques, such as the Random Forest algorithm, have gained widespread popularity for estimating forest tree biomass. This study aimed to evaluate the capability of Sentinel 2 data, coupled with the Random Forest algorithm, to estimate above-ground biomass in Arabdagh reforested stands located in Golestān province. Materials and Methods: In this study, a total of 180 circular sample plots, each with an area of 400 m 2, were measured using the cluster sampling method. Measurements of the diameter at breast height (DBH) and tree height (H) were recorded. Additionally, the precise coordinates of the sample plot centers were captured using DGPS. Subsequently, the aboveground biomass of trees was calculated using the developed allometric equations. For this study, pre-processed radiometric and geometrical data from Sentinel 2 were utilized, enabling the creation of various vegetation indices. The random forest algorithm was employed to explore the relationship between biomass characteristics (dependent variable) and the spectral values of vegetation indices (independent variables). The modeling process involved using 75% of the sample plots (135 sample plots) for training the random forest algorithm, while the remaining 25% (45 sample plots) were reserved for validating the estimates. Results: The findings showed that the NDVI and GNDVI indices exhibited the strongest correlation in estimating above-ground biomass. By employing the random forest algorithm with 310 trees and 5 predictors, the percentage root mean square error was determined to be 35.83%, while the coefficient of determination was 0.51, indicating the algorithm's capability to estimate the above-ground biomass of Arabdagh reforested stands. Furthermore, the results indicated that the random forest algorithm, utilizing Sentinel 2 data, provided higher estimates for the above-ground biomass of trees compared to the actual values. However, at a 95% probability level, there was no significant difference between the estimated and real above-ground biomass values (p-value > 0.05). Conclusion: The findings demonstrated that Sentinel 2 data successfully estimated the above-ground biomass of Arabdagh reforested stands with satisfactory accuracy. Based on the results presented, it can be concluded that the information derived from the main bands and spectral indices played a crucial role in the estimation of above-ground biomass. [ABSTRACT FROM AUTHOR]

Published

2023

16. Determining Allometry and Carbon Sequestration Potential of Breadfruit (Artocarpus altilis) as a Climate-Smart Staple in Hawai'i.

Author

Livingston, Chad and Lincoln, Noa Kekuewa

Abstract

Breadfruit (Artocarpus altilis) is an underutilized Pacific tree crop that has been highlighted as having substantial potential to contribute to global food security and climate-smart agriculture, including adaptation to and mitigation of climate change. To explore the carbon sequestration potential of breadfruit production, we characterize tree volume, wood density, carbon density, foliar biomass, and growth rates of breadfruit in Hawai'i. Strong relationships to trunk or branch diameter were displayed for wood density (r2 0.81), carbon density (r2 0.87), and foliar biomass (r2 0.91), which were combined to generate an allometric prediction of tree volume (r2 0.98) based on tree diameter at breast height. Growth rates, as measured by diameter at breast height, were well predicted over time when trees were classified by habitat suitability. We extrapolate potential breadfruit growth and carbon sequestration in above-ground biomass to the landscape scale over time. This study shows that breadfruit is on the low end of broadleaf tropical trees in moist and wet environments, but in an orchard can be expected to sequester ~69.1 tons of carbon per hectare in its above-ground biomass over a 20-year period. [ABSTRACT FROM AUTHOR]

Published

2023

17. An Automated Pipeline for Extracting Forest Structural Parameters by Integrating UAV and Ground-Based LiDAR Point Clouds.

Author

Xu, Dali, Chen, Guangsheng, Zhang, Shuming, and Jing, Weipeng

Subjects

POINT cloud, AIRBORNE lasers, STANDARD deviations, FOREST surveys, OAK, SCOTS pine, LIDAR, RADAR in aeronautics, DRONE aircraft

Abstract

In recent times, airborne and terrestrial laser scanning have been utilized to collect point cloud data for forest resource surveys, aiding in the estimation of tree and stand attributes over hectare-scale plots. In this study, an automated approach was devised to estimate the diameter at breast height (DBH) and tree height across the entire sample area, utilizing information acquired from terrestrial laser scanning (TLS) and airborne laser scanning (ULS). Centered around a meticulously managed artificial forest in Northern China, where Mongolian oak and Chinese Scots pine are the predominant species, both TLS and ULS operations were conducted concurrently on each plot. Subsequent to data collection, a detailed processing of the point cloud data was carried out, introducing an innovative algorithm to facilitate the matching of individual tree point clouds from ULS and TLS sources. To enhance the accuracy of DBH estimation, a weighted regression correction equation based on TLS data was introduced. The estimations obtained for the Chinese Scots pine plots showed a correlation of R2 = 0.789 and a root mean square error (RMSE) of 3.2 cm, while for the Mongolian oak plots, an improved correlation of R2 = 0.761 and a RMSE of 3.1 cm was observed between predicted and measured values. This research significantly augments the potential for non-destructive estimations of tree structural parameters on a hectare scale by integrating TLS and ULS technologies. The advancements hold paramount importance in the domain of large-scale forest surveys, particularly in the calibration and validation of aboveground biomass (AGB) estimations. [ABSTRACT FROM AUTHOR]

Published

2023

18. Application of Allometric Equations to Estimate Carbon Stock and Above-Ground Biomass in Narpuh Wildlife Sanctuary, Meghalaya

Author

Syiemiong, Pynshailang, Chaturvedi, Shiva Shankar, Uppaluri, Ramagopal V. S., editor, and Rangan, Latha, editor

Published

2023

19. Current Status and Future Prospects

Author

Pandi, Vivek and Pandi, Vivek

Published

2023

20. Allometric equations and carbon stocks assessment for Bambusa vulgaris Schrad. ex J.C.Wendl. in the bimodal rainfall forest of Cameroon

Author

Rene Kaam, Martin Tchamba, Barnabas Neba Nfornkah, and Cédric Chimi Djomo

Subjects

Bambusa vulgaris, Allometric equation, carbon stock, Climate change mitigation, Agroecological zone 5, Cameroon, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Over the last two decades, bamboo has received increasing attention owing to its socio-economic and environmental importance. Environmentally, bamboo plays an important role in carbon sequestration, thus enhancing climate change mitigation. In Cameroon, knowledge about the importance of Bambusa vulgaris Schrad. ex J.C.Wendl. to climate change mitigation is deficient, despite the fact that it is the most abundant bamboo species in Cameroon's Bimodal rainforest agroecological zone (Agroecological zone 5 - AEZ5). This study was initiated to develop allometric equations and estimate carbon stocks of B. vulgaris in Cameroon's AEZ5. The destructive, clump-based method was used for bamboo biomass data collection on 40 clumps and 86 culms. Regression analyses were performed to obtain allometric models for B. vulgaris biomass prediction which were used for B. vulgaris carbon stocks estimation in AEZ5. The best allometric model for culms was obtained when all predictive variables including age, diameter and height were considered into the model. For clump, the best model was obtained when the number of culms per clump, girth and average diameter were considered in the model. Model quality adjustment was better for clump aboveground biomass (AGB) compared to those of culm AGB. The model of B. vulgaris of the evergreen rainfall forest was validated with a bias of 45.5 %. Bamboo aboveground biomass proportions were 77 %, 15 % and 8 %, respectively for culms, branches and leaves. The mean density and carbon stocks of B. vulgaris were estimated at 2,0679 culms.ha−1, 257 clumps.ha−1, and 61.65 tC ha−1. B. vulgaris has a veritable carbon sequestration capacity which policymakers should consider in climate change mitigation strategies like those linked to payments for ecosystem services, voluntary carbon stocks market, Bonn Challenge, AFR100 initiative, and the Paris agreement ratified by the government of Cameroon.

Published

2023

21. Carbon stock in biomass pool of fragmented mangrove habitats of Kochi, Southern India.

Author

Rani, Varghese, Nandan, Sivasankaran Bijoy, Jayachandran, Paravanparambil Rajakumar, Preethy, Chakkalakkal Mani, Sreelekshmi, Suseela, Joseph, Philomina, and Asha, Chalil Veedu

Subjects

MANGROVE plants, MANGROVE ecology, FRAGMENTED landscapes, MANGROVE forests, ALLOMETRIC equations, BIOMASS, CLIMATE change mitigation

Abstract

Even though, the blue carbon ecosystems are gaining keen research interest around the globe, the carbon stock of South-West coast of India was poorly reported, and this study is a pioneer attempt and will be an important document for filling the gaps in uncertainties in global carbon stock assessment and also will increase knowledge on biomass variability among mangrove species and mangrove habitats. The study also highlighted the vital role of biomass carbon pool for long-term soil carbon burial. We estimated the above and below-ground biomass carbon stock of 13 mangrove species using two common allometric equations and species-specific equations and reported a very high mean total living biomass carbon stock of Kochi mangroves at 237.19 ± 113.82 Mg C ha−1, 295.78 ± 143.14 Mg C ha−1, and 272.42 ± 132.78 Mg C ha−1 according to Chave's, Komiyama equation and species-specific equation respectively corresponding to carbon dioxide equivalent (CO2e) of approximately 4,37,774.51 Mg CO2e. The biomass stock was significantly differed between the stations (p = 0.000) and also within species (p = 0.020). Among the mangrove species, Avicennia officinalis contributed highest and Bruguiera sexangula contributed least. Variation was observed for biomass stock of mangroves with large trunk diameter while comparing different allometric equations and therefore projected the need for the development of site- and species-specific equations for solving the uncertainty in global mangrove carbon stock. The study observed that dominant mangrove vegetation type, salinity and also the geomorphology of mangrove habitat had strong influence on variability in biomass stock within a small regional area. The study also suggests that understanding the structure and biomass carbon storage of each regional mangrove habitats can be wisely used in mangrove restoration and conservation programmes and in turn for nature-based solutions for climate change mitigation efforts. [ABSTRACT FROM AUTHOR]

Published

2023

22. Effect of habitat specific wood specific gravity on biomass and carbon stock of trees in tropical dry deciduous forest of central India.

Author

Pati, Pranab Kumar, Kaushik, Priya, Khan, M. L., and Khare, P. K.

Subjects

TROPICAL dry forests, SPECIFIC gravity, WOOD, BIOMASS, BIOMASS conversion, BIOMASS estimation, DECIDUOUS forests, FOREST biomass

Abstract

Wood specific gravity (WSG) is one of the important variables in biomass and carbon stock estimation through non-destructive method. Present study was conducted in a tropical dry deciduous forest in central India. A non-destructive method was adopted for biomass estimation. Habitat specific WSG of all the species present in the study area was determined using maximum moisture content method. Reported WSG values of the same species were procured from global wood density database. The present paper deals with the comparison of biomass and carbon stock of mature individuals estimated using habitat specific WSG and WSG procured from the database for the same species. Further, comparison was made among biomass and carbon values estimated using habitat specific WSG and without WSG for juvenile individuals. Procured WSG from database for different tree species were found to be higher in most cases than the WSG determined in the habitat. Results envisage that biomass estimates using non habitat specific WSG (database) over-estimate the biomass and carbon stock. Total biomass (including both mature and juvenile individuals) per hectare was 24.2% higher with reported WSG for mature individuals and without WSG for juvenile individuals than using habitat specific WSG for both mature and juvenile individuals. It is calculated that using WSG from data base may result in increased AGB by 1.5 × 108 Mg and 6.6 × 108 Mg at state and national level respectively. We suggest the consideration of habitat specific WSG for biomass and carbon estimation in non-destructive method for both mature and juvenile individuals. [ABSTRACT FROM AUTHOR]

Published

2023

23. Predictive biomass equations of chir pine silvipasture ecosystem of Himalayas, India

Author

Bhutia, P. L., Gupta, B., Yadav, R. P., Islam, Sadikul, Pal, Sharmistha, Khola, O. P. S., and Bhutia, K. G.

Published

2022

24. Estimation of Mangrove Aboveground Biomass in China Using Forest Canopy Height through an Allometric Equation

Author

Wen Xin, Liu Kai, Cao Jingjing, Zhu Yuanhui, and Wang Ziyu

Subjects

mangrove, remote sensing, aboveground biomass, forest canopy height, allometric equation, china, Geography (General), G1-922

Abstract

Mangroves, which have extremely high primary productivity, are efficient coastal blue carbon ecosystems. Aboveground biomass (AGB) is an important component of vegetation carbon pools. Thus, accurate estimation of mangrove AGB is critical for studying carbon cycle and climate change. While the practical significance and application of information obtained on mangrove AGB in China is apparent, studies of this nature in China at a national scale have rarely been reported. Remote sensing technology is convenient, efficient, has a wide observational range, and can be used for large-scale ecosystem monitoring. Canopy height is a structural parameter that is positively correlated with the AGB of vegetation. The Global Ecosystem Dynamics Investigation (GEDI) spaceborne Light Detection and Ranging (LiDAR) satellite, launched in recent years, is able to obtain vegetation canopy height. This study employed forest canopy height derived from GEDI satellite-based LiDAR and an allometric equation based on the allometric theory to estimate mangrove AGB in China in 2019, and the quantitative and spatial distribution of mangrove biomass and their main influencing factors were analyzed. The results showed that the total and mean AGB of mangroves in China in 2019 were about 1,974,827 t and 73.0 t/hm2, respectively. Guangdong-Hong Kong-Macao area showed the largest total mangrove AGB, reaching 843,836 t. The mean values of AGB in each province (region) with mangrove ecosystems nationwide ranged from 53.3 to 92.1 t/hm2, of which the largest was found in Hainan Province, reaching 92.1 t/hm2. In Hainan, Taiwan, and Fujian provinces, mean mangrove AGB was higher than the national mean. Considering nature reserves, the mean AGBs of mangroves in Neilingdingdao-Futian and Mai Po mangrove nature reserves in Shenzhen Bay in the Guangdong-Hong Kong-Macao area and Dongzhaigang mangrove nature reserve in Hainan province were relatively high, with values greater than 110 t/hm2. The accumulation and distribution of mangrove AGB in China are affected by latitude and anthropogenic factors. This study provides a comprehensive analysis of mangrove AGB in China based on remote sensing and an allometric equation and can provide a database and technical reference for estimating carbon storage in mangrove ecosystems. It will also contribute to the implementation of ecological restoration and protection measures for coastal mangroves, as well as carbon emission control in China.

Published

2023

25. Biomass Estimation and Uncertainty Quantification From Tree Height

Author

Qian Song, Conrad M. Albrecht, Zhitong Xiong, and Xiao Xiang Zhu

Subjects

Above-ground biomass (AGB) estimation, allometric equation, Gaussian process regression, model uncertainty, tree height, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

We propose a tree-level biomass estimation model approximating allometric equations by LiDAR data. Since tree crown diameter estimation is challenging from spaceborne LiDAR measurements, we develop a model to correlate tree height with biomass on the individual-tree levels employing a Gaussian process regressor. In order to validate the proposed model, a set of 8342 samples on tree height, trunk diameter, and biomass has been assembled. It covers seven biomes globally present. We reference our model to four other models based on both, the Jucker data and our own dataset. Although our approach deviates from standard biomass–height–diameter models, we demonstrate the Gaussian process regression model as a viable alternative. In addition, we decompose the uncertainty of tree biomass estimates into the model- and fitting-based contributions. We verify the Gaussian process regressor has the capacity to reduce the fitting uncertainty down to below 5%. Exploiting airborne LiDAR measurements and a field inventory survey on the ground, a stand-level (or plot-level) study confirms a low relative error of below 1% for our model. The data used in this study are available at https://github.com/zhu-xlab/BiomassUQ.

Published

2023

26. BIOMASS, STEM VOLUME, AND CARBON SEQUESTRATION BASED ON ALLOMETRIC EQUATIONS FOR POPULUS DELTOIDES W. BARTRAM EX MARSHALL. PLANTATIONS (A STUDY OF GUILAN, IRAN).

Author

Abedi, Tooba and Abedi, Roya

Subjects

COTTONWOOD, CARBON sequestration, BIOMASS energy, SUSTAINABLE development, ALLOMETRIC equations

Abstract

Populus deltoides W. Bartram ex Marshall is one of the most important economically (wood production), environmentally (biomass production and carbon sequestration), and fast-growing species in plantations. Therefore, this study aimed to investigate biomass, volume, and carbon sequestration models according to age by using the stem analysis method in poplar plantations in five regions of Guilan province. Measurement features included DBH and the total height of all trees in two plots with one hectare area in each region. 30 trees were randomly selected in different diameter classes and cut down and the discs were obtained in order to stem analysis. The annual rings of discs were counted, ages at different tree heights were obtained, and the diameter of the annual rings was measured to determine the annual diameter and volume increments. Carbon measurement, volume measurement of wood, and volume conversion to weight ratio were calculated. Finally, regression analysis was performed by the relationship between volume and biomass growth by age based on the highest coefficient of determination and minimum standard error. The results showed that the nonlinear models were able to show the highest coefficient of determination (R2 = 0.93-0.99) and the least standard error of the relationship between these characteristics. These models can be applied for the annual growth assessment of poplar plantations in carbon sequestration and optimal management for achieving sustainable development of the various plantations. [ABSTRACT FROM AUTHOR]

Published

2023

27. Aboveground Biomass Productivity and Nutrient Use Dynamics of Clumping Tropical Bamboos in Northern Thailand.

Author

Chantarat, Pramena, Poolsiri, Roongreang, Wannalangka, Ittipong, Kaitpraneet, San, Puangchit, Ladawan, and Jenke, Michael

Subjects

BAMBOO, BIOMASS, RURAL development, INTRODUCED species, ALLOMETRIC equations, STATISTICAL models

Abstract

Bamboo has great potential in restoring degraded lands while providing multiple environmental benefits and harvestable products at regular intervals due to its unique characteristics of rapid growth. However, a comprehensive and species-specific knowledge of biomass productivity, nutrient dynamics, and potential harvest-induced nutrient losses is lacking. This study compared the biomass and nutrient dynamics of four bamboo species Bambusa oldhamii Munro, Dendrocalamus latiflorus Munro, Bambusa tulda Roxburgh, and Dendrocalamus brandisii (Munro) Kurz in Northern Thailand. Field measurements, laboratory analyses, and statistical modeling were used to estimate their aboveground biomass (AGB), nutrient use efficiency (NUE), and nutrient stocks. Culm diameter at breast height (DBH) and age were identified as the most reliable predictors of AGB. The study revealed that D. brandisii had superior productivity and NUE compared to the other species, particularly the introduced non-native bamboo species. These findings emphasize the need for species-specific strategies that consider both biomass productivity and nutrient dynamics. Furthermore, D. brandisii can be suggested as a native candidate for bamboo plantations in Northern Thailand and similar environments, given its high productivity and efficient nutrient use, underpinning its potential contribution to environmental rehabilitation and rural livelihoods. However, more research is required to minimize nutrient losses and maintain a productive age structure. [ABSTRACT FROM AUTHOR]

Published

2023

28. Aboveground Carbon Stock in a Bottomland Hardwood Forest in the Southeastern United States.

Author

Streeter, Jared R., Bhattacharjee, Joydeep, and Kandel, Bibek

Subjects

HARDWOOD forests, COARSE woody debris, WILDLIFE management areas, FOREST litter, ECOSYSTEM management, TEMPERATE forests, SHRUBS, TUNDRAS

Abstract

Bottomland Hardwood Forests (BHFs) are commonly acknowledged worldwide for their vast carbon sequestration potential and carbon storage capacity. However, the paucity of forest carbon stock data from BHFs along the Lower Mississippi Alluvial Valley (LMAV) in Northeast Louisiana is an existing knowledge gap in understanding the carbon sequestration and storage dynamics across the region. This study was carried out in the Russell Sage Wildlife Management Area (RSWMA) in Northeast Louisiana using a protocol modified from the Terrestrial Carbon Observations Protocol for Vegetation Sampling. Comprehensive analyses of carbon stocks in trees, woody shrubs and seedlings, herbaceous vegetation, downed woody debris, leaf litter, and soil were carried out to quantify the carbon stored in each ecosystem component. Trees accounted for a carbon stock of 132.4 Mg C ha−1, approximately 99% of the total stock for the area. Woody shrubs and seedlings and leaf litter stored 0.4% (0.62 Mg C ha−1) and 0.3% (0.4 Mg C ha−1), respectively. Considering the sparse understory in a BHF, the carbon stored per hectare is comparable to other temperate forests in the conterminous United States. These findings highlight the importance of the BHF ecosystem in carbon storage and their overall role in regional and global ecosystem management in light of climate change. [ABSTRACT FROM AUTHOR]

Published

2023

29. Aboveground Biomass and Carbon Storage in Mangrove Forests in Southeastern Mexico

Author

Carlos Roberto Ávila-Acosta, Marivel Domínguez-Domínguez, César Jesús Vázquez-Navarrete, Rocío Guadalupe Acosta-Pech, and Pablo Martínez-Zurimendi

Subjects

allometric equation, carbon dioxide, forest protocol for Mexico, ecosystem services, tree density, Science

Abstract

The aboveground contributions of mangroves to global carbon sequestration reinforce the need to estimate biomass in these systems. The objective was to determine the aboveground biomass storage and quantify the carbon and CO2e content in Rhizophora mangle, Avicennia germinans, and Laguncularia racemosa present in southeastern Mexico. Based on the Forest Protocol for Mexico Version 2.0 methodology, published by Climate Action Reserve, 130 circular plots were randomly selected and established in an area of 930 ha of mangrove vegetation, and the aboveground biomass and stored carbon were determined. The mangrove had a density of 3515 ± 428.5 individuals per hectare. The aboveground biomass of the three species was 120.5 Mg ha−1. The biomass of L. racemosa was 99.5 Mg ha−1, which represents 82.6% of the total biomass. The biomass of R. mangle was 20.33 Mg ha−1, and that of A. germinans was 0.32 Mg ha−1. The total carbon retained in the trees was 60.25 Mg C ha−1 and 221.1 Mg CO2e ha−1. Laguncularia racemosa generated the highest contributions of CO2e. The area of mangroves accumulated 112,065 Mg of aboveground biomass. The carbon contained in this biomass corresponds to 205,623 Mg CO2e. This mangrove contributes to mitigating the effects of climate change globally through the reduction in greenhouse gases.

Published

2024

30. Rubber Trees and Biomass Estimation Using Remote Sensing Technology

Author

Ismail, Mohd Hasmadi, Shidiq, Iqbal Putut Ash, Ramli, Mohammad Firuz, Kamarudin, Norizah, Zaki, Pakhriazad Hassan, Rokhmatuloh, and Suratman, Mohd Nazip, editor

Published

2022

31. Traits plasticity of Sodom Apple (Calotropis procera) along the environmental gradient in the semi-arid environment.

Author

Siraj, Khan, Nasrullah, Okla, Mohammad, Al-amri, Saud, Al-Qahtani, Wahidah, Abdel-Maksoud, Mostafa, and AbdElgawad, Hamada

Abstract

Biomass and morphological characteristics of plant species provide essential insight into how well a species adapts to its environment. The study aims to evaluate how environmental variables (viz., altitude, slope, aspect degree, and soil properties) influence the morphological traits and biomass variability of Calotropis procera (Aiton) W.T. Aiton in a semi-arid environment. C. procera sample locations were divided into 39 permanent sites (5×5 = 25 m2). Slope, aspect degree, slope aspect, altitude, and soil variables (soil moisture, organic matter, nitrogen (N %), and phosphorus (P) gradients were used to quantify morphological parameters (height, diameters, canopy area, volume, and leave/ branch biomass) and aboveground biomass. Environmental variables, i.e., altitude and aspect degree, were the most important factor influencing the biomass variation and affecting soil moisture content; however, they did not directly affect the total biomass of the species. The results also reveal significant plasticity in morphological traits exists concerning elevation and aspect degree at (p< 0.05). Plant volume was a better indicator of species’ total biomass revealed from the regression model showing significant at p< 0.05. The study also reveals that soil properties such as soil moisture and Phosphorus have an important role in enhancing the productivity of the studied plant species. The results concluded that plants functional traits and biomass shows significant variation across the altitude and these parameters could be consider in the conservation of this native species. [ABSTRACT FROM AUTHOR]

Published

2023

32. Estimating and mapping woodland biomass and carbon using Landsat 8 vegetation index: A case study in Dirmaga Watershed, Ethiopia

Author

M. Adamsew Marelign and D. Temesgen Mekonen

Subjects

carbon stock, woodland, allometric equation, ndvi, regression, correlation, Technology (General), T1-995, Science

Abstract

This study was conducted to estimate the above and below ground carbon storage in the Woodlands of Dirmaga Watershed, North Western Ethiopia. The field data were collected through systematic random sampling techniques of 40 sample plots. The above-ground biomass and below-ground biomass of the study area was collected from 20 m by 20 m area of the main plot. The biomass and carbon stock of the woodland was estimated using site-specific allometric models and Landsat 8 NDVI and analyzed by ArcGIS. The result showed that the mean carbon stock of above-ground carbon and below-ground carbon were accounted for about 291.47 t/ha and 24.81 t/ha, respectively. The relationship between AGC and NDVI was strong with correlation coefficient of 0.86 and R2 value of 0.745. Tree species of Anogeissus leiocarrpa, Adansonia digitata and Diospyros mespiliformis sequestered the largest portion of the carbon stockwhile, Ficus sycomorus L., Rhus glutinosa and Securinega virosa were the least contributor of carbon stock. The woodland has a great potential for carbon sequestration and biodiversity conservation and the concerned body should conserve and manage the resource properly.

Published

2022

33. Tree-level biomass estimation using unmanned aerial vehicle (UAV) imagery and allometric equation.

Author

Jia, Xingyu, Wang, Cuicui, Da, Yizhuo, Tian, Xianchao, and Ge, Wenyan

Subjects

*ALLOMETRIC equations, *FOREST biomass, *BIOMASS estimation, *VEGETATION management, *FOREST management

Abstract

Estimating forest biomass is imperative for comprehensively understanding the function of forest in regulating climate, providing theoretical support for vegetation management. Constructing allometric equations rationally is essential for accurate tree-level biomass estimation without destructive sampling, and optimizing the sample size for fitting allometric equations ensures a desirable balance between accuracy and cost. In this study, the optimal sample size and the best allometric equation for biomass estimation were discussed using unmanned aerial vehicles (UAVs) imagery and field measurements of tree height (H), diameter at breast height (DBH) and crown radius (R c) in an artificial Pinus tabuliformis forest. Results demonstrated that the optimal sample size for accurately estimating tree-level biomass with minimal manpower and time costs was 130. Besides, the estimating precision of allometric equations can be enhanced by increasing the number of suitable variables, altering the variables combination, and modifying functional forms. The proposed allometric equation based on H and R c in this study outperformed common equations in estimating Pinus tabuliformis forest biomass. This equation achieved a coefficient of determination (R2) of 0.72 and a root-mean-square error (RMSE) of 8.56 kg for biomass estimation, owing to its utilization of multivariate analysis and exclusive application of logarithmic transformation to the dependent variable. Moreover, the study revealed that the total biomass of 1490 planted Pinus tabuliformis trees in this study area was 67.3 t. This research offers valuable insights into accurately estimating tree-level forest biomass, which is essential for addressing challenging ecological issues and formulating rational forest management policies. • A new allometric equation based on H and R c was proposed to evaluate biomass. • 130 was the optimal sample size for biomass estimation by allometric equation. • Tree-level biomass of a Pinus tabuliformis forest was estimated using UAV data. [ABSTRACT FROM AUTHOR]

Published

2024

34. The Study of T The Study of Tree Biomass Calculation b ee Biomass Calculation by Comparing P y Comparing Partial Harvest Method with the Allometric Equations Method

Author

Kanlayarat Jantawong and Titinan Pothong

Subjects

allometric equation, forestry, aboveground biomass, partial harvest, ecology., Environmental sciences, GE1-350, Ecology, QH540-549.5

Abstract

This study aimed to investigate the effective of partial harvest method used for tree biomass estimation. Such method was analyzed for the correlation in compare with invented allometric equations. The advantages and disadvantages of those methods were discussed. The significantly difference between estimation methods were analyzed. As a result, tree biomass calculated by the Brown’s allometric equation produced highest results, followed by the partial harvest method, Tsutsumi’s, Chave’s and Pothong’s equations respectively. The selected allometric equations showed the positive correlation with partial harvest method. The highest positive correlation was found between the partial harvest method and both equation of Chave and Pothong (R = 0.99, p ≤ 0.05 and R = 0.99, p ≤ 0.05, respectively), followed by Tsutsumi’s and Brown’s equations (R = 0.96, p ≤ 0.05 and 0.88, p ≤ 0.05 respectively). Wood density significantly varied among tree species and that affected the effective of biomass estimation. The allometric equations of Pothong and Chave can be applied for tree biomass estimation in secondary forest or ‘mixed-species’ plantation. The use of site-specific allometric equation should be validated with the results from a partial harvest method to avoid the possible errors of model limitation. Moreover, the partial harvest method can be used for forest monitoring in the national park or protected area to obtain the accurate and reliable results.

Published

2022

35. Allometric models for aboveground biomass estimation of small trees and shrubs in African savanna ecosystems

Author

Antonia Nyamukuru, Cory Whitney, John R.S. Tabuti, Josephine Esaete, and Matthew Low

Subjects

Above-ground biomass, Allometric equation, Destructive sampling, Shrubs, Small trees, Biometric variables, Forestry, SD1-669.5, Plant ecology, QK900-989

Abstract

Quantification of plant biomass and carbon in ecosystems is critical for establishing climate change mitigation potential. For large trees in various ecosystems, allometric models for estimating biomass have been developed but few biomass equations exist for small trees and shrubby vegetation. Allometric above-ground biomass (AGB) models are needed for small trees and shrubs in order to improve the quantification of biomass, particularly for savanna ecosystems, where small trees and shrubs comprise a significant portion of the biomass. In this study we have developed species-specific and multi-species allometric models for biomass estimation of small tree species and shrubs in the savanna ecosystem of Lake Mburo National Park in South Western Uganda. For our models we selected 27 small tree species (N = 403 individuals) and 12 shrub species (N = 177) common in savanna ecosystems for destructive sampling. We developed species-specific and multi-species allometric AGB models to provide estimates of AGB using specific biometric variables recorded for the small trees (i.e. species, DBH, height and crown area), and shrubs (species, height and crown area). We found that crown area was the best single predictor of species-specific AGB for small trees and for species-specific and multi-species models for shrubs. Species-specific models had the best predictive capacity of AGB compared to multi-species biomass models for small trees and shrubs. Multiple-variable models had the best predictive capacity of AGB in both species-specific and multi-species modeling compared to single-variable models. Based on these findings we conclude that the evaluation of carbon stocks of tropical savanna ecosystems should use multi-variable species-specific models for AGB estimation at the individual level, and multi-species models for AGB at the ecosystem level.

Published

2023

36. Dynamics of forest net primary productivity based on tree ring reconstruction in the Tianshan Mountains

Author

Ting Wang, Anming Bao, Wenqiang Xu, Guoxiong Zheng, Vincent Nzabarinda, Tao Yu, Xiaoran Huang, Gang Long, and Sulei Naibi

Subjects

Forest biomass, Allometric equation, Tree-ring chronology, MODIS NPP, Solar-induced chlorophyll fluorescence (SIF), Central Asia, Ecology, QH540-549.5

Abstract

The lack of long-term high-resolution data makes it difficult to determine historical and future trends in net primary productivity (NPP). This study used tree rings as a proxy to investigate the dynamics of NPP in Tianshan forests where coniferous forests are the major species and the other species are deficient. All trees and some tree cores from five sample plots in different geographic locations in the western Tianshan Mountains were selected to reconstruct forest NPP data from 1950 to 2020. Multiple historical events that resulted in large-scale terrestrial carbon fluxes were identified and the existence of 28a and 17a time-scale cycles of historical forest NPP was observed. We discovered that the reconstructed forest NPP in the western Tianshan Mountains did not significantly correlate with satellite-based products (e.g., MODIS NPP, solar-induced chlorophyll fluorescence data). This result was attributed to the lag of forest growth for climate, the accuracy of the satellite-based products and statistical errors due to the short overlap time. We analysed the uncertainties in reconstructing historical forest NPP using tree ring widths and proposed corresponding solutions. We concluded that the reconstructed data remain the ideal proxy for regions lacking long-term empirical data and exhibit a high degree of confidence for expressing trends in forest productivity change over long time series.

Published

2023

37. 基于森林冠层高度和异速生长方程的中国红树林地上生物量估算.

Author

闻馨, 刘凯, 曹晶晶, 朱远辉, and 王子予

Abstract

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Published

2023

38. Developing allometric equations to estimate forest biomass for tree species categories based on phylogenetic relationships.

Author

Mingxia Yang, Xiaolu Zhou, Changhui Peng, Tong Li, Kexin Chen, Zelin Liu, Peng Li, Cicheng Zhang, Jiayi Tang, and Ziying Zou

Subjects

FOREST biomass, ALLOMETRIC equations, PLANT phylogeny, CARBON sequestration in forests, FOREST surveys

Abstract

The development of allometric biomass models is important process in biomass estimation because the reliability of forest biomass and carbon estimations largely depends on the accuracy and precision of such models. National Forest Inventories (NFI) are detailed assessments of forest resources at national and regional levels that provide valuable data for forest biomass estimation. However, the lack of biomass allometric equations for each tree species in the NFI currently hampers the estimation of national-scale forest biomass. The main objective of this study was to develop allometric biomass regression equations for each tree species in the NFI of China based on limited biomass observations. These equations optimally grouped NFI and biomass observation species according to their phylogenetic relationships. Significant phylogenetic signals demonstrated phylogenetic conservation of the crown-to-stem biomass ratio. Based on phylogenetic relationships, we grouped and matched NFI and biomass observation species into 22 categories. Allometric biomass regression models were developed for each of these 22 species categories, and the models performed successfully (R² = 0.97, root mean square error (RMSE) = 12.9 t.ha-1, relative RMSE = 11.5%). Furthermore, we found that phylogeny-based models performed more effectively than wood density-based models. The results suggest that grouping species based on their phylogenetic relationships is a reliable approach for the development and selection of accurate allometric equations. [ABSTRACT FROM AUTHOR]

Published

2023

39. Allometric Equation for Aerial Carbon Estimation (AGC) of Rhizophora racemosa and Avicennia germinans Mangroves of Olende and Ozouri in the Ogooué Delta in Gabon.

Author

Aken, Igor Akendengue, Okanga-Guay, Marjolaine, Abaker, Madi, Dumont, Estelle, Boubala, Silas Davy Mbadinga, Ngombi-Pemba, Lauriss, and Nieguitsila, Adelaïde

Subjects

RHIZOPHORA, AVICENNIA, CARBON sequestration in forests, MANGROVE forests

Abstract

The global carbon is determined by forests at 45%. Mangroves sequester more carbon per area unit than the dry land forest. The carbon sequestration capacities of mangroves in the Ogooue Delta are still unknown. Thus, this study aims to set up a carbon estimation equation for the species Rhizophora racemosa and Avicennia germinans of the Ogooué Delta mangroves in Gabon. Data was collected in 25 m * 25 m square plots in four sites. The dendrometry parameters collected were mainly diameter at breast height (DBH) with a forest meter and height from the laser rangefinder. The individual basal area and volume of each tree was determined using the Husch et al. (2003) method. This resulted in a fractal-shaped equation of the type: y=αxβ, i.e., AGC = 0.000112*DBH2.466 with a determination rate of 96%, a relative bias of 0.007 and an RMSE of 1.2. This model was developed with a dataset of 47 individuals and validated with 41 individuals, i.e., 53% versus 47%. This study also allowed us to understand that the DBH structure of Ozouri and Olendé mangroves is stable without external disturbance. [ABSTRACT FROM AUTHOR]

Published

2023

40. Life History of the Arctic Squid Gonatus fabricii (Cephalopoda: Oegopsida) Reconstructed by Analysis of Individual Ontogenetic Stable Isotopic Trajectories.

Author

Golikov, Alexey V., Ceia, Filipe R., Hoving, Hendrik J. T., Queirós, José P., Sabirov, Rushan M., Blicher, Martin E., Larionova, Anna M., Walkusz, Wojciech, Zakharov, Denis V., and Xavier, José C.

Subjects

*LIFE history theory, *CEPHALOPODA, *LIFE cycles (Biology), *ECOLOGICAL models, *STABLE isotope analysis, *SQUIDS, *CALANOIDA

Abstract

Simple Summary: Gonatus fabricii is the most abundant cephalopod in the Arctic and northern part of the North Atlantic, which are areas of rapid environmental change. It is very important as a predator of many species of fish and invertebrates and as a prey for larger fish, seabirds, and marine mammals. The life cycle of G. fabricii, in particular ontogenetic changes in diet and habitat, is little known. Ecological modelling is an important method to forecast ecosystems' dynamics in relation to a changing climate, and it is crucial to assess their present structure and functioning for a viable forecast. Here, the ontogenetic changes in the diet and habitat of large G. fabricii from West Greenland are studied using stable isotope analysis of carbon (δ13C) and nitrogen (δ15N) along trajectories in chitin beaks, which function as archival structures. Using this approach, four stages with clearly distinct ecologies were revealed in the species' life cycle. This novel ecological periodization is a crucial baseline tool in Arctic marine ecosystem studies and cephalopod biology, and should be used in models to correctly reflect the ecological roles of G. fabricii in marine ecosystems. Cephalopods are important in Arctic marine ecosystems as predators and prey, but knowledge of their life cycles is poor. Consequently, they are under-represented in the Arctic ecosystems assessment models. One important parameter is the change in ecological role (habitat and diet) associated with individual ontogenies. Here, the life history of Gonatus fabricii, the most abundant Arctic cephalopod, is reconstructed by the analysis of individual ontogenetic trajectories of stable isotopes (δ13C and δ15N) in archival hard body structures. This approach allows the prediction of the exact mantle length (ML) and mass when the species changes its ecological role. Our results show that the life history of G. fabricii is divided into four stages, each having a distinct ecology: (1) epipelagic squid (ML < 20 mm), preying mostly on copepods; (2) epi- and occasionally mesopelagic squid (ML 20–50 mm), preying on larger crustaceans, fish, and cephalopods; (3) meso- and bathypelagic squid (ML > 50 mm), preying mainly on fish and cephalopods; and (4) non-feeding bathypelagic gelatinous females (ML > 200 mm). Existing Arctic ecosystem models do not reflect the different ecological roles of G. fabricii correctly, and the novel data provided here are a necessary baseline for Arctic ecosystem modelling and forecasting. [ABSTRACT FROM AUTHOR]

Published

2022

41. Examining the Role of UAV Lidar Data in Improving Tree Volume Calculation Accuracy.

Author

Liao, Kuo, Li, Yunhe, Zou, Bingzhang, Li, Dengqiu, and Lu, Dengsheng

Subjects

*EUCALYPTUS, *DEAD trees, *OPTICAL radar, *LIDAR, *ALLOMETRIC equations, *TREE height, *FOREST surveys, *DRONE aircraft

Abstract

Traditional forest inventories are based on field surveys of established sample plots, which involve field measurements of individual trees within a sample plot and the selection of proper allometric equations for tree volume calculation. Thus, accurate field measurements and properly selected allometric equations are two crucial factors for providing high-quality tree volumes. One key problem is the difficulty in accurately acquiring tree height data, resulting in high uncertainty in tree volume calculation when the diameter at breast height (DBH) alone is used. This study examined the uncertainty of tree height measurements using different means and the impact of allometric models on tree volume estimation accuracy. Masson pine and eucalyptus plantations in Fujian Province, China, were selected as examples; their tree heights were measured three ways: using an 18-m telescopic pole, UAV Lidar (unmanned aerial vehicle, light detection and ranging) data, and direct measurement of felled trees, with the latest one as a reference. The DBH-based and DBH–height-based allometric equations corresponding to specific tree species were used for the calculations of tree volumes. The results show that (1) tree volumes calculated from the DBH-based models were lower than those from the DBH–height-based models. On average, tree volumes were underestimated by 0.018 m3 and 0.117 m3 for Masson pine and eucalyptus, respectively, while the relative root-mean-squared errors (RMSEr) were 24.04% and 33.90%, respectively, when using the DBH-based model; (2) the tree height extracted from UAV Lidar data was more accurate than that measured using a telescopic pole, because the pole measurement method generally underestimated the tree height, especially when the trees were taller than the length of the pole (18 m in our study); (3) the tree heights measured using different methods greatly impacted the accuracies of tree volumes calculated using the DBH–height model. The telescopic-pole-measured tree heights resulted in a relative error of 9.1–11.8% in tree volume calculations. This research implies that incorporation of UAV Lidar data with DBH field measurements can effectively improve tree volume estimation and could be a new direction for sample plot data collection in the future. [ABSTRACT FROM AUTHOR]

Published

2022

42. Assessment of the Mass and Surface Area of the Scots Pine (Pinus sylvestris L.) Needles.

Author

Sporek, Monika, Sporek, Kazimierz, Stebila, Ján, Kučerka, Martin, Kminiak, Richard, and Lubis, Muhammad Adly Rahandi

Subjects

SCOTS pine, SURFACE area, LEAF area index, CONIFEROUS forests, ALLOMETRIC equations, PINE needles

Abstract

The assessment of the surface area of all leaves from a tree crown is regarded as one of the key parameters in scaling ecophysiological processes, such as growth, carbon budget, and water management. The purpose of this study was to investigate the variation of the mass and surface area of Scots pine needles, obtained from trees growing in the same habitat conditions but at different stock densities, therefore occupying different biosocial positions. The mass of needles and the leaf area index (LAI) were determined for an even-aged 33-year-old Scots pine stand located at a fresh mixed coniferous forest site in southwest Poland (50°32′ N; 17°42′ E). The needles, collected from all the sample trees, were subjected to a biometric analysis to determine the total mass of needles from each tree, the mass of 1000 needle pairs, the number of needles per crown, and the needle length distribution. Based on the actual measurements, we derived allometric equations for finding the fresh mass (FMN) and the surface area of the needles (SN), using the diameter at breast height (DBH) as an independent variable. The relationships between the mass of the needles and the DBH were significant (p < 0.0001), and so were those between the surface area of the needles and the DBH (p < 0.001). The fresh mass of needles for the tree stands varied from 6458 kg·ha−1 to 11,102 kg·ha−1. The LAI was in the range of 3.2 to 5.4 m2·m−2. The mean value of the LAI for the Scots pine stand was 4 m2·m−2. Further studies are required and more algorithms need to be developed for the quantitative assessment of the LAI in Scots pine trees, using a larger number of sample trees with more varied biometric features. [ABSTRACT FROM AUTHOR]

Published

2022

43. Tree allometric equations for estimating biomass and volume of Ethiopian forests and establishing a database: Review

Author

Heiru Sebrala, Amsalu Abich, Mesele Negash, Zerihun Asrat, and Bohdan Lojka

Subjects

Allometric equation, Database, Model verification, Quality control, Eastern Africa, Carbon stock, Forestry, SD1-669.5, Plant ecology, QK900-989

Abstract

Biomass measurements are central to understanding and monitoring carbon stocks in the forests. They also assists in assessing the growing stock of a species and biomass energy. Efforts in allometric equation development have grown. This compiled information is an important tool for assessing biomass and associated carbon stocks, the growing stock of a species and biomass energy. Despite this, except for a few attempts, the compilation of available equations has received little attention, particularly in Ethiopia. The uncertainty involved in biomass estimation is also associated with the choice and errors of the equations. The aim of the present paper is thus to review and compile available biomass and volume allometric equations and to critically synthesise quality control procedures for the equations. A total of 767 equations for both volume and biomass were collected from 47 articles, theses and dissertations, representing 47 sites in Ethiopia. Of these, 49% of the equations were developed for the Dry Afromontane biome, 22% for the Acacia-Commiphora biome, 15% for the Combretum-Terminalia biome and 14% for the Moist Afromontane biome. Among the compiled equations, biomass equations comprised 86.7% while the remainder 13.3% were for volume. Although a wide range of natural variations resulted in diverse species in Ethiopia, the already available equations were constrained by the size of individual samples, tree diameter range, tree species and spatial coverage. Moreover, variability in equation presentation and the missing of some relevant statistical parameters or inconsistent statistical analysis were among the problems observed. A quality control procedure revealed that 45 allometric equations had verification problems and were inappropriate for application. Invalid numeric values that may over- or underestimated values were predicted in 42% of the equations. Moreover, seven equations predicted “unrealistic” values, which were low values (4 equations) or both negative and low estimates (3 equations) within their interval of calibration. Altogether, 174 equations (22.7%) were statistically credible equations. These missing information affected the use of the equations and led to the preference of the generalised equations to assess forest biomass stocks. This highlighted important research gaps. The compiled database will also be useful to minimise duplication of efforts and enable efficient utilisation of limited resources, particularly in developing countries such as those in Eastern Africa and beyond in the tropics.

Published

2022

44. Allometric equations for biomass and carbon stock estimation of small diameter woody species from tropical dry deciduous forests: Support to REDD+

Author

Pranab Kumar Pati, Priya Kaushik, M.L. Khan, and P.K. Khare

Subjects

Allometric equation, Aboveground biomass, Belowground biomass, Regression equation, Root to shoot ratio, Seedling, Forestry, SD1-669.5, Plant ecology, QK900-989

Abstract

In order to assess the contribution to the overall carbon stock and generate carbon credits under REDD+, it is essential to have an accurate estimation of biomass of different forest components. Forest cover in India is gradually increasing due to the active restoration of degraded land and plantation on waste and barren lands leading to an increase in the abundance of small diameter woody species. However, these were not included in biomass studies due to the non- availability of adequate allometric equations and low carbon stocks compared to mature individuals. We have harvested 589 individuals belonging to 23 woody species at the seedling and sapling stage from a tropical dry deciduous forest and developed species specific allometric equation and general allometric equation for aboveground biomass estimation. Further, the belowground biomass equation of 9 species were also developed using above ground biomass and root to shoot ratio as predictor variable. In the case of general equation, the combination of diameter with height and diameter, height and wood specific gravity exhibited highest adjusted R2 value. In case of species-specific allometric equations, combination of diameter with height predicts above ground biomass more precisely as compared to the diameter and wood specific gravity. Since the estimation of wood specific gravity requires destruction of lower diameter individuals, usage of diameter and height for biomass estimation would help protecting regeneration as both methods yield same results. All the equations developed in the present study for below ground biomass predicts biomass precisely. We suggest use of species specific allometric model developed with diameter and height for estimation of biomass. Further, general models consisting of height and diameter may be used for biomass estimation in case of non-availability of species specific equations without destroying the regeneration.

Published

2022

45. Efecto del espaciamiento en la estimación indirecta del índice de área foliar en plantaciones dendroenergéticas de Eucalipto.

Author

Carlos Valverde, Juan

Subjects

*LEAF area index, *DIGITAL photography, *ESTIMATION bias, *EUCALYPTUS, *EVALUATION methodology, *ALLOMETRIC equations

Abstract

The influence of spacing on the estimation of the leaf area index (LAI) in Eucalyptus tereticornis and Eucalyptus saligna plantations was evaluated. Three spacings per species were analyzed: 1.0 x 2.0 m, 1.0 x 1.0 m, and 1.0 x 0.5 m. Dasometric variables and the LAI were measured with two indirect methods (LICOR 2000 and digital hemispheric photography, DHP) and a direct method. The results showed no differences between species. On the other hand, spacing significantly influenced the diameter (less spacing, less diameter) and the LAI (less spacing, higher LAI), with variations from 2.11 to 3.96 m².m-2. An evaluation of the indirect methods showed that, by reducing the spacing, the bias in the estimation increased. FDH showed greater accuracy and tended to underestimate the LAI by 7%. In contrast, LICOR 2000 showed a high bias, with a tendency to overestimate the LAI by up to 30%. [ABSTRACT FROM AUTHOR]

Published

2022

46. Allometric Equations for the Biomass Estimation of Calophyllum inophyllum L. in Java, Indonesia.

Author

Basuki, Tyas Mutiara, Leksono, Budi, Baral, Himlal, Andini, Sarah, Wahyuni, Novi Sari, Artati, Yustina, Choi, Eunho, Shin, Seongmin, Kim, Raehyun, Yang, A-Ram, Samsudin, Yusuf B., and Windyarini, Eritrina

Subjects

FOREST restoration, BIOMASS estimation, ALLOMETRIC equations, CALOPHYLLUM inophyllum, FOREST microclimatology, FOREST biomass

Abstract

Reliable data on CO2 quantification is increasingly important to quantify the climate benefits of forest landscape restoration and international commitments, such as the Warsaw REDD+ Framework and Nationally Determined Contributions under the Paris Agreement. Calophyllum inophyllum L. (nyamplung as a local name or tamanu tree for the commercial name) is an increasingly popular tree species in forest landscape restoration and bioenergy production for a variety of reasons. In this paper, we present allometric equations for aboveground biomass (AGB), belowground biomass (BGB), and total above- and belowground biomass (TABGB) predictions of C. inophyllum L. Data collection was carried out twice (2017 and 2021) from 40 trees in Java, Indonesia. Allometric equations using the natural logarithm of diameter at breast height (lnDBH) and ln height (lnH) for biomass prediction qualified the model's fit with statistical significance at 95% of the confidence interval for AGB, BGB, and TABGB predictions. The results showed that the linear models using both lnDBH and lnH were well fit and accurate. However, the model with lnDBH is more precise than the model using lnH. Using lnDBH as a predictor, the R2 values were 0.923, 0.945, and 0.932, and MAPE were 24.7, 37.0, and 25.8 for AGB, BGB, and TABGB, respectively. Using lnH as a predictor, the R2 values were 0.887, 0.918, and 0.898 and MAPE were 37.4, 49.0, and 39.8 for AGB, BGB, and TABGB, respectively. Consequently, the driven allometric equations can help accurate biomass quantification for carbon-trading schemes of C. inophyllum L. [ABSTRACT FROM AUTHOR]

Published

2022

47. COMPARISON OF BIOMASS ESTIMATION APPROACHES BASED ON INVENTORY DATA: A CASE STUDY IN KAPIKAYA FOREST, TURKEY.

Author

Sivrikaya, Fatih and Işık, Mehmet

Abstract

The aim of this study is to evaluate different above-ground biomass (AGB) considering different estimation approaches and to investigate if there are significant differences between the AGB estimations of these approaches using analysis of variance. In this study, the capabilities of three approaches including Biomass Conversion and Expansion Factor (BCEF) method, Biomass Conversion and Expansion Factor based on Tree Species (BCEFTS) method and Allometric Equation (AE) method were evaluated in estimation of AGB using forest inventory data in Kapıkaya Forest District (FD) located in the city of Kahramanmaraş in Turkey. The AGB values estimated by three approaches were 587362.4 tons, 587679.0 tons and 834112.3 tons for the BCEF, BCEFTS, and AE approaches, respectively. According to result of the analysis of variance, there was a significant difference between the AGB estimations of three approaches. AGB estimation of the AE approach was statistically different from the estimations of BCEF and BCEFTS. [ABSTRACT FROM AUTHOR]

Published

2022

48. Aboveground biomass and carbon storage in mangrove forests in southeastern Mexico

Author

Ávila Acosta, Carlos Roberto and Ávila Acosta, Carlos Roberto

Abstract

Producción Científica, The aboveground contributions of mangroves to global carbon sequestration reinforce the need to estimate biomass in these systems. The objective was to determine the aboveground biomass storage and quantify the carbon and CO2e content in Rhizophora mangle, Avicennia germinans, and Laguncularia racemosa present in southeastern Mexico. Based on the Forest Protocol for Mexico Version 2.0 methodology, published by Climate Action Reserve, 130 circular plots were randomly selected and established in an area of 930 ha of mangrove vegetation, and the aboveground biomass and stored carbon were determined. The mangrove had a density of 3515 ± 428.5 individuals per hectare. The aboveground biomass of the three species was 120.5 Mg ha−1. The biomass of L. racemosa was 99.5 Mg ha−1, which represents 82.6% of the total biomass. The biomass of R. mangle was 20.33 Mg ha−1, and that of A. germinans was 0.32 Mg ha−1. The total carbon retained in the trees was 60.25 Mg C ha−1 and 221.1 Mg CO2e ha−1. Laguncularia racemosa generated the highest contributions of CO2e. The area of mangroves accumulated 112,065 Mg of aboveground biomass. The carbon contained in this biomass corresponds to 205,623 Mg CO2e. This mangrove contributes to mitigating the effects of climate change globally through the reduction in greenhouse gases., Consejo Nacional de Ciencia y Tecnología (CONACYT) - (grant 441771)

Published

2024

49. Aboveground Biomass and Carbon Storage in Mangrove Forests in Southeastern Mexico

Author

Consejo Nacional de Ciencia y Tecnología (México), Ávila-Acosta, Carlos Roberto [0009-0000-0320-762X], Domínguez-Domínguez, Marivel [0000-0001-7579-1378], Vázquez-Navarrete, César Jesús [0000-0003-1071-6232], Acosta-Pech, Rocío Guadalupe [0000-0002-8855-765X], Martínez-Zurimendi, Pablo [0000-0002-8031-6448], Ávila-Acosta, Carlos Roberto, Domínguez-Domínguez, Marivel, Vázquez-Navarrete, César Jesús, Acosta-Pech, Rocío Guadalupe, Martínez-Zurimendi, Pablo, Consejo Nacional de Ciencia y Tecnología (México), Ávila-Acosta, Carlos Roberto [0009-0000-0320-762X], Domínguez-Domínguez, Marivel [0000-0001-7579-1378], Vázquez-Navarrete, César Jesús [0000-0003-1071-6232], Acosta-Pech, Rocío Guadalupe [0000-0002-8855-765X], Martínez-Zurimendi, Pablo [0000-0002-8031-6448], Ávila-Acosta, Carlos Roberto, Domínguez-Domínguez, Marivel, Vázquez-Navarrete, César Jesús, Acosta-Pech, Rocío Guadalupe, and Martínez-Zurimendi, Pablo

Abstract

The aboveground contributions of mangroves to global carbon sequestration reinforce the need to estimate biomass in these systems. The objective was to determine the aboveground biomass storage and quantify the carbon and CO2e content in Rhizophora mangle, Avicennia germinans, and Laguncularia racemosa present in southeastern Mexico. Based on the Forest Protocol for Mexico Version 2.0 methodology, published by Climate Action Reserve, 130 circular plots were randomly selected and established in an area of 930 ha of mangrove vegetation, and the aboveground biomass and stored carbon were determined. The mangrove had a density of 3515 ± 428.5 individuals per hectare. The aboveground biomass of the three species was 120.5 Mg ha−1. The biomass of L. racemosa was 99.5 Mg ha−1, which represents 82.6% of the total biomass. The biomass of R. mangle was 20.33 Mg ha−1, and that of A. germinans was 0.32 Mg ha−1. The total carbon retained in the trees was 60.25 Mg C ha−1 and 221.1 Mg CO2e ha−1. Laguncularia racemosa generated the highest contributions of CO2e. The area of mangroves accumulated 112,065 Mg of aboveground biomass. The carbon contained in this biomass corresponds to 205,623 Mg CO2e. This mangrove contributes to mitigating the effects of climate change globally through the reduction in greenhouse gases.

Published

2024

50. Remote sensing, allometry, and carbon stocks of Phyllostachys aurea in the Western Highlands of Cameroon

Author

Kaam, Rene, Tchamba, Martin, Nfornkah, Barnabas Neba, Djomo, Cédric Chimi, Kaam, Rene, Tchamba, Martin, Nfornkah, Barnabas Neba, and Djomo, Cédric Chimi

Abstract

The fight against climate change is one of the major concerns of the international community and has led to a search to identify cost-effective ways to manage ecosystems in a way that removes atmospheric carbon-dioxide while providing essential societal benefits. As bamboo ecosystems in Cameroon are poorly known, this study sought to evaluate the distribution of bamboo, develop allometric equations for it and estimate carbon stocks associated with bamboo in the Western Highlands of Cameroon. Landsat 8 OLI imagery was used to increase data on the distribution and carbon stocks of Phyllostachys aurea Carrière ex Rivière & C. Rivière in the study area. P. aurea is reportedly the most exploited species for ecological, socioeconomic and cultural activities in the region, posing a challenge for the sustainability of the species. Twelve circular plots were established in P. aurea stands in the Western Highlands. Five per cent of the bamboo stems were harvested. Every stem was sorted into leaves, branches, and culms. These were weighed, and sub-samples taken to the laboratory. Sub-samples were oven-dried for biomass estimation. Regression analysis was used to develop the allometric equations. The best equation was used to estimate the carbon stocks. The Western Highlands region of Cameroon is estimated to have 241,296 ha of bamboos. The dominant bamboo species identified in the study area include Oldeania alpina (K.Schum.) Stapleton (syn. Yushania alpina K.Schum.), Bambusa vulgaris Schrad. ex J.C.Wendl. and P. aurea. Focusing on P. aurea the best fit equation with a bias of − 6.98%, Adj.R² = 0.711, AIC = 17 and RSE = 0.262, was selected. The mean density of P. aurea was 38,017 ± 4510 culms.ha−1. The mean culm aboveground biomass was 3.15 ± 0.94 kg. The AGB of P. aurea was estimated at 119.05 ± 3.63 t.ha−1, mean AGC was 55.95 ± 5.81 t C.ha−1 and mean aboveground carbon dioxide equivalence (AGCO2eq) was 205.35 ± 58.01.22 t CO2.ha−1. P. aurea constitutes a significant carbon s

Published

2024