Your search keyword '"below-ground biomass"' showing total 132 results

1. Numerical modelling of biogeomorphological processes in salt marsh development: Do short-term vegetation dynamics influence long-term development?

Author

Dzimballa, S., Willemsen, P.W.J.M., Kitsikoudis, V., Borsje, B.W., and Augustijn, D.C.M.

Published

2025

2. Tree biomass carbon stocks and biodiversity, and their determinants in a traditional agroforestry landscape in the Vhembe Biosphere Reserve, South Africa.

Author

Makhubele, Lucky, Chirwa, Paxie, and Araia, Mulugheta

Abstract

Traditional agroforestry systems have been recognized worldwide for their positive contribution to biodiversity conservation, climate change mitigation, and improving socio-economic livelihood. Little has been reported regarding the effects of ecological determinants (tree density, species richness and diversity) on the biomass carbon accumulation potential of traditional agroforestry in South Africa, especially in the Vhembe Biosphere Reserve (VBR). The main objective of this study was to quantify tree biomass carbon stock and biodiversity in the VBR traditional agroforestry landscape along three distance levels (immediate, intermediate, and far distance) from villages to the forest. Vegetation data was collected using forestry inventory tools. In each distance, nine (9) linear transects (250 m long) were established with five rectangular plots (20 × 10m2) in 10 m apart. The sampling intensity was 10% and the sampling effort achieved was > 80%. Tree diversity metrics and above-and below ground carbon estimates were calculated from the data and then analyzed using PERMANOVA, ANOVA, Spearman’s correlation, and linear regression models. Tree species richness and diversity had no significant effect on carbon stocks, while an effect was found on tree density and elevation. The results showed no statistically significant differences in above-and below ground carbon stocks (F = 0.888, p = 0.413) among distance levels from villages while tree density (F = 19.353, p < 0.05) was found to be increasing with increasing distance from the village to the forest. The results suggest that biomass carbon stocks in traditional agroforestry landscape are independent of species richness and diversity, dependent on tree density. The lower tree density, species richness and diversity at immediate distance implies the effect of proximity disturbance. The immediate distance has a greater potential for high biomass carbon accumulation if the disturbance can be minimized and tree density augmented through planting indigenous tree species and conservation. [ABSTRACT FROM AUTHOR]

Published

2025

3. Comprehensive propagation of errors for the prediction of woody biomass

Author

Stephen H. Roxburgh and Keryn I. Paul

Subjects

above‐ground biomass, allometric models, allometry, below‐ground biomass, carbon accounting, error propagation, Ecology, QH540-549.5, Evolution, QH359-425

Abstract

Abstract Managing vegetation to sequester carbon in biomass requires estimates to meet standards for accuracy, with methods that are transparent, verifiable and cost‐effective. Allometric models are commonly used to predict biomass from non‐destructive field inventory data. Although a number of studies have addressed biomass error propagation, none have provided a general set of methods for linking errors all the way from initial allometric model development through to the final site‐based biomass prediction, for both above‐ and below‐ground biomass. Error sources in total biomass (above‐ + below‐ground) were quantified using a combination of analytical and Monte Carlo methods, illustrated with four contrasting case studies using either site‐ and‐species‐specific, species‐specific or generalised allometric models. Sampling error was found to be the most important contributor to site‐level biomass uncertainty, arising from the interaction between spatial variability and the field sampling design. The contribution of allometric model covariance to total error was also quantified, with errors in the determination of moisture content during allometric model development identified as a potentially important yet often overlooked error source. Application of different allometric models to the same inventory data suggested the error from generalised models was no greater than that from site‐ or species‐specific models, with increases in the generalised model prediction error balanced by decreases in other error sources associated with the increased sample size on which generalised models are based. Recommendations for reducing errors in predicted biomass include increasing field survey sample size, adopting field survey designs that ensure spatial representativeness and improving moisture content measurement protocols and increasing the moisture content sample size during allometric model development. To reduce costs while maintaining acceptable accuracy, the use of generalised allometric models is recommended, with the caveat that additional biomass sampling for model validation may be required to limit the potential for biased predictions.

Published

2025

4. Effects of livestock grazing on herbaceous species composition and biomass in the Simien Mountains National Park, Ethiopia.

Author

Abebe, Belayneh, Ashagrie, Mezgebu, and Eshete, Girma

Abstract

Simien Mountains National Park (SMNP) provides valuable ecosystem services. Despite its ecological values, the effect of livestock-free grazing on habitat quality has not been investigated. The present study aimed to examine how livestock grazing within the Simien Mountains National Park affects herbaceous plant diversity and biomass. The study was carried out from February 2019 to July 2019 in livestock-grazed and ungrazed sites. In each grazing site, ten transects with a length of 25 m were set monthly. Along each transect line, five temporary sample plots (1 m2) were established. For aboveground biomass estimation, grass and forbs were clipped from 0.25 m2 in every sample plot, whereas below-ground biomass was estimated from two soil core (diameter = 6.35 cm, depth =20 cm) samples in each transect. Species diversity and evenness were estimated using the Shannon-Wiener diversity and evenness index. A total of 43 plant species belonging to 20 families were identified. Aboveground biomass and below-ground biomass were significantly higher in ungrazed areas than in the grazed ones. Similarly, species diversity and richness were relatively lower in the grazed areas than in ungrazed areas. The study concluded that livestock grazing has affected the habitat by degrading the vegetation diversity and biomass production. Therefore, stakeholders should be encouraged to innovate appropriate grazing management technologies for the local livestock ranchers to support the conservation efforts of the park. [ABSTRACT FROM AUTHOR]

Published

2024

5. Alpine meadow degradation regulates soil microbial diversity via decreasing plant production on the Qinghai-Tibetan Plateau

Author

Yu Sun, Xiujuan Zhang, Yongsheng Yang, Yuheng Zhang, Junbang Wang, Mingyang Zhang, Chu Wu, Junliang Zou, Huakun Zhou, and Jiexia Li

Subjects

Alpine meadow degradation, Bacterial diversity, Fungal diversity, Above-ground biomass, Below-ground biomass, Ecology, QH540-549.5

Abstract

In recent decades, alpine meadows have experienced severe degradation owing to external disturbances. Although soil microorganisms are critical for ecosystem services, little is known about their responses to soil degradation and the potential patterns in alpine meadows. To solve this question, we collected and analyzed soil samples from three degraded alpine meadows situated on the Qinghai-Tibet Plateau. We aimed to examine the effects of degradation on soil microbial diversity and identify the ecological predictors for the diversity of bacteria and fungi. Our results showed that alpine meadow degradation significantly changed soil bacterial and fungal diversity and community composition. Specifically, the relationship between bacterial and fungal diversity and degradation intensity was a hump-shaped, with the highest diversity observed at a moderate degradation level. Additionally, alpine meadow degradation-induced changes in microbial diversity were strongly correlated with decreased plant production, with fungal diversity showing a closer link with below-ground biomass (BGB) than with bacterial diversity. Our findings offer empirical evidence that intermediate disturbance (i.e., moderate degradation) may be beneficial for supporting soil biodiversity. This has important implications for informing policy and management strategies meant to conserve soil biodiversity and ecosystem services when facing anthropogenic change.

Published

2024

6. Carbon storage in old hedgerows: The importance of below‐ground biomass.

Author

Drexler, Sophie, Thiessen, Eiko, and Don, Axel

Subjects

*WINDBREAKS, shelterbelts, etc., *BIOMASS, *AGRICULTURE, *FOREST biomass

Abstract

Ambitious climate change mitigation goals require novel carbon (C) sinks in agricultural systems. Thus, the establishment of new hedgerows is increasingly attracting attention as a C sequestration measure. Despite hedgerows being a traditional agroforestry system, few studies have been conducted on hedgerow C stocks. Data on below‐ground biomass (BGB) in particular are limited. The aim of this study was therefore to quantify both above‐ground biomass (AGB) and BGB C stocks, as well as litter and soil organic C stocks, of established hedgerow systems by destructive sampling at three sites in northern Germany. The total biomass C (TBC) stock of the sampled hedgerows was 105 ± 11 Mg ha−1 on average. An additional 11 ± 2 Mg ha−1 were found in hedgerow litter and dead roots. Coarse roots (34% of TBC), stumps (22%) and harvestable biomass (20%) were the largest biomass C pools of the hedgerows. The BGB:AGB ratio was 0.7 ± 0.1, showing the importance of BGB in old hedgerow systems. Compared with other woody systems, these old hedgerows seem to have a different biomass distribution, with more biomass allocated below‐ground. About 15% of BGB C stock was stored in fine roots, whereas 85% was stored in coarse roots. The topsoil (0–30 cm) contained 85% of coarse root biomass C and 51% of fine root biomass C. Hedgerow C stock exceeded that of average German forests, and thus demonstrated their large potential for C sequestration when newly planted. This study provides detailed empirical data on C stocks in old hedgerow systems, and thus can be used to take hedgerow C sinks into account in C farming frameworks. [ABSTRACT FROM AUTHOR]

Published

2024

7. Comparing the Grain Yields and Other Properties of Old and New Wheat Cultivars.

Author

Bilandžija, Darija, Zgorelec, Željka, Galić, Marija, Grubor, Mateja, Krička, Tajana, Zdunić, Zvonimir, and Bilandžija, Nikola

Subjects

*GRAIN yields, *WINTER wheat, *CARBON sequestration, *CULTIVARS, *WHEAT, *BIOMASS, *FOOD security

Abstract

Selecting cultivars with greater biomass results in higher yields and greater carbon sequestration. Storage of atmospheric carbon in the plant/soil pool contributes not only to food security but also to mitigating climate change and other agroecological benefits. The objective of this study was to determine: (1) grain, residue, and root biomass yields; (2) harvest indexes; (3) residue-to-product ratio; (4) root-to-shoot ratio; (5) biomass carbon and nitrogen contents; and (6) C:N ratios for two new and two old winter wheat cultivars. The greatest yield difference was found between old Srpanjka (the lowest) and new Kraljica (the highest) cultivar where grain, residue, root, and total biomass yield was higher by 38%, 91%, 71%, and 64%, respectively. Total biomass was composed of 40–47% grain, 10–11% roots, 32–36% stems + leaves, 9–11% chaff, and 1–2% spindle. The range of HI was 0.45–0.53, RPR 0.91–1.25, and R:S ratio 0.12–0.13. For all cultivars, positive carbon and negative nitrogen balance within the plant pool was determined. Still, root biomass and rhizodeposition carbon remain open questions for a better understanding of agroecosystems' C dynamics. [ABSTRACT FROM AUTHOR]

Published

2023

8. Organic Carbon, Nitrogen Accumulation and Nitrogen Leaching as Affected by Legume Crop Residues on Sandy Loam in the Eastern Baltic Region.

Author

Tripolskaja, Liudmila, Kazlauskaite-Jadzevice, Asta, and Razukas, Almantas

Subjects

CROP residues, LEGUME farming, LEGUMES, LEACHING, SOIL leaching, ATMOSPHERIC nitrogen

Abstract

Legumes have a wide range of positive effects on soil properties, including nitrogen and carbon storage, soil structure and the phytosanitary condition of crops. From an agronomic point of view, legumes are most valued for their ability to take up atmospheric nitrogen in symbiosis with nitrogen-fixing bacteria. The aim of this research was to determine the effect of legume residues (peas, fodder beans, narrow-leaved lupins) on the N (Ntotal) and organic carbon (Corg) accumulation in soil and N leaching under temperate climate conditions. The experiment was carried out in lysimetric equipment in 2016–2023. The effect of legumes on Corg and Ntotal accumulation in soil and N leaching were studied in a Fabaceae–Cereals sequence. Three species of legumes—peas, fodder beans and narrow-leaved lupines—were tested; spring barley (Hordeum vulgare L.) was grown as a control treatment. The lysimeter surface area was 1.75 m2 and the experimental soil layer was 0.60 m (sand loam Haplic Luvisol). It was found that after harvesting, more residues were incorporated into the soil with lupines (p < 0.05), which, compared to pea and bean residues, increased Ntotal and Corg concentrations in the soil. There was a strong correlation (r = 0.95) between the Ntotal concentration in the soil and the N amount incorporated with residues. Mineral N released during residue decomposition was leached from the humic horizon under conditions of excess moisture in the autumn–winter period and increased the nitrate concentration in the lysimeter water. The increase in concentration was recorded within 5 to 6 months after the application of the residues. As a result, the N leaching losses increased on average by 24.7–33.2% (p < 0.05) during the year of legume cultivation. In the following year, after legume residue incorporation, the effect of residues on nitrate concentration and N leaching decreased and did not differ significantly from that of barley residues. [ABSTRACT FROM AUTHOR]

Published

2023

9. Decomposition and Nutrient Release from Larix olgensis Stumps and Coarse Roots in Northeast China 33-Year Chronosequence Study.

Author

Men, Xiuli, Yue, Yang, Wang, Xiuwei, and Chen, Xiangwei

Subjects

LARCHES, NUTRIENT cycles, FOREST plants, SOIL fertility, HEMICELLULOSE, PINACEAE

Abstract

Stumps and coarse roots form an important C pool and nutrient pool in a Larix olgensis (Larix olgensis Henry) plantation ecosystem, and their decomposition processes would affect nutrient cycling dynamics of the overall Larix olgensis plantation. We studied the decomposition and release of nutrients from stumps and coarse roots that were cleared 0, 6, 16, 26 and 33 years ago in Northeast China. The stumps and coarse roots were divided into stump discs (SD), stump knots (SK), coarse roots (>10 cm in diameter) (CR1), medium-coarse roots (5–10 cm in diameter) (CR2) and fine-coarse roots (2–5 cm in diameter) (CR3). During the entire 33-year study period, SK, CR1, CR2 and CR3 lost 87.37%, 96.24%, 75.76% and 91.98% of their initial mass, respectively. The average annual decomposition rate (k) was 0.068 for SD, 0.052 for SK, 0.092 for CR1, 0.068 for CR2 and 0.066 for CR3. After 33 years of decomposition, CR3 lost 5% of its initial C, CR2 lost 2%, and SK accumulated 1%, indicating slow C release. The N residues in SK, CR1, CR2 and CR3 were 186%, 109%, 158% and 170%, respectively. Coarse roots released P significantly faster than SD and SK, with 13% of the initial P released in CR1. SD and SK release cellulose, hemicellulose and lignin faster than coarse roots. The results show that Larix olgensis stumps and coarse roots could contribute to soil fertility recovery and serve as a long-term nutrient reservoir for forest vegetation. [ABSTRACT FROM AUTHOR]

Published

2023

10. Effect of experimental climate change and soil moisture content on germination and early growth response of Quercus dentata seedlings

Author

Eui-Joo Kim, Young-Ho Jung, Jae-Hoon Park, Eung-Pill Lee, Chae-Sun Na, Chung-Yeoul Park, Jun-Hyeok Kim, Se-Hee Kim, Ji-Won Park, Jung-Min Lee, Yoon-Seo Kim, Kyung-Mi Cho, Hae-Ran Kim, Heon-Mo Jeong, and Young-Han You

Subjects

Initial establishment, below-ground biomass, population variance, environment gradient, individual characteristics, Forestry, SD1-669.5

Abstract

AbstractThis study was conducted to investigate the effect of changes in soil moisture content under climate change conditions on the growth response of Quercus dentata, a representative species of the genus Quercus on the Korean peninsula. The results showed that Q. dentata germination increased by 9.4 days under climate change conditions (RCP 4.5 scenario), whereas the below-ground biomass and plant biomass increased by 1.3 and 1.2 times, respectively. However, the soil moisture treatment condition solely affected the leaf area, below-ground biomass, and plant biomass but not the germination percentage, germination speed, above-ground length, and above-ground biomass. The variance across the measured growth variables was considerably higher in the control group than in the climate change treatment group, whereas the variance was lower for lower soil moisture content. The findings suggested that under climate change conditions, Q. dentata germinated rapidly and exhibited broader leaf area and increased development below ground, which may be advantageous for the early establishment of seedlings. However, the plants may face difficulties in conditions with low soil moisture content. In conclusion, with continuous climate changes, Q. dentata seedlings are predicted to efficiently adapt to the altered soil moisture content to exhibit even more reliable growth than with the current condition. However, the growth of Q. dentata seedlings would be more difficult with severely low soil moisture content than with abundant soil moisture content, which is predicted to be detrimental to population maintenance in the long term.

Published

2022

11. Organic Carbon, Nitrogen Accumulation and Nitrogen Leaching as Affected by Legume Crop Residues on Sandy Loam in the Eastern Baltic Region

Author

Liudmila Tripolskaja, Asta Kazlauskaite-Jadzevice, and Almantas Razukas

Subjects

nitrogen, organic carbon, leaching, above-ground biomass, below-ground biomass, Botany, QK1-989

Abstract

Legumes have a wide range of positive effects on soil properties, including nitrogen and carbon storage, soil structure and the phytosanitary condition of crops. From an agronomic point of view, legumes are most valued for their ability to take up atmospheric nitrogen in symbiosis with nitrogen-fixing bacteria. The aim of this research was to determine the effect of legume residues (peas, fodder beans, narrow-leaved lupins) on the N (Ntotal) and organic carbon (Corg) accumulation in soil and N leaching under temperate climate conditions. The experiment was carried out in lysimetric equipment in 2016–2023. The effect of legumes on Corg and Ntotal accumulation in soil and N leaching were studied in a Fabaceae–Cereals sequence. Three species of legumes—peas, fodder beans and narrow-leaved lupines—were tested; spring barley (Hordeum vulgare L.) was grown as a control treatment. The lysimeter surface area was 1.75 m2 and the experimental soil layer was 0.60 m (sand loam Haplic Luvisol). It was found that after harvesting, more residues were incorporated into the soil with lupines (p < 0.05), which, compared to pea and bean residues, increased Ntotal and Corg concentrations in the soil. There was a strong correlation (r = 0.95) between the Ntotal concentration in the soil and the N amount incorporated with residues. Mineral N released during residue decomposition was leached from the humic horizon under conditions of excess moisture in the autumn–winter period and increased the nitrate concentration in the lysimeter water. The increase in concentration was recorded within 5 to 6 months after the application of the residues. As a result, the N leaching losses increased on average by 24.7–33.2% (p < 0.05) during the year of legume cultivation. In the following year, after legume residue incorporation, the effect of residues on nitrate concentration and N leaching decreased and did not differ significantly from that of barley residues.

Published

2023

12. Grassland biomass allocation across continents and grazing practices and its response to climate and altitude.

Author

Cao, Jianjun, Li, Yumei, Biswas, Asim, Holden, Nicholas M., Adamowski, Jan F., Wang, Fengchu, Hong, Shuyan, and Qin, Yanyan

Subjects

*RANGE management, *DATABASES, *BIOMASS, *ALTITUDES, *GLOBAL studies, *GRASSLANDS, *GRAZING

Abstract

• Grassland biomass allocation is sensitive to natural conditions and grazing practices. • Differences in grassland biomass allocation existed among continents. • Grazing practice affected aboveground part and the ratio of it to below-ground part. • Climate has a stronger role in regulating grassland biomass allocation than altitude. • Warming may exert a more detrimental effect on grazed grasslands than non-grazed ones. Biomass allocation in grasslands is key to understanding plant response to environmental changes and grazing management. Yet, global studies on how this split between above-ground and below-ground biomass varies across continents and grazing practices are notably scarce. We employ a comprehensive field-oriented grassland database to examine differences in total net primary productivity (TNPP), above-ground net primary productivity (ANPP), below-ground net primary productivity (BNPP), and the BNPP to ANPP ratio across continents and between grazed and non-grazed grasslands. Oceania showed the greatest ANPP (916 g·m−2·a−1), while Asia had the lowest (192 g·m−2·a−1). BNPP values were similar among Oceania, Africa, and Asia (∼600 g·m−2·a−1), significantly exceeding those in Europe (289 g·m−2·a−1) and North America (408 g·m−2·a−1). South America, Africa, and Oceania had the highest TNPP (around 1418 g·m−2·a−1 to 1466 g·m−2·a−1), while Europe had the lowest TNPP (344 g·m−2·a−1). The BNPP to ANPP ratio was highest in South America (4.17) and Asia (3.46). Global differences in TNPP and BNPP between grazed and non-grazed grasslands were minimal, but ANPP (169 g·m−2·a−1 and 198 g·m−2·a−1, respectively) and the BNPP to ANPP ratio (4.87 and 2.40, respectively) differed significantly. Across continents and grazing practices, climate had a greater role in regulating grassland biomass allocation than altitude, and warming may have a more detrimental impact on grazed grasslands than non-grazed grasslands. Distinct biomass allocation trends under various continental and grazing conditions exert effects on the economic and ecological functions of grasslands. Our study underscores the need for balanced grassland utilization strategies at a global scale. This involves optimizing grazing in high ANPP grasslands and protecting those with significant BNPP, thereby contributing to a sustainable and ecologically sound use of grasslands in the future. [ABSTRACT FROM AUTHOR]

Published

2024

13. Carbon dioxide sequestered by trees in an urban institution: A case study

Author

Ritica Mohan, Saima Qamar, and Anil K. Raina

Subjects

Above ground biomass, Below-ground biomass, Carbon sequestration, Oxygen production, Trees, Environmental sciences, GE1-350

Abstract

The geographical location, climate, topography and most important human interference has contributed to the characteristic flora of the old campus of University of Jammu. A total of 24 tree species having 153 individuals belonging to 14 families have been recorded. Out of 24, 23 species belong to Angiosperms (22 dicots and 1 monocot) whereas, only 1 species belong to Gymnosperms. Overall, Moraceae was found to be the dominant family. The total growing stock, total biomass, total carbon content within university campus has been assessed to be 215663.99cm3, 107.83kg, 50.68kg respectively. The total CO2 sequestered by trees and net oxygen produced have been estimated to be 185.84kg and 495.65kg, respectively. Thus, the old campus of University of Jammu with lot of built-up area, roads, lawns, parking places, garden, etc. has sequestered considerably good amount of carbon and also produced considerable amount of oxygen as compared to its size, and its potential for sequestration can be enhanced with the help of management practices and plantation of more trees/shrubs within the permissible areas.

Published

2022

14. Simulated precipitation change drives plant diversity and biomass change in the desert steppe.

Author

Wang, Yuehua, Wang, Zhongwu, Li, Haigang, Sun, Hailian, Shen, Tingting, Song, Xiaohui, Wang, Zhanwen, and Han, Guodong

Subjects

*PLANT biomass, *PLANT species diversity, *STEPPES, *PLANT diversity, *DROUGHTS, *DESERTS, *BIOMASS

Abstract

There is a large uncertainty regarding the direction and magnitude of projected changes in the pattern and quantity of precipitation in future climate change scenarios. As changes in precipitation are likely to greatly impact plant diversity and biomass in desert ecosystems, we undertook a water addition/exclusion experiment to quantify the responses of plant diversity and biomass. To quantify the short-term impacts of changing the quantity of precipitation on plant species diversity and productivity in a desert steppe ecosystem. A simulated precipitation manipulation (addition and exclusion) experiment was made with four treatments: precipitation decreased by 50% (P-50%), precipitation increased by 50% (P+50%), precipitation increased by 100% (P+100%) and natural precipitation (Control). The richness of annual and biennial species was related to treatment; above-ground biomass increased in dry years in the P+100% treatment. Water addition had no statistically significant impacts on below-ground biomass. Increase in above-ground biomass with added precipitation in a drought year was mainly contributed by perennial grasses, suggesting that, from a management point of view, perennial grasses should be the focus of mitigation of projected future precipitation changes. [ABSTRACT FROM AUTHOR]

Published

2022

15. Carbon dioxide sequestered by trees in an urban institution: A case study.

Author

Mohan, Ritica, Qamar, Saima, and Raina, Anil K.

Subjects

URBAN trees, CARBON dioxide, BOTANY, ANGIOSPERMS, DICOTYLEDONS, SHRUBS, MORACEAE

Abstract

The geographical location, climate, topography and most important human interference has contributed to the characteristic flora of the old campus of University of Jammu. A total of 24 tree species having 153 individuals belonging to 14 families have been recorded. Out of 24, 23 species belong to Angiosperms (22 dicots and 1 monocot) whereas, only 1 species belong to Gymnosperms. Overall, Moraceae was found to be the dominant family. The total growing stock, total biomass, total carbon content within university campus has been assessed to be 215663.99cm3, 107.83kg, 50.68kg respectively. The total CO2 sequestered by trees and net oxygen produced have been estimated to be 185.84kg and 495.65kg, respectively. Thus, the old campus of University of Jammu with lot of built-up area, roads, lawns, parking places, garden, etc. has sequestered considerably good amount of carbon and also produced considerable amount of oxygen as compared to its size, and its potential for sequestration can be enhanced with the help of management practices and plantation of more trees/shrubs within the permissible areas. [ABSTRACT FROM AUTHOR]

Published

2022

16. Variation in biomass allocation and root functional parameters in response to fire history in Brazilian savannas.

Author

Le Stradic, Soizig, Roumet, Catherine, Durigan, Giselda, Cancian, Leonardo, and Fidelis, Alessandra

Subjects

*BIOMASS, *SAVANNAS, *VEGETATION dynamics, *ECOSYSTEM dynamics, *WOODY plants, BRAZILIAN history

Abstract

Fire is a fundamental ecological factor in savannas because it affects vegetation dynamics and ecosystem functioning. However, the effects of fire on below‐ground compartments, including biomass and root traits, and their regeneration remain poorly understood. In this study, we assess the variation of above‐ and below‐ground plant components along fire‐history gradients in Brazilian open savannas and investigate whether changes in vegetation and soil properties are associated with the responses of below‐ground biomass and root traits.The study was conducted in eight sampling areas of open savanna (campo sujo, i.e. vegetation having low woody cover) within the Cerrado (Brazilian savannas), located along a gradient of time since the last fire (1–34 years); the number of fires that occurred within the past 34 years (0–9 fires) varied by sampling area. In each sampling area, we measured above‐ and below‐ground biomass, root depth distribution, root functional parameters and nutrient levels in the upper soil layers (0–10 cm).Rapid recovery of above‐ground live biomass after a fire was primarily due to resprouting of graminoids. This recovery was associated with an increase in absorptive root biomass in the upper soil layer in the most recently burnt sites, whereas root biomass was unaffected in deeper layers. Root parameters remained constant regardless of fire history but responded to variations in vegetation structure and soil properties. Specific root length (SRL) decreased with K, Mg2+, Al3+, N and C and increased with P concentration. In contrast, root tissue density (RTD) and absorptive root proportion were negatively correlated with soil P. RTD was strongly associated with the above‐ground biomass of graminoids. Soil texture impacted the root system: the proportion of absorptive roots increased with fine sand content in the soil, inversely to transport root biomass. The relationship between fire and soil properties was insignificant.Synthesis. In savannas, fire stimulates absorptive root biomass in response to the higher demand for below‐ground resources. This response is correlated with shoot regrowth after a fire. Variations in morphological root parameters are not directly associated with fire history; instead, they reflect differences in soil chemistry, especially soil P and graminoid biomass changes. [ABSTRACT FROM AUTHOR]

Published

2021

17. Using Allometric Equations to Estimate Mangrove Biomass and Carbon Stock in Demta Bay, Papua Province, Indonesia.

Author

Indrayani, Ervina, Kalor, John Dominggus, Warpur, Maklon, and Hamuna, Baigo

Subjects

MANGROVE forests, MANGROVE plants, ALLOMETRIC equations, CLIMATE change mitigation, BIOMASS, CARBON sequestration, CARBON cycle

Abstract

The mangrove ecological services as carbon sinks and storage are very useful in the efforts to mitigate global warming and climate change. In this study, the above and below-ground biomass, carbon stock, as well as carbon sequestration by the mangroves in Demta Bay, Papua Province, Indonesia were estimated. Allometric equations were used to determine the mangrove biomass in 36 observation plots. The biomass value was used to determine carbon stock and estimate carbon sequestration. Nine mangrove species were found in Demta Bay, with the contribution of mangrove species to biomass (AGB and BGB) in the following order: Rhizophora apiculata > Rhizophora mucronata > Bruguiera gymnorhiza > Bruguiera cylindrica > Heritiera Littoralis > Xylocarpus molucensis > Rhizophora stylosa > Avicennia marina > Sonneratia caseolaris. The average mangrove biomass was estimated at 174.20 ± 68.14 t/ha (AGB = 117.62 ± 45.68 t/ha and BGB = 56.58 ± 22.49 t/ha). The carbon stocks in mangroves at the Ambora site were higher than the Tarfia and Yougapsa sites, averaging 123.57 ± 30.49 t C/ha, 81.64 ± 25.29 t C/ha, and 56.09 ± 39.03 t C/ha, respectively. The average carbon stock in the mangrove ecosystem of Demta Bay is estimated at 87.10 ± 34.07 t C/ha or equivalent to 319.37 ± 124.92 t CO2 e/ha. The results of this study indicate that the mangrove ecosystem in Demta Bay stores quite high carbon stocks, so it is necessary to maintain it with sustainable management. Therefore, climate change mitigation is not only done by reducing the carbon emission levels but also needs to be balanced by maintaining the mangrove ecosystem services as carbon sinks and sequestration. [ABSTRACT FROM AUTHOR]

Published

2021

18. Plant quality and primary productivity modulate plant biomass responses to the joint effects of grazing and fertilization in a mesic grassland.

Author

Campana, Sofía and Yahdjian, Laura

Abstract

Questions: Human activities are increasing the density of domestic grazers and global nutrient loads, modifying the main determinants of vegetation community dynamics. Grazing (top‐down control) and nutrient availability (bottom‐up control) may interactively modify plant biomass, which is particularly important in grasslands devoted to livestock production. Here, we aim to understand the interactive effects of grazing and fertilization on grassland plant biomass. We hypothesized that the joint effects of nutrient addition and domestic grazing on above‐ground plant biomass are not additive, but they modify each other through changes in ground‐level light, leaf nutritional quality, above‐ground net primary productivity (ANPP), and below‐ground plant allocation. Location: Flooding Pampa (Buenos Aires, Argentina). Methods: We carried out a factorial experiment of grazing exclusion and fertilization with nitrogen, phosphorus, and potassium + micronutrients during ​several years in a mesic grassland devoted to livestock production. Results: After four years, grazing reduced live above‐ground plant biomass by 52%, and when combined with fertilization this reduction was 70%. Nutrient addition in the grazed grassland increased ANPP and leaf nutrient concentration. These changes in turn intensified grazing pressure and cattle’s plant consumption. By contrast, fertilization did not produce any significant effect on plant biomass or ANPP inside the exclosures, where ground‐level light was low. A structural equation model revealed that the increase in ANPP fostered above‐ground and reduced below‐ground plant biomass. Conclusions: This is the first study conducted in the Pampas grasslands that evaluated the effect of cattle grazing and fertilization on plant communities under field conditions over several years. Grazing and nutrient addition synergistically controlled grassland plant biomass, as the reduction in above‐ground biomass by cattle consumption was greater in fertilized plots. Our results provided empirical evidence that leaf nitrogen and ANPP modulated plant biomass dynamics in grasslands devoted to livestock production in the context of increased nutrient loads in terrestrial ecosystems.Grassland ecosystems are used for livestock production and are exposed to the global alteration of nutrient budgets. We found that grazing reduced above‐ground plant biomass, but this reduction was greater when combined with nutrient addition. The observed changes in plant biomass across experimental plots were mainly accounted for by differences in plant quality and rates of above‐ground plant biomass production. [ABSTRACT FROM AUTHOR]

Published

2021

19. A non-destructive method for estimating woody biomass and carbon stocks of Vitellaria paradoxa in southern Mali, West Africa.

Author

Sanogo, Kapoury, Bayala, Jules, Villamor, Grace B., Dodiomon, Soro, and van Noordwijk, Meine

Subjects

AGROFORESTRY, BIOMASS, MATHEMATICAL finance, MONETARY incentives, FUNCTIONAL analysis, WOODY plants, CARBON, PLANT biomass

Abstract

The shea tree, Vitellaria paradoxa, shields people, crops and livestock in West African parkland agroforestry systems from climate variability. Accurate estimates of accumulated biomass of such key species may support ways to secure financial incentives within global climate policies. In this quest, variation in allometric relations used for biomass (carbon stock) estimates on the basis of stem diameter matters, but parameters a and b of the standard format (AGB = a Db; AGB = aboveground biomass, D = stem diameter) are correlated and are directly related to tree shapes. Functional branch analysis (FBA) allows non-destructive derivation of allometrics. For Koutiala and Yanfolila shea populations empirical branching parameters were scale-independent, matching FBA assumptions. Allometry (AGB = 169 (D/20)2.64 and AGB = 146 (D/20)2.65, kg tree−1) implied 22%, 16% and 11% larger vegetative aboveground biomass in Koutiala than in Yanfolila at stem diameters (D) of 10, 20 and 32 cm, respectively. Below-ground biomass predictions (BGBi = 8.73 (Di/10)2.35 and BGBi = 8.16 (Di/10)2.38, kg per proximal root) differed − 6% and − 15% for root diameters Di of 10 and 32 cm, respectively. On a dry weight basis, the shoot:root ratio was 2.7 and 2.9, respectively for the two sites. Stand-level above-and below-ground carbon stocks in Koutiala (2.16 ± 0.44 and 0.8 ± 0.15 Mg C ha−1) were not significantly different from those in Yanfolila (3.21 ± 0.60 and 1.26 ± 0.21 Mg C ha−1), respectively. Further research is required to include (potential) fruit production to the plant architectural model. [ABSTRACT FROM AUTHOR]

Published

2021

20. Light grazing facilitates carbon accumulation in subsoil in Chinese grasslands: A meta‐analysis.

Author

Jiang, Zhi‐Yun, Hu, Zhong‐Min, Lai, Derrick Y. F., Han, Dao‐Rui, Wang, Mei, Liu, Min, Zhang, Meng, and Guo, Ming‐Yan

Subjects

*GRASSLAND soils, *SUBSOILS, *GRAZING, *GRASSLANDS, *SOIL dynamics, *SOIL depth

Abstract

Grazing by livestock greatly affects the soil carbon (C) cycle in grassland ecosystems. However, the effects of grazing at different intensities and durations on the dynamics of soil C in its subsoil layers are not clearly understood. Here, we compiled data from 78 sites (in total 122 published studies) to examine the effects of varying grazing intensities and durations on soil C content at different depths for grasslands in China. Our meta‐analysis revealed that grazing led to an overall decrease in soil C content and productivity of above‐ground vegetation (e.g., above‐ground biomass and litter) but an increase in below‐ground biomass. Specifically, the effects of grazing on soil C content became less negative or even positive with increasing soil depths. An increase of soil C content was consequently found under light grazing (LG), although soil C content still decreased under moderate and heavy grazing. The increase in soil C content under LG could be largely attributed to the increase of soil C content in subsoil layers (>20 cm), despite that soil C content in surface soil layer (0–20 cm) decreased. Moreover, the magnitude of increase in soil C content under LG in subsoil layers increased with grazing duration. A possible reason of the increase in soil C content in the subsoil layers was due to the increases in below‐ground biomass. Our study highlights that LG may modify the allocation of C input and promote its accumulation in subsoil layers, thus offsetting the negative impact of grazing on surface soil C content, a finding that has significant implications for C sequestration in grasslands. [ABSTRACT FROM AUTHOR]

Published

2020

21. Weekly defoliation controls, but does not kill broad‐leaved dock (Rumex obtusifolius).

Author

Evert, F K, Cockburn, M, Beniers, J E, Latsch, R, and Moonen, Camilla

Subjects

*DEFOLIATION, *RUMEX, *LEAF area, LEAF growth

Abstract

Summary: Broad‐leaved dock (Rumex obtusifolius L.) is a troublesome weed that predominantly grows in pastures and grassland. We hypothesised that frequent defoliation of Rumex will, over time, result in a reduction in root weight and leaf area, to the point where the impact on grass production is negligible. In order to investigate this hypothesis, we conducted three experiments. The objective of the first experiment was to perform a preliminary test of the hypothesis, using potted plants growing in the controlled conditions of a glasshouse. This experiment showed a rapid decline in leaf growth in plants that were defoliated weekly. The objective of the second experiment was to test the hypothesis in realistic outdoor conditions while still being able to collect detailed plant growth information. This experiment confirmed the findings of the glasshouse experiment and provided evidence that leaf growth ceased as a result of a dwindling supply of carbohydrate reserves in the root. Defoliated plants did not exhibit increased mortality. Finally, the objective of the third experiment was to test the hypothesis in a commercial pasture where normal field operations, specifically grass harvesting (three times) and slurry injection (twice), were performed. The results of this experiment were consistent with the results of the other two experiments. We conclude that weekly defoliation, maintained for three or more months, is an effective method to control (reduce the impact on grass production), but not kill, R. obtusifolius in pasture. [ABSTRACT FROM AUTHOR]

Published

2020

22. Below-ground biomass of plants, with a key contribution of buried shoots, increases foredune resistance to wave swash.

Author

Battisti, Davide De and Griffin, John N

Subjects

*PLANT biomass, *SAND dunes, *DISEASE resistance of plants, *ANNUALS (Plants), *COASTAL changes, *GRAIN size, *PLANT shoots, *ROOTSTOCKS

Abstract

Background and aims Sand dunes reduce the impact of storms on shorelines and human infrastructure. The ability of these ecosystems to provide sustained coastal protection under persistent wave attack depends on their resistance to erosion. Although flume experiments show that roots of perennial plants contribute to foredune stabilization, the role of other plant organs, and of annual species, remains poorly studied. Furthermore, it remains unknown if restored foredunes provide the same level of erosion resistance as natural foredunes. We investigated the capacity of three widespread pioneer foredune species (the perennial Ammophila arenaria and the annuals Cakile maritima and Salsola kali) to resist dune erosion, and compared the erosion resistance of Ammophila at natural and restored sites. Methods Cores collected in the field were tested in a flume that simulated a wave swash. A multi-model inference approach was used to disentangle the contributions of different below-ground compartments (i.e. roots, rhizomes, buried shoots) to erosion resistance. Key Results All three species reduced erosion, with Ammophila having the strongest effect (36 % erosion reduction versus unvegetated cores). Total below-ground biomass (roots, rhizomes and shoots), rather than any single compartment, most parsimoniously explained erosion resistance. Further analysis revealed that buried shoots had the clearest individual contribution. Despite similar levels of total below-ground biomass, coarser sediment reduced erosion resistance of Ammophila cores from the restored site relative to the natural site. Conclusions The total below-ground biomass of both annual and perennial plants, including roots, rhizomes and buried shoots, reduced dune erosion under a swash regime. Notably, we show that (1) annual pioneer species offer erosion protection, (2) buried shoots are an important plant component in driving sediment stabilization, and (3) management must consider both biological (plants and their traits) and physical (grain size) factors when integrating dunes into schemes for coastal protection. [ABSTRACT FROM AUTHOR]

Published

2020

23. Get on your boots: estimating root biomass and rhizodeposition of peas under field conditions reveals the necessity of field experiments.

Author

Hupe, Anke, Schulz, Hannes, Bruns, Christian, Haase, Thorsten, Heß, Jürgen, Dyckmans, Jens, Joergensen, Rainer Georg, and Wichern, Florian

Subjects

*PEAS, *BIOMASS, *HARVESTING time, *SOIL sampling, *PLANT development, *BOOTS

Abstract

Aims: More sustainable agricultural systems, which contribute to C sequestration and biological N fixation, require accurate quantification of plant C and N inputs into soils. This has to be conducted under field conditions, as there are serious shortcomings to pot-based experiments, which have dominated studies on rhizodeposition estimation in the past. Therefore, amounts of below-ground plant C, N, and especially the rhizodeposition of peas were quantified in the field more accurately, with particular emphasis on their transfer into different soil compartments during vegetation. Methods: Pea (Pisum sativum L.) plants were labelled with multiple pulses of 13C-glucose and 15N urea using the cotton wick method. Plants were harvested at four dates depending on plant development. Representative soil samples were taken at harvest with a special drilling tool, considering the spatial distribution of pea roots. Results: Our results indicate that the quantity of C and N rhizodeposition did not change between flowering and maturity. About one third of the C and N rhizodeposits were present in microbial biomass and extractable C or the inorganic N pool of soil. When comparing this field study to a former pot experiment, a higher root-to-shoot ratio was detected; also the rhizodeposition-to-root ratio was altered in the field, questioning the assumption that results from pot experiments can be transferred to field conditions. Conclusions: Due to a higher below-ground C (BGC) and N (BGN) input compared to pot experiments, studies aiming at quantifying BGC and BGN input will have to be conducted under field conditions. [ABSTRACT FROM AUTHOR]

Published

2019

24. Differential tolerance of native and invasive tree seedlings from arid African deserts to drought and shade.

Author

Abbas, A.M., Rubio-Casal, A.E., De Cires, A., Grewell, B.J., and Castillo, J.M.

Subjects

*TREE seedlings, *IRRADIATION treatment of water, *SHADES & shadows, *CLIMATE change, *DROUGHTS

Abstract

Efforts to understand why some species become successful invaders and why some habitats are more at risk from invasive species is an important research focus in invasion ecology. With current global climate change, evaluation of the effects of shade and drought on cohabiting native and invasive species from extreme ecosystems is especially important. Acacia tortilis subsp. raddiana is a tree taxon native to arid African deserts. Prosopis glandulosa, native to the southwestern United States and Mexico, is invading African arid and semiarid regions that are habitat for A. t. subsp. raddiana. The aim of this study was to evaluate and compare the tolerance and responses of the seedlings of these two tree species to shade, water stress and their interactions. We measured and recorded growth rates and morphological, biochemical and physiological plant traits under two radiation and two water treatments in greenhouse conditions. Radiation intensity was a stronger driver of the performance of both species than water availability. Beyond the independent effects of shade and drought, the interactions of these factors yielded synergistic effects on seedlings of both tree species, affecting key plant traits. The seedlings of A. t. subsp. raddiana were able to implement important shifts in key functional traits in response to altering abiotic stress conditions, behaving as a stress-tolerant species that is well-adapted to the habitat it occupies in hot arid African deserts. In contrast, the fast-growing seedlings of P. glandulosa were stress-avoiding. The alien P. glandulosa seedlings were highly sensitive to water and shade stress. Moreover, they were particularly sensitive to drought in shade conditions. However, although alien P. glandulosa seedlings were exposed to high stress levels, they were able to avoid permanent damage to their photosynthetic apparatus by mechanisms such as increasing energy dissipation by heat emission and by adjusting the relative allocation of resources to above- and below-ground structures. Our results are useful for conservation planning and restoration of invaded hyperarid ecosystems. • Radiation intensity was a stronger driver of plant responses than water availability. • The interactions between shade and drought yielded synergistic effects. • The seedlings of Acacia tortilis subsp. raddiana behaved as stress-tolerant. • The seedlings of Prosopis glandulosa behaved as stress-avoiding and fast-growing. • Prosopis glandulosa avoided permanent damage to its photosynthetic apparatus under high stress conditions. [ABSTRACT FROM AUTHOR]

Published

2019

25. Root carbon and soil temperature may be key drivers of below-ground biomass in grassland following prescribed fires in autumn and spring.

Author

Luo, Chaoyi, Fang, Zhao, Liu, Jiang, Han, Fengpeng, Wu, Yanhong, Bing, Haijian, and Zhao, Peng

Subjects

*PRESCRIBED burning, *SPRING, *AUTUMN, *SOIL temperature, *CARBON in soils

Abstract

Under global warming, fire and the season in which the fire occurs both have important impacts on grassland plant biomass. Still, the effect of fire on below-ground biomass (BB) along a natural aridity gradient and the main impact factors remain unclear. Here, we conducted a fire manipulation experiment (including un-fired, autumn fire and spring fire treatments) to investigate the effects of prescribed fire on BB and its critical determinants along a transect of grassland in northern China. BB had different response strategies in different aridity regions and fire seasons, despite above-ground biomass (AB) and root-shoot ratio were not significantly affected by fire. General linear regression models revealed that the fire changed the trend of increasing BB to decreasing along increasing aridity (p ＜ 0.05). Random forest model (RFM) and partial correlations revealed that the BB was primarily influenced by aridity, followed by the nitrogen (N) and phosphorus (P) concentration ratio of AB under un-fired disturbance. For autumn fire, the BB was primarily influenced by below-ground biomass carbon concentration (BB c), followed by the C and N concentration ratio of BB. For spring fire, the BB was primarily influenced by soil temperature (ST), followed by aridity and soil total phosphorus concentration (Soil p). Furthermore, partial least squares path model (PLS-PM) revealed that autumn fires weakened the effects of environmental factors on BB, while spring fires enhanced the effects of soil nutrients on BB. These suggested that fire disrupted the original stable nutrient dynamics of BB. Our results suggested that fire promoted the growth of BB in relatively humid areas (aridity = 0.51–0.53) while inhibited the growth of BB in relatively arid areas (aridity = 0.68–0.74). BB c and ST may be key drivers of BB after prescribed fire in autumn and spring. • The prescribed fire changed the trend of increasing belowground biomass to decreasing along with increasing aridity. • The belowground biomass of plants was mainly regulated by belowground biomass C after prescribed fire in autumn. • The belowground biomass of plants was mainly regulated by soil temperature after prescribed fire in spring. • The prescribed fire disrupted belowground biomass's original stable nutrient dynamics. [ABSTRACT FROM AUTHOR]

Published

2024

26. Biomass partitioning of C3- and C4-dominated grasslands in response to climatic variability and climate extremes

Author

Md Lokman Hossain and Jianfeng Li

Subjects

above-ground biomass, below-ground biomass, biomass partitioning, C3- and C4-dominated grasslands, climate extremes, ecoregion, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

The rising temperature, altering precipitation, and increasing extreme events under climate warming affect the stability and sustainability of grassland ecosystems. The dynamics of above-ground biomass (AGB), below-ground biomass (BGB), and biomass partitioning (BGB:AGB ratio) of grasslands are of fundamental importance to understand their feedback to climate change. In this study, we used grassland productivity data extracted from the Oak Ridge National Laboratory Distributed Active Archive Center, Tennessee, USA, in which the AGB was collected within a 1.0 m × 0.25 m quadrat and the BGB was sampled within the center of the quadrat. Using multiple pairwise tests and Pearson’s correlation analysis, we assessed the variations of grassland productivity and examined the response of single-harvest and annual biomass partitioning of C _3 - and C _4 -dominated grasslands to the growing-season and annual climatic variability and climate extremes in seven sites belonging to four ecoregions (i.e. cold steppe, humid temperate, humid savanna, and savanna). The results show that the annual and single-harvest BGB:AGB ratio varied significantly across the plant types and ecoregions. Overall, the C _3 -dominated grasslands exhibited a higher BGB:AGB ratio than that of C _4 -dominated grasslands. Growing-season temperatures (GSTs) were found to be the key determinants in explaining the single-harvest BGB:AGB ratio rather than growing-season precipitation. For instance, the single-harvest BGB:AGB ratio of C _4 -dominated grasslands increased, while that of C _3 -dominated grasslands decreased with elevated GSTs. The growing-season extreme dry climates significantly increased the single-harvest BGB:AGB ratio of C _4 plants by a large reduction of AGB, potentially affecting the ecosystem functioning and stability. The C _3 -dominated grasslands in the cold steppe ecoregion are at great threat of drought-induced stress, as we observed that growing-season extreme dry climates reduced, albeit insignificantly, both the single-harvest AGB and BGB. This study provides key insights into factors influencing the biomass partitioning of C _3 - and C _4 -dominated grasslands and has important implications for assessing the grassland functioning and stability under increasing climate extremes.

Published

2021

27. Variation in fine root biomass along a 1000 km long latitudinal climatic gradient in mixed boreal forests of North-East Europe.

Author

Finér, Leena, Zverev, Vitali, Palviainen, Marjo, Romanis, Tatiana, and Kozlov, Mikhail V.

Subjects

BIOMASS, TAIGAS, NITROGEN content of plants, WEATHER, PLANT communities

Abstract

Highlights • Among-site variation in the total fine root biomass was not explained by latitude. • Fine root density increased in the organic layer towards the north. • The future climate may shift fine roots from the organic layer to the mineral soil. Abstract The geographical patterns in the distribution of fine root biomass (FRB) and in the contribution of fine roots to below-ground nitrogen and carbon stocks are poorly documented. Here, we examined FRB and the ecological factors that govern it, along a 1000 km long latitudinal gradient in unmanaged mixed boreal forests in North-East Europe. We sampled fine roots (diameter ≤2 mm; trees and field layer vegetation combined) twice per growing season in 2015 and 2016 from ten sites spaced one degree of latitude between 60°N (near St. Petersburg) and 69°N (near Murmansk, Russia). We separated living fine roots. The roots were dried and weighed; tissue carbon and nitrogen concentrations were measured. The obtained values were correlated with climatic, plant community and soil characteristics. Among-site variation in the total FRB and carbon and nitrogen concentrations were not explained by latitude or by climatic, plant community or soil characteristics. However, fine root density in the organic layer increased towards the north. The more superficial root system in the north than in the south may indicate a poleward increase in the vulnerability of boreal forests to abiotic risks (forest fires, drought). Our results suggest that the future climate may shift fine roots as well as carbon and nitrogen cycling from the organic layer to mineral soils, thereby increasing the volume of soil utilized by fine roots for water and nutrient uptake. [ABSTRACT FROM AUTHOR]

Published

2019

28. Assessment of the compensation point of Cirsium arvense and effects of competition, root weight and burial depth on below‐ground dry weight – leaf stage trajectories.

Author

Verwijst, T., Tavaziva, V. J., and Lundkvist, A.

Subjects

*CANADA thistle, *WEED control, *LEAF physiology, *AGRONOMY, *BIOMASS energy

Abstract

Summary: Farmers are recommended to employ mechanical control when Cirsium arvense is most sensitive to disturbance. Earlier studies suggest that this occurs at a stage of minimum below‐ground dry weight, coinciding with three to seven or seven to ten leaves per shoot, depending on the definition of below‐ground dry weight. However, some farmers notice better effects when mechanical control is performed at earlier leaf stages. To estimate the compensation point (CP), defined as the minimum weight of the entire below‐ground structure of C. arvense and to further understand links between initial root weight, planting depth and crop competition, three outdoor pot experiments were performed in Sweden in 2013‐2014. We hypothesised that (i) CP likely occurs before C. arvense has developed three leaves, (ii) relative depletion of the below‐ground system at CP is less at lower initial root weight compared with higher weight, and (iii) methodological variations in CP estimations have minor impact on the results. We found that the CP for C. arvense in all treatments occurred before shoots had developed three leaves and that treatment effects were minor (<0.5 leaf stages). Leaf and leaf stage definitions, choice of leaf range and model also had minor effects on CP estimates. Depletion of planted root fragments ceased around leaf stages 3‐4, and their partial replenishment also constitutes evidence for a CP at early leaf stages. For agronomy, our results imply that mechanical control of C. arvense should be performed earlier than previously recommended, probably before reaching an average of three to four leaves per shoot. [ABSTRACT FROM AUTHOR]

Published

2018

29. Species traits and shoot–root biomass allocation in 20 dry-grassland species.

Author

Husáková, Iveta, Weiner, Jacob, and Münzbergová, Zuzana

Subjects

PLANT resource allocation, PLANT biomass, GRASSLANDS, ALLOMETRY in plants, PLANT phylogeny

Abstract

Aims: A plant has a limited amount of resources at any time and it allocates them to different structures. In spite of the large number of previous studies on allocation patterns within single species, knowledge of general patterns in species allocation is still very limited. This is because each study was done in different conditions using different methodology, making generalization difficult. We investigate intraspecific above- versus below-ground biomass allocation among individuals across a spectrum of drygrassland plant species at two different developmental stages and ask whether allocation is age- and species specific, and whether differences among species can be explained by their life-history traits and phylogeny. Methods: We collected data on above- and below-ground biomass of seedlings and adult plants of 20 species from a common garden experiment. We analysed data on shoot–root biomass allocation allometrically and studied the relationship between the allometric exponents (slopes on log–log scale), species life-history traits and phylogenetic distances. Important Findings: We found isometric as well as allometric patterns of biomass allocation in the studied species. Seedlings and adult individuals of more than half of the species differed in their above- versus below-ground biomass allometric exponents. Seedlings and adult individuals of the remaining species differed in their allometric coefficients (intercepts). Annual species generally allocated proportionally more to above- than below-ground biomass as seedlings than as adults, whereas perennial species showed the opposite pattern. Plant lifehistory traits, such as plant life span, age of first flowering, month in which the species begin flowering and specific leaf area were much more important in explaining differences in shoot–root allometry among species than were phylogenetic relationships. This suggests that allocation patterns vary greatly among closely related species but can be predicted based on species life-history traits. [ABSTRACT FROM AUTHOR]

Published

2018

30. Below and above-ground carbon distribution along a rainfall gradient. A case of the Zambezi teak forests, Zambia.

Author

Ngoma, Justine, Moors, Eddy, Kruijt, Bart, Speer, James H., Vinya, Royd, Chidumayo, Emmanuel N., and Leemans, Rik

Subjects

*BIOMASS, *CARBON & the environment, *CLIMATE change, *ALLOMETRY in plants, *RAINFALL, *ECONOMICS

Abstract

Understanding carbon (C) stocks or biomass in forests is important to examine how forests mitigate climate change. To estimate biomass in stems, branches and roots takes intensive fieldwork to uproot, cut and weigh the mass of each component. Different models or equations are also required. Our research focussed on the dry tropical Zambezi teak forests and we studied their structure at three sites following a rainfall gradient in Zambia. We sampled 3558 trees at 42 plots covering a combined area of 15ha. Using data from destructive tree samples, we developed mixed-species biomass models to estimate above ground biomass for small (<5 cm diameter at breast height (DBH, 1.3 m above-ground)) and large (≥5 cm DBH) trees involving 90 and 104 trees respectively, that belonged to 12 species. A below-ground biomass model was developed from seven trees of three species (16–44 cm DBH) whose complete root systems were excavated. Three stump models were also derived from these uprooted trees. Finally, we determined the C fractions from 194 trees that belonged to 12 species. The analysis revealed that DBH was the only predictor that significantly correlated to both above-ground and below-ground biomass. We found a mean root-to-shoot ratio of 0.38:0.62. The C fraction in leaves ranged from 39% to 42%, while it varied between 41% and 46% in wood. The C fraction was highest at the Kabompo site that received the highest rainfall, and lowest at the intermediate Namwala site. The C stocks varied between 15 and 36 ton C ha −1 and these stocks where highest at the wetter Kabompo site and lowest at the drier Sesheke site. Our results indicate that the projected future rainfall decrease for southern Africa, will likely reduce the C storage potential of the Zambezi teak forests, thereby adversely affecting their mitigating role in climate change. [ABSTRACT FROM AUTHOR]

Published

2018

31. Decline in holm oak coppices (Quercus ilex L. subsp. ballota (Desf.) Samp.): biometric and physiological interpretations

Author

Rafael Serrada, Valentín Gómez-Sanz, María J. Aroca, Javier Otero, J. Alfredo Bravo-Fernández, and Sonia Roig

Subjects

decay, stool, above-ground biomass, below-ground biomass, drought, global change, Forestry, SD1-669.5

Abstract

Aim of the study: To analyse the decline in aged holm oak coppice forests as regards above-ground and below-ground fractions and physiological features. Area of study: Centre of the Iberian Peninsula (Guadalajara province). Material and methods: 26 pairs of holm oak stools with different vigour but with similar site and structural characteristics within each pair were selected. Morphological (basal area, number of stools, maximum height) and physiological traits (leaf water potential, stomatal conductance) of the standing stools were assessed. Their aerial and underground parts were extracted and different size fractions of both their above and below-ground biomass were quantified. Linear mixed models were built to test the effect of ’Stool vigour’ on the mean behaviour of the measured variables. Additionally, for the aerial part, linear regressions between the weights of the different size fractions and the basal area at breast height were performed using ‘Stool vigour’ as a fixed factor. Main results: For the same site, root depth, and number and diameter of shoots than good vigour stools, poor vigour stools displayed: lower predawn water potential, greater leaf mass per unit of area; lower total leaf area; lower above-ground biomass (in total as well as per fractions); lower fine roots biomass; lower proportion of leaf biomass and a greater proportion of biomass of both all roots and those with diameter 2-7 cm. Research highlights: The above-ground physiological and morphological characteristics of declined stools are interpreted as poorer adaptation to site conditions. Root system architecture was found to be relevant to explain this behaviour.

Published

2017

32. Effects of sodicity induced changes in soil physical properties on paddy root growth

Author

P.K. Srivastava, M. Gupta, A. Pandey, V. Pandey, N. Singh, and S.K. Tewari

Subjects

below-ground biomass, bulk density, sodic soil, oryza sativa l, Plant culture, SB1-1110

Abstract

A study was conducted to investigate the influence of sodicity induced changes in soil physical properties on paddy root growth in the normal agriculture, semi-reclaimed and sodic soils. The root growth (length, length density, biomass and distribution pattern) were unfavourably affected by the soil physical properties (bulk density, soil aggregate stability, available water content, hydraulic conductivity and soil water retention potential) in the case of sodic soil. The microbial biomass carbon, bacterial, fungal population and dehydrogenase activity showed the lower values in the case of sodosol compared to the normal soil. These soil biological properties tend to sustain paddy root growth in normal and semi-reclaimed soils. Principal component analysis revealed that soil physical properties accounted for 98.2% of total variance in root growth. The study revealed that salt stress induces changes in soil physical properties limiting paddy root growth in the salt affected soils. It is important to reclaim sodosols to alleviate salt induced physical stress for optimum paddy root growth.

Published

2014

33. Moso bamboo ( Phyllostachys pubescens) forests as a significant carbon sink? A case study based on 4-year measurements in central Taiwan.

Author

Lin, Meng-Yin, Hsieh, I-Fang, Lin, Po-Hsuan, Laplace, Sophie, Ohashi, Mizue, Chen, Tsai-Huei, and Kume, Tomonori

Subjects

*PHYLLOSTACHYS pubescens, *FORESTS & forestry, *CARBON cycle, *ECOSYSTEMS

Abstract

The aggressive expansion of Moso bamboo ( Phyllostachys pubescens) forest into adjacent ecosystems which might alter the carbon balance replacement, has been noted recently in East Asian countries such as Taiwan. Moso bamboo has a biennial growth cycle that causes significant inter-annual variations in net primary productivity (NPP) and net ecosystem productivity (NEP). To our knowledge, only one study has investigated NPP covering biennial cycles in a Moso bamboo forest. Therefore, the aim of the present study was to clarify the NPP and NEP in a Moso bamboo forest in Taiwan by considering above- and below-ground processes over a 4-year experimental period. The estimated NPP and NEP showed considerable inter-annual variations (coefficient of variation of 39 and 79%, respectively). Averaged over the 4 years, the NPP and NEP were 8.86 ± 3.46 and 4.32 ± 3.35 Mg C ha year, respectively, which were within the ranges (6.53-14.36 and 3.59-7.98 Mg C ha year, respectively) reported for Moso bamboo forests in East Asian countries. A global comparison of NPP and NEP among forest ecosystems using data from published literature indicated that the estimated NPP and NEP in the present study, as well as those in Moso bamboo forests from East Asian countries, were within the upper range of the values reported for other forest ecosystem. The results indicate that Moso bamboo forests may have high potential as a carbon sink among forests ecosystems. [ABSTRACT FROM AUTHOR]

Published

2017

34. Relationships between below-ground biomass and foliar N:P stoichiometry along climatic and altitudinal gradients of the Chinese grassland transect.

Author

Yu, Hailing, Fan, Jiangwen, Li, Yuzhe, and Harris, Warwick

Subjects

FOLIAR diagnosis, STOICHIOMETRY, BIOMASS, ECOLOGY, GRASSLANDS, SOILS

Abstract

N and P concentrations and their ratios were determined for 132 foliar and 120 below-ground biomass (BGB) samples obtained at 132 sites along the 4500 km Chinese Grassland Transect (CGT) across the Inner Mongolian and Qinghai-Tibet Plateaus. Patterns of foliar and BGB N, P and their ratio (N/P) at the community level were related to altitude, temperature, and precipitation gradients. Also, patterns of relative N and P foliar and BGB concentrations were determined (N, foliar N/BGB N; P, foliar P/BGB P). The relationship between foliar N concentrations and mean annual temperature (MAT) was negative, agreeing with the Temperature-Plant Physiological hypothesis, whereas BGB N decreased with decreasing MAT, supporting the Biogeochemical hypothesis. Patterns of BGB N varying with altitude, MAP and MAT differed from the patterns for leaf N, which may indicate differences in nutrient allocation and utilization by leaves and BGB. N and P may reflect trade-offs by plants for N and P in leaves and BGB. For the entire CGT, N and P increased as altitude increased. N was positively related with MAP but negatively related with MAT, while P showed no correlations with MAP and MAT. Results suggest that ecological stoichiometry at the community level is similar to that at the species level. Strategies of nutrient utilization by leaves and BGB are indicated to be different, and abiotic environmental conditions could influence the stoichiometric characteristics and nutrient allocation to leaves and BGB. [ABSTRACT FROM AUTHOR]

Published

2017

35. Legume Grasslands Promote Precipitation Infiltration better than Gramineous Grasslands in arid Regions.

Author

Huang, Ze, Tian, Fu‐Ping, Wu, Gao‐Lin, Liu, Yu, and Dang, Zhi‐Qiang

Subjects

SOIL infiltration, ARID regions, SOIL moisture, HUMUS, PLANT growth

Abstract

Precipitation infiltration is the most important process for soil water supply of vegetation in the arid regions. Higher infiltration rate is advantageous for vegetation growth and maintenance in the arid areas. Four grassland types ( Medicago sativa, Agropyron cristatum, Caragana korshinskii and Stipa capillata) were selected in this study. Results showed that the infiltration capacity in the legume grasslands was about 30% higher than in the gramineous grasslands and the difference was significant ( p < 0·05). Furthermore, the infiltration rate in legume shrub-grassland was 16% less than the legume grasslands, but the difference was not significant ( p > 0·05). The below-ground biomass, total porosity, capillary porosity, soil organic matters and soil aggregate were the main factors to determine the soil infiltration rates. The capillary porosity and soil aggregate of the top soil presented significant negative effects on soil infiltration rate ( p < 0·05). The below-ground biomass in 10-30 cm soil layer was the most important factor, which significantly and positively correlates with the soil infiltration rate ( p < 0·01). It is possible to conclude that the legume grasslands presented the higher soil infiltration rate and promoted precipitation infiltration in the studied area. And the legume grasslands might be a more suitable option for vegetation restoration from the perspective of soil infiltration and water supply in the arid regions. Copyright © 2016 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2017

36. Ecological biomass allocation strategies in plant species with different life forms in a cold desert, China

Author

Fan, Lianlian, Ding, Junxiang, Ma, Xuexi, and Li, Yaoming

Published

2019

37. Tree root distribution modelling in different environmental conditions.

Author

Perona, Paolo, Flury, Reto, Barry, D. Andrew, and Schwarz, Massimiliano

Subjects

*SOIL moisture, *WATER levels, *SOIL dynamics, *SPATIAL ability, *HYDROLOGY, *TREES

Abstract

The ability to predict the spatial distribution of tree root system variables (e.g., the Root system Area (RA), the maximum root diameter, the number of roots in diameter classes, the density of fine roots, etc.) under different environmental conditions is relevant to several scientific disciplines and to engineering practice. In this work, three well known analytical models from the literature are assembled into a unique framework called the Root Distribution Model (RDM). RDM models the expected vertical and horizontal distribution of coarse and fine root system variables for mature plants growing in different environmental conditions ranging from moderately humid to arid climates. All soil and moisture dynamic parameters are physically based, which make the model straightforward to calibrate via a single tuning parameter. At this investigative stage, it is shown that the model has the flexibility to represent a broad range of situations where soil moisture may result from precipitation inputs or from water level fluctuations due to either the presence of a water coarse or of deep aquifers or both. Accordingly, the distribution of the sectional RA may be either positively or negatively skewed, as well as show a peculiar bi-modal structure. The model can be used to study the impact of changing scenarios affecting precipitation, aquifer and channel hydrology. [Display omitted] • Three models from the literature are joined into a unique mathematical framework (Root Distribution Model). • The model has an analytical form that depends on soil and moisture physically based parameters. • The model reproduces the spatial distribution of tree root system variables over a broad range of environmental conditions. [ABSTRACT FROM AUTHOR]

Published

2022

38. Contrasting effects of nutrient enrichment on below-ground biomass in coastal wetlands.

Author

Graham, Sean A., Mendelssohn, Irving A., and Silliman, Brian

Subjects

*PLANT nutrients, *PLANT-soil relationships, *PLANT fertilization, *PLANT growth, *PLANT biomass, *COASTAL wetlands

Abstract

1. Anthropogenically enhanced nutrient availability is often cited among the most important drivers of altered ecosystem function and loss of services world-wide. Although the above-ground consequences of nutrient enrichment on plant growth patterns are numerous and well documented, belowground impacts are less clear but nonetheless critical from a global change perspective. In coastal wetlands, for example, plant-soil-nutrient dynamics directly affect the capacity to sequester carbon as soil organic matter, keep pace with sea level rise and resist storm-induced erosion. 2. Here, we investigate the effects of excess nutrient loading on below-ground plant growth in an oligohaline marsh fertilized for 7 years with a factorial combination of nitrogen (N) and phosphorus (P). We used two common assessment procedures, the ingrowth and standing crop methods, to simultaneously quantify distinct aspects of below-ground plant growth, which are (i) below-ground biomass accumulation into unexploited open resource space and (ii) in situ, or maintenance, belowground biomass of plants in equilibrium with their environment, respectively. Our objective was to determine if plant growth responses to nutrient enrichment differed depending on process and/or biomass component measured. 3. We show that excess N concurrently increased live root biomass accumulation in ingrowth cores and reduced in situ live root standing crop. Similar, albeit non-significant, response trajectories were apparent for other below-ground biomass pools using both methods, excepting dead biomass and total standing crop. A review of previously published research supports our results and suggests that nutrient enrichment consistently has contrasting effects on below-ground plant growth depending on whether biomass accumulation or standing crop is measured, and that living biomass components are most responsive to enhanced nutrient availability. 4. Synthesis. We conclude that eutrophic conditions can be both beneficial and detrimental to ecosystem function by either stimulating below-ground biomass accumulation in unexploited soil or reducing the below-ground standing crop required to sustain the nutritional needs of established plants in mature communities. Thus, nutrient enrichment may, in the short-term, contribute to soil organic matter (i.e. carbon) accumulation by increasing below-ground growth as plants exploit new resource space. Over the long-term, however, nutrient enrichment has the potential to negatively impact soil organic matter content as plants equilibrate to excess nutrient availability by down-regulating below-ground standing crop. [ABSTRACT FROM AUTHOR]

Published

2016

39. Modelling fine root biomass of boreal tree stands using site and stand variables.

Author

Lehtonen, A., Palviainen, M., Ojanen, P., Kalliokoski, T., Nöjd, P., Kukkola, M., Penttilä, T., Mäkipää, R., Leppälammi-Kujansuu, J., and Helmisaari, H.-S.

Subjects

SCOTS pine, PLANT biomass, PLANT roots, NUTRIENT cycles, PEATLANDS, NORWAY spruce

Abstract

Quantification of fine root biomass is needed for estimating the role of roots as carbon (C) stores and sources of C input into the soil, as well as for modelling of forest nutrient cycling. Due to the laborious nature of root biomass determinations, there is a need to develop indirect methods that would allow fine root biomass to be estimated using data on easily measurable stand and site variables. We developed models for estimating tree fine root (diameter ⩽ 2 mm) biomass of boreal forests by compiling data from 95 Finnish forest stands (55 on upland soils and 40 on drained peatlands). Stand basal area predicted fine root biomass ( R 2 -adj. = 0.35, p < 0.001) better than any other stand variable alone. A model that included stand basal area, dominant tree species group [birch/other], soil type [upland soil/drained peatland], temperature sum and the interaction of soil type and temperature sum accounted for 46% of the variation in fine root biomass. Stand basal area, the C:N ratio of the organic layer or upper 0–20 cm peat layer and the dominant tree species group together explained 45% of the variation in fine root biomass. Temperature sum correlated with fine root biomass in opposite ways in upland soils and in drained peatlands: fine root biomass increased with decreasing temperature sum in upland soil sites, whereas in peatlands fine root biomass decreased as the temperature sum decreased. Although the models were based on a large dataset representing well the variation in stand age, basal area, site fertility and climatic conditions in northern European boreal forests, half of the variation in fine root biomass remained unexplained. More comprehensive fine root biomass sampling in relation to spatial and temporal variation in the forthcoming studies, for example in connection with monitoring campaigns, and additional predictors such as soil texture, successional stage and the fine root biomass of ground vegetation might improve the predictive power of fine root biomass models. [ABSTRACT FROM AUTHOR]

Published

2016

40. Carbon dynamics in an Imperata grassland in Northeast India.

Author

THOKCHOM, AMRABATI and YADAVA, PRATAP S.

Subjects

GRASSLAND soils, GRASSLANDS, CARBON in soils, SOIL temperature, MICROBIAL respiration, CARBON

Abstract

Copyright of Tropical Grasslands / Forrajes Tropicales is the property of International Centre for Tropical Agriculture - CIAT and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2016

41. Carbon stocks in a 50‑year‑old Eucalyptus camaldulensis stand in Sicily, Italy.

Author

Scalenghe, Riccardo, Celi, Luisella, Costa, Giovanna, Laudicina, V Armando, Santoni, Stefania, Vespertino, Dario, and La Mantia, Tommaso

Subjects

EUCALYPTUS, BIOMASS, MYRTACEAE, CARBON foams, HISTOSOLS

Abstract

Eucalyptusstands in semi‑arid areas may contribute to enhance carbon (C) stocks in both biomass and soil. However, the limited information available is mainly focused on short‑rotation plantations. In this study, the above‑ and below‑ground C pools in five 50‑year‑oldEucalyptus camaldulensisDehnh. stands planted on Miocenic evaporitic deposits in Sicily, Italy, with a xeric and thermic pedoclimate, were measured. Above‑ground biomass was determined by partitioning and weighing branches, stem and leaves. Below‑ground C pools included the determination of litter, root biomass, and soil organic and inorganic C.In terms of the above‑ground biomass, theE. camaldulensisstand accumulated on average 116 Mg ha−1 corresponding to 55 Mg C ha−1.Below‑ground biomass consisted mainly of larger roots, followed by fine and medium roots (33 Mg ha−1 corresponding to 14 Mg C ha−1). Litter accumulation on the soil surface accounted for 13 Mg ha−1 corresponding to 5 Mg C ha−1. The amount of C stored in soil was 554 Mg C ha−1, of which 75% was in organic form. AlthoughE. camaldulensisis planted extensively throughout the Southern Hemisphere and tropics where it is managed over short rotations (c. 2–4 years), the results obtained from this study make this species important in terms of future afforestation planning for longer rotations due to its potential to sequester C, particularly in the below‑ground components. [ABSTRACT FROM AUTHOR]

Published

2015

42. Carbon stock of oil palm plantations and tropical forests in Malaysia: A review.

Author

Kho, Lip Khoon and Jepsen, Martin Rudbeck

Subjects

*OIL palm, *PALM oil, *PLANTATIONS, *CARBON, *FOREST ecology

Abstract

In Malaysia, the main land change process is the establishment of oil palm plantations on logged-over forests and areas used for shifting cultivation, which is the traditional farming system. While standing carbon stocks of old-growth forest have been the focus of many studies, this is less the case for Malaysian fallow systems and oil palm plantations. Here, we collate and analyse Malaysian datasets on total carbon stocks for both above- and below-ground biomass. We review the current knowledge on standing carbon stocks of 1) different forest ecosystems, 2) areas subject to shifting cultivation (fallow forests) and 3) oil palm plantations. The forest ecosystems are classified by successional stage and edaphic conditions and represent samples along a forest succession continuum spanning pioneer species in shifting cultivation fallows to climax vegetation in old-growth forests. Total carbon stocks in tropical forests range from 4 to 384 Mg C/ha, significantly wider than the range of total carbon stocks of oil palm plantations, 2 to 60 Mg C/ha. Conversion of old-growth forest areas to oil palm plantations leads to substantial reduction in carbon storage, while conversion of forest fallows to oil palm plantations may sustain or even increase the standing carbon stock. [ABSTRACT FROM AUTHOR]

Published

2015

43. Isometric scaling of above- and below-ground biomass at the individual and community levels in the understorey of a sub-tropical forest.

Author

Dongliang Cheng, Quanlin Zhong, Niklas, Karl J., Yuzhu Ma, Yusheng Yang, and Jianhua Zhang

Abstract

Background and Aims Empirical studies and allometric partitioning (AP) theory indicate that plant above-ground biomass (MA) scales, on average, one-to-one (isometrically) with below-ground biomass (MR) at the level of individual trees and at the level of entire forest communities. However, the ability of the AP theory to predict the biomass allocation patterns of understorey plants has not been established because most previous empirical tests have focused on canopy tree species or very large shrubs. Methods In order to test the AP theory further, 1586 understorey sub-tropical forest plants from 30 sites in southeast China were harvested and examined. The numerical values of the scaling exponents and normalization constants (i.e. slopes and y-intercepts, respectively) of log–log linear MA vs. MR relationships were determined for all individual plants, for each site, across the entire data set, and for data sorted into a total of 19 sub-sets of forest types and successional stages. Similar comparisons of MA/MR were also made. Key Results The data revealed that the mean MA/MR of understorey plants was 2.44 and 1.57 across all 1586 plants and for all communities, respectively, and MA scaled nearly isometrically with respect to MR, with scaling exponents of 1.01 for all individual plants and 0.99 for all communities. The scaling exponents did not differ significantly among different forest types or successional stages, but the normalization constants did, and were positively correlated with MA/MR and negatively correlated with scaling exponents across all 1586 plants. Conclusions The results support the AP theory’s prediction that MA scales nearly one-to-one with MR (i.e. MA α MR ≈1.0) and that plant biomass partitioning for individual plants and at the community level share a strikingly similar pattern, at least for the understorey plants examined in this study. Furthermore, variation in environmental conditions appears to affect the numerical values of normalization constants, but not the scaling exponents of the MA vs. MR relationship. This feature of the results suggests that plant size is the primary driver of the MA vs. MR biomass allocation pattern for understorey plants in sub-tropical forests. [ABSTRACT FROM AUTHOR]

Published

2015

44. Below-ground competition drives the self-thinning process of Stipa purpurea populations in northern Tibet.

Author

Zhu, Juntao, Jiang, Lin, Zhang, Yangjian, Jiang, Yanbin, Tao, Jian, Tian, Li, Zhang, Tao, Xi, Yi, and Pugnaire, Francisco

Subjects

*COMPETITION (Biology), *STIPA, *PERENNIALS, *PLANT population measurement, *PLANT spacing, *EFFECT of stress on plants

Abstract

Questions Above-ground, below-ground and individual mass-density relationships for perennial herbs were examined along a natural precipitation gradient in northern Tibet. We asked: (1) how do the self-thinning exponents respond to variation in precipitation; and (2) what mechanisms drive the observed population self-thinning? Location The alpine grassland of northern Tibet. Methods Forty-seven fenced sites along a precipitation gradient were established and surveyed in 2011 and 2012. Data (geographic coordinates, elevation, and vegetation information) were collected for Stipa purpurea populations at each site. Population self-thinning exponents were estimated using reduced major axis regression. Results The self-thinning exponents for below-ground (−1.27, −0.47) and individual biomass (−1.26, −0.46) increased with increasing mean annual precipitation, but those for above-ground biomass decreased with precipitation (0.18, −0.25). Soil resources (moisture and nutrients) are a more important constraining factor for below-ground components than light is for above-ground components. Root competition for below-ground resources dominated in S. purpurea population self-thinning. The driving force of density regulation changed from above-ground competition to below-ground competition with increased drought stress. Our results indicate that an increased root/shoot ratio was linked to enhanced below-ground competition and weakened above-ground competition. Our study further confirmed the hypothesis that plant populations in different environments exhibit different biomass allocation patterns, which, in turn, leads to different biomass-density relationships. Conclusions Our study revealed the mechanisms of population self-thinning for perennial herbs in the extreme environment of northern Tibet, where below-ground processes play a critical role in regulating population self-thinning. Our study also advances understanding of the interactions between above- and below-ground processes, providing baseline knowledge useful for local grassland management. [ABSTRACT FROM AUTHOR]

Published

2015

45. Allometric equations for estimating tree biomass in restored mixed-species Atlantic Forest stands.

Author

Nogueira Junior, Lauro Rodrigues, Engel, Vera Lex, Parrotta, John A., De Melo, Antonio Carlos Galvão, and Ré, Danilo Scorzoni

Subjects

*ALLOMETRIC equations, *FOREST biomass, *BIODIVERSITY conservation, *FORESTS & forestry

Abstract

Restoration of Atlantic Forests is receiving increasing attention because of its role in both biodiversity conservation and carbon sequestration for global climate change mitigation. This study was carried out in an Atlantic Forest restoration project in the south-central region of São Paulo State - Brazil to develop allometric equations to estimate tree biomass of indigenous tree species in mixed plantations. Above and below-ground biomass (AGB and BGB, respectively), stem diameter (DBH: diameter at 1.3 m height), tree height (H: total height) and specific wood density (WD) were measured for 60 trees of 19 species. Different biomass equations (linear and nonlinear-transformed) were adjusted to estimate AGB and BGB as a function of DBH, H and WD. For estimating AGB and BGB, the linear biomass equation models were the least accurate. The transformed nonlinear biomass equation that used log DBH2, log H and log WD as predictor variables were the most accurate for AGB and the transformed nonlinear biomass equations that used log DBH2*WD as predictor variables were the most accurate for BGB. It is concluded that these adjusted equations can be used to estimate the AGB and BGB in areas of the studied project. The adjusted equations can be recommended for use elsewhere in the region for forest stands of similar age, tree size ranges, species composition and site characteristics. [ABSTRACT FROM AUTHOR]

Published

2014

46. Do Spartina maritima Plantations Enhance the Macroinvertebrate Community in European Salt Marshes?

Author

Curado, Guillermo, Sánchez-Moyano, Juan, Figueroa, Enrique, and Castillo, Jesús

Subjects

SPARTINA, PLANTATIONS, PLANT communities, SALT marshes, ECOLOGICAL restoration monitoring, INVERTEBRATE ecology

Abstract

Ecological restoration of salt marshes using plantations may enhance the macroinvertebrate community, but little is known about the development of benthic macroinvertebrates after ecological engineering projects in European salt marshes. This study analyzed the environment and the macroinvertebrate community in European salt marshes 3 years after restoration using Spartina maritima plantations in comparison with non-restored and preserved marshes in Odiel Marshes (Southwest Iberian Peninsula). We hypothesized that planting Spartina maritima on intertidal mudflats would increase species richness and diversity (Shannon-Weaver index) of the benthic macroinvertebrate community by increasing environmental heterogeneity, providing feeding resources and improving sediments characteristics. Benthic macrofauna samples (composed mainly of annelids, crustaceans, and mollusks) were sampled in plots of 20 cm × 25 cm to 5 cm depth between +1.8 and +3.0 m above Spanish Hydrographic Zero. Sediment organic matter content, bulk density, pH, and redox potential were the variables that best explained macroinvertebrate distribution. Restored marshes achieved similar diversity and even higher specific richness than preserved marshes, although with differences in species composition. Non-restored marshes showed the lowest diversity. Restored and preserved marshes did not differ in total abundance or biomass of macroinvertebrates, both being higher than in non-restored marshes. The macroinvertebrate communities in preserved and non-restored marshes showed the largest difference in taxa composition, with restored marshes occupying an intermediate position. Salt marsh restoration using S. maritima increased the complexity (ecological diversity and species richness) and abundance of the benthic macroinvertebrate community. Our study offers new information about the role of salt marsh plants in mediating faunal communities via ecological engineering projects. [ABSTRACT FROM AUTHOR]

Published

2014

47. Observations of below-ground characteristics of young redwood trees ( Sequoia sempervirens) from two sites in New Zealand - implications for erosion control.

Author

Phillips, Christopher, Marden, Michael, Lambie, Suzanne, Watson, Alex, Ross, Craig, and Fraser, Scott

Subjects

*PINUS radiata, *REDWOOD (Wood), *COAST redwood, *PLANT development, *PLANT growth, *PLANT embryology

Abstract

Aims: Radiata pine ( Pinus radiata D. Don) plantations are widely used to control erosion in New Zealand. However, other species with similar growth but longer rotation lengths and ability to coppice may offer future alternatives to radiata pine. Comparing performance of alternative species to radiata thus becomes important if policy is to be developed to promote them. Methods: The below-ground characteristics (roots) of young redwood ( Sequoia sempervirens (D. Don) Endl.) trees from two established plantations in New Zealand were examined and compared with those of radiata pine, and selected poplar and New Zealand native species. Results: Roots with diameters less than 10 mm comprised over 99 % of total root length in 3-yr-old trees and 98 % of total root length in 4-yr-old trees. For roots greater than 2 mm in diameter, total root length of young redwood trees was greater than that of young radiata pine, poplar and the best performing New Zealand native plant. Total root length at a given root collar diameter for young (1-4 year old) redwood trees was significantly greater than for radiata pine trees. Roots of redwoods were finer and more numerous than for radiata but the below-ground biomass for a given root collar diameter showed no statistical difference between the two species. Conclusions: Redwood, because of its comparable growth rate and the production of many fine lateral roots, has the potential to become a keystone erosion-control species in New Zealand, especially on steep lands where there is an increased risk of post-harvest landsliding associated with moderate to severe rainstorm events. [ABSTRACT FROM AUTHOR]

Published

2013

48. Biomass carbon stocks and their changes in northern China's grasslands during 1982-2006.

Author

Ma, WenHong, Fang, JingYun, Yang, YuanHe, and Mohammat, Anwar

Abstract

Grassland covers approximately one-third of the area of China and plays an important role in the global terrestrial carbon (C) cycle. However, little is known about biomass C stocks and dynamics in these grasslands. During 2001-2005, we conducted five consecutive field sampling campaigns to investigate above-and below-ground biomass for northern China's grasslands. Using measurements obtained from 341 sampling sites, together with a NDVI (normalized difference vegetation index) time series dataset over 1982-2006, we examined changes in biomass C stock during the past 25 years. Our results showed that biomass C stock in northern China's grasslands was estimated at 557.5 Tg C (1 Tg=10 g), with a mean density of 39.5 g C m for above-ground biomass and 244.6 g C m for below-ground biomass. An increasing rate of 0.2 Tg C yr has been observed over the past 25 years, but grassland biomass has not experienced a significant change since the late 1980s. Seasonal rainfall (January-July) was the dominant factor driving temporal dynamics in biomass C stock; however, the responses of grassland biomass to climate variables differed among various grassland types. Biomass in arid grasslands (i.e., desert steppe and typical steppe) was significantly associated with precipitation, while biomass in humid grasslands (i.e., alpine meadow) was positively correlated with mean January-July temperatures. These results suggest that different grassland ecosystems in China may show diverse responses to future climate changes. [ABSTRACT FROM AUTHOR]

Published

2010

49. The effect of grazing pressure on species richness, composition and productivity in North Adriatic Karst pastures.

Author

Škornik, S., Vidrih, M., and Kaligarič, M.

Subjects

*GRAZING, *PLANT diversity, *PASTURES, *PLANT species, *KARST

Abstract

We studied the effects of sheep grazing intensity and abandonment on plant species richness and composition, plant life forms and the productivity of North Adriatic Karst pastures. The experimental sites were under controlled grazing regimes (heavy, moderate, light and abandonment) for 10 years. Data were collected during one season; plant species composition, the number of species and above-ground and below-ground biomass were evaluated. Species richness was significantly reduced with increasing grazing intensity and abandonment. The greatest differences in species composition were recorded for the heavily grazed site owing to the appearance of a group of grasslands species typical of nutrient-rich soil. Heavy grazing increased therophytes and decreased the proportion of chamaephytes and geophytes. Above-ground productivity at the season's peak was typical of subhumid grasslands (up to 500 g m-2) and was significantly the highest in the abandoned pasture. Below-ground biomass was significantly the lowest in the heavily grazed sites and the highest in those that were moderately or lightly grazed. We could conclude that grazing intensification and abandonment have significant effects on the structure of these pastures. Low- or moderate-intensity (4-7 sheep ha-1) grazing seems to be the most appropriate treatment since it can maintain the species richness and typical floristic composition of those pastures. Abbreviations: ANOVA, analysis of variance; DCA, detrended correspondence analysis; HSD, honest significant difference Nomenclature: Martincic et al. (2007) [ABSTRACT FROM AUTHOR]

Published

2010

50. Estimating root biomass in Salix viminalis × Salix schwerinii cultivar “Olof” using the electrical capacitance method.

Author

Pitre, F. E., Brereton, N. J. B., Audoire, S., Richter, G. M., Shield, I., and Karp, A.

Subjects

*PLANT roots, *BIOMASS, *SALIX viminalis, *WILLOWS, *PLANT development

Abstract

Non-destructive assessment of root systems is important in order to understand and optimise the potential of resource capture and allocation by the plant. We studied the relationships between electrical capacitance (EC) and the below- and above-ground biomass of willows. Cuttings of Salix viminalis × Salix schwerinii cv. Olof were maintained in pots and root development was followed up using a portable capacitance meter over the course of 2.5 months. Pot observations were compared with excavation of two-year-old established trees. A strong significant linear relationship (R2 = 0.81, p < 0.001) was obtained between EC and root biomass (dry weight [DW]) for the pot experiment. EC also showed good correlations with stem and leaf biomass, as well as with stem height. In the excavated willow trees, there was a strong logarithmic relationship between EC and root biomass (R2 = 0.66, p < 0.001). These results suggest that EC is a good estimator of below-ground biomass in willow and may become useful in screening varieties for differences in root biomass traits, especially in distinguishing below-ground resource allocation at an early stage. [ABSTRACT FROM AUTHOR]

Published

2010