Your search keyword '"Carbon Sequestration physiology"' showing total 85 results

1. Efficient carbon recycling between calcification and photosynthesis in red coralline algae.

Author

Mao J, Burdett HL, and Kamenos NA

Subjects

Carbon Dioxide metabolism, Carbon Cycle, Carbon Sequestration physiology, Photosynthesis, Rhodophyta physiology, Rhodophyta metabolism, Calcification, Physiologic, Carbon metabolism

Abstract

Red coralline algae create abundant, spatially vast, reef ecosystems throughout our coastal oceans with significant ecosystem service provision, but our understanding of their basic physiology is lacking. In particular, the balance and linkages between carbon-producing and carbon-sequestering processes remain poorly constrained, with significant implications for understanding their role in carbon sequestration and storage. Using dual radioisotope tracing, we provide evidence for coupling between photosynthesis (which requires CO 2 ) and calcification (which releases CO 2 ) in the red coralline alga Boreolithothamnion soriferum (previously Lithothamnion soriferum )-a marine ecosystem engineer widely distributed across Atlantic mid-high latitudes. Of the sequestered HCO 3 - , 38 ± 22% was deposited as carbonate skeleton while 39 ± 14% was incorporated into organic matter via photosynthesis. Only 38 ± 2% of the sequestered HCO 3 - was transformed into CO 2 , and almost 40% of that was internally recycled as photosynthetic substrate, reducing the net release of carbon to 23 ± 3% of the total uptake. The calcification rate was strongly dependent on photosynthetic substrate production, supporting the presence of photosynthetically enhanced calcification. The efficient carbon-recycling physiology reported here suggests that calcifying algae may not contribute as much to marine CO 2 release as is currently assumed, supporting a reassessment of their role in blue carbon accounting.

Published

2024

2. Diagnosing destabilization risk in global land carbon sinks.

Author

Fernández-Martínez M, Peñuelas J, Chevallier F, Ciais P, Obersteiner M, Rödenbeck C, Sardans J, Vicca S, Yang H, Sitch S, Friedlingstein P, Arora VK, Goll DS, Jain AK, Lombardozzi DL, McGuire PC, and Janssens IA

Subjects

Carbon Dioxide analysis, Carbon Dioxide metabolism, Seasons, Atmosphere chemistry, Pacific Ocean, Temperature, Nitrogen metabolism, Risk Assessment, Carbon analysis, Carbon metabolism, Carbon Sequestration physiology, Ecosystem, Plants classification, Plants metabolism, Geographic Mapping, Climate Change

Abstract

Global net land carbon uptake or net biome production (NBP) has increased during recent decades 1 . Whether its temporal variability and autocorrelation have changed during this period, however, remains elusive, even though an increase in both could indicate an increased potential for a destabilized carbon sink 2,3 . Here, we investigate the trends and controls of net terrestrial carbon uptake and its temporal variability and autocorrelation from 1981 to 2018 using two atmospheric-inversion models, the amplitude of the seasonal cycle of atmospheric CO 2 concentration derived from nine monitoring stations distributed across the Pacific Ocean and dynamic global vegetation models. We find that annual NBP and its interdecadal variability increased globally whereas temporal autocorrelation decreased. We observe a separation of regions characterized by increasingly variable NBP, associated with warm regions and increasingly variable temperatures, lower and weaker positive trends in NBP and regions where NBP became stronger and less variable. Plant species richness presented a concave-down parabolic spatial relationship with NBP and its variability at the global scale whereas nitrogen deposition generally increased NBP. Increasing temperature and its increasing variability appear as the most important drivers of declining and increasingly variable NBP. Our results show increasing variability of NBP regionally that can be mostly attributed to climate change and that may point to destabilization of the coupled carbon-climate system., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

3. PDAT regulates PE as transient carbon sink alternative to triacylglycerol in Nannochloropsis.

Author

Yang J, Liu J, Pan Y, Maréchal E, Amato A, Liu M, Gong Y, Li Y, and Hu H

Subjects

Carbon Dioxide metabolism, Carbon Sequestration genetics, Carbon Sequestration physiology, Diacylglycerol O-Acyltransferase metabolism, Plants metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Triglycerides genetics, Triglycerides metabolism, Acyltransferases genetics, Acyltransferases metabolism, Microalgae genetics, Microalgae metabolism, Phosphatidylethanolamines genetics, Phosphatidylethanolamines metabolism

Abstract

Triacylglycerols (TAGs) are the main storage lipids in photosynthetic organisms under stress. In the oleaginous alga Nannochloropsis oceanica, while multiple acyl CoA:diacylglycerol (DAG) acyltransferases (NoDGATs) are involved in TAG production, the role of the unique phospholipid:DAG acyltransferase (NoPDAT) remains unknown. Here, we performed a functional complementation assay in TAG-deficient yeast (Saccharomyces cerevisiae) and an in vitro assay to probe the acyltransferase activity of NoPDAT. Subcellular localization, overexpression, and knockdown (KD) experiments were also conducted to elucidate the role of NoPDAT in N. oceanica. NoPDAT, residing at the outermost plastid membrane, does not phylogenetically fall into the clades of algae or plants and uses phosphatidylethanolamine (PE) and phosphatidylglycerol with 16:0, 16:1, and 18:1 at position sn-2 as acyl-donors in vivo. NoPDAT KD, not triggering any compensatory mechanism via DGATs, led to an ∼30% decrease of TAG content, accompanied by a vast accumulation of PEs rich in 16:0, 16:1, and 18:1 fatty acids (referred to as "LU-PE") that was positively associated with CO2 availability. We conclude that the NoPDAT pathway is parallel to and independent of the NoDGAT pathway for oil production. LU-PE can serve as an alternative carbon sink for photosynthetically assimilated carbon in N. oceanica when PDAT-mediated TAG biosynthesis is compromised or under stress in the presence of high CO2 levels., (© American Society of Plant Biologists 2022. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2022

4. Retention of deposited ammonium and nitrate and its impact on the global forest carbon sink.

Author

Gurmesa GA, Wang A, Li S, Peng S, de Vries W, Gundersen P, Ciais P, Phillips OL, Hobbie EA, Zhu W, Nadelhoffer K, Xi Y, Bai E, Sun T, Chen D, Zhou W, Zhang Y, Guo Y, Zhu J, Duan L, Li D, Koba K, Du E, Zhou G, Han X, Han S, and Fang Y

Subjects

Environment, Nitrogen Isotopes chemistry, Nitrogen Oxides analysis, Soil chemistry, Ammonium Compounds analysis, Carbon Sequestration physiology, Environmental Restoration and Remediation, Forests, Nitrates analysis, Trees metabolism

Abstract

The impacts of enhanced nitrogen (N) deposition on the global forest carbon (C) sink and other ecosystem services may depend on whether N is deposited in reduced (mainly as ammonium) or oxidized forms (mainly as nitrate) and the subsequent fate of each. However, the fates of the two key reactive N forms and their contributions to forest C sinks are unclear. Here, we analyze results from 13 ecosystem-scale paired 15 N-labelling experiments in temperate, subtropical, and tropical forests. Results show that total ecosystem N retention is similar for ammonium and nitrate, but plants take up more labelled nitrate ([Formula: see text]%) ([Formula: see text]) than ammonium ([Formula: see text]%) while soils retain more ammonium ([Formula: see text]%) than nitrate ([Formula: see text]%). We estimate that the N deposition-induced C sink in forests in the 2010s  is [Formula: see text] Pg C yr -1 , higher than previous estimates because of a larger role for oxidized N and greater rates of global N deposition., (© 2022. The Author(s).)

Published

2022

5. Incorporation of uncertainty to improve projections of tidal wetland elevation and carbon accumulation with sea-level rise.

Author

Buffington KJ, Janousek CN, Dugger BD, Callaway JC, Schile-Beers LM, Borgnis Sloane E, and Thorne KM

Subjects

Bays, Models, Theoretical, Salinity, San Francisco, Soil chemistry, Tidal Waves, Carbon analysis, Carbon Sequestration physiology, Global Warming statistics & numerical data, Sea Level Rise statistics & numerical data, Wetlands

Abstract

Understanding the rates and patterns of tidal wetland elevation changes relative to sea-level is essential for understanding the extent of potential wetland loss over the coming years. Using an enhanced and more flexible modeling framework of an ecosystem model (WARMER-2), we explored sea-level rise (SLR) impacts on wetland elevations and carbon sequestration rates through 2100 by considering plant community transitions, salinity effects on productivity, and changes in sediment availability. We incorporated local experimental results for plant productivity relative to inundation and salinity into a species transition model, as well as site-level estimates of organic matter decomposition. The revised modeling framework includes an improved calibration scheme that more accurately reconstructs soil profiles and incorporates parameter uncertainty through Monte Carlo simulations. Using WARMER-2, we evaluated elevation change in three tidal wetlands in the San Francisco Bay Estuary, CA, USA along an estuarine tidal and salinity gradient with varying scenarios of SLR, salinization, and changes in sediment availability. We also tested the sensitivity of marsh elevation and carbon accumulation rates to different plant productivity functions. Wetland elevation at all three sites was sensitive to changes in sediment availability, but sites with greater initial elevations or space for upland transgression persisted longer under higher SLR rates than sites at lower elevations. Using a multi-species wetland vegetation transition model for organic matter contribution to accretion, WARMER-2 projected increased elevations relative to sea levels (resilience) and higher rates of carbon accumulation when compared with projections assuming no future change in vegetation with SLR. A threshold analysis revealed that all three wetland sites were likely to eventually transition to an unvegetated state with SLR rates above 7 mm/yr. Our results show the utility in incorporating additional estuary-specific parameters to bolster confidence in model projections. The new WARMER-2 modeling framework is widely applicable to other tidal wetland ecosystems and can assist in teasing apart important drivers of wetland elevation change under SLR., Competing Interests: Appointment funding for one author (LSB) comes from Silvestrum Climate Associates, a commercial source. This does not alter the authors’ adherence to all the PLoS ONE policies on sharing data and materials. Authors declare no other competing interests exist.

Published

2021

6. Opinion: We need biosphere stewardship that protects carbon sinks and builds resilience.

Author

Rockström J, Beringer T, Hole D, Griscom B, Mascia MB, Folke C, and Creutzig F

Subjects

Carbon, Climate, Climate Change, Conservation of Natural Resources trends, Earth, Planet, Ecosystem, Carbon Sequestration physiology, Conservation of Natural Resources methods

Abstract

Competing Interests: The authors declare no competing interest. D.H. and M.B.M. were supported by a grant from Gordon and Betty Moore to Conservation International. B.G. was supported by the Lui-Walton Innovators Fellowship program.

Published

2021

7. The decomposition process and nutrient release of invasive plant litter regulated by nutrient enrichment and water level change.

Author

Yang R, Dong J, Li C, Wang L, Quan Q, and Liu J

Subjects

Carbon metabolism, Carbon Sequestration physiology, Ecosystem, Introduced Species, Nitrogen metabolism, Phosphorus metabolism, Wetlands, Nutrients metabolism, Poaceae metabolism, Water metabolism

Abstract

Wetlands are vulnerable to plant invasions and the decomposition of invasive plant litter could make impacts on the ecosystem services of wetlands including nutrient cycle and carbon sequestration. However, few studies have explored the effects of nutrient enrichment and water level change on the decomposition of invasive plant litter. In this study, we conducted a control experiment using the litterbag method to compare the decomposition rates and nutrient release in the litter of an invasive plant Alternanthera philoxeroides in three water levels and two nutrient enrichment treatments. This study found that the water level change and nutrient enrichment showed significant effects on the litter decomposition and nutrient dynamic of A. philoxeroides. The increase of water level significantly reduced the decomposition rate and nutrient release of litter in the nutrient control treatment, whereas no clear relationship was observed in the nutrient enrichment treatment, indicating that the effect of water level change on litter decomposition might be affected by nutrient enrichment. At the late stage of decomposition, the increase of phosphorus (P) concentration and the decrease of the ratio of carbon to P suggested that the decomposition of invasive plant litter was limited by P. Our results suggest that controlling P enrichment in water bodies is essential for the management of invasive plant and carbon sequestration of wetlands. In addition, the new index we proposed could provide a basis for quantifying the impact of invasive plant litter decomposition on carbon cycle in wetlands., Competing Interests: The authors have declared that no competing interests exist.

Published

2021

8. Nitrogen deposition accelerates soil carbon sequestration in tropical forests.

Author

Lu X, Vitousek PM, Mao Q, Gilliam FS, Luo Y, Turner BL, Zhou G, and Mo J

Subjects

Carbon chemistry, Climate Change, Ecosystem, Forests, Nitrogen chemistry, Rainforest, Soil Microbiology, Trees growth & development, Tropical Climate, Carbon Sequestration physiology, Nitrogen metabolism, Soil chemistry

Abstract

Terrestrial ecosystem carbon (C) sequestration plays an important role in ameliorating global climate change. While tropical forests exert a disproportionately large influence on global C cycling, there remains an open question on changes in below-ground soil C stocks with global increases in nitrogen (N) deposition, because N supply often does not constrain the growth of tropical forests. We quantified soil C sequestration through more than a decade of continuous N addition experiment in an N-rich primary tropical forest. Results showed that long-term N additions increased soil C stocks by 7 to 21%, mainly arising from decreased C output fluxes and physical protection mechanisms without changes in the chemical composition of organic matter. A meta-analysis further verified that soil C sequestration induced by excess N inputs is a general phenomenon in tropical forests. Notably, soil N sequestration can keep pace with soil C, based on consistent C/N ratios under N additions. These findings provide empirical evidence that below-ground C sequestration can be stimulated in mature tropical forests under excess N deposition, which has important implications for predicting future terrestrial sinks for both elevated anthropogenic CO 2 and N deposition. We further developed a conceptual model hypothesis depicting how soil C sequestration happens under chronic N deposition in N-limited and N-rich ecosystems, suggesting a direction to incorporate N deposition and N cycling into terrestrial C cycle models to improve the predictability on C sink strength as enhanced N deposition spreads from temperate into tropical systems., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

9. Mature Andean forests as globally important carbon sinks and future carbon refuges.

Author

Duque A, Peña MA, Cuesta F, González-Caro S, Kennedy P, Phillips OL, Calderón-Loor M, Blundo C, Carilla J, Cayola L, Farfán-Ríos W, Fuentes A, Grau R, Homeier J, Loza-Rivera MI, Malhi Y, Malizia A, Malizia L, Martínez-Villa JA, Myers JA, Osinaga-Acosta O, Peralvo M, Pinto E, Saatchi S, Silman M, Tello JS, Terán-Valdez A, and Feeley KJ

Subjects

Biomass, Forests, South America, Tropical Climate, Carbon metabolism, Carbon Sequestration physiology, Climate Change, Conservation of Natural Resources, Trees metabolism

Abstract

It is largely unknown how South America's Andean forests affect the global carbon cycle, and thus regulate climate change. Here, we measure aboveground carbon dynamics over the past two decades in 119 monitoring plots spanning a range of >3000 m elevation across the subtropical and tropical Andes. Our results show that Andean forests act as strong sinks for aboveground carbon (0.67 ± 0.08 Mg C ha -1 y -1 ) and have a high potential to serve as future carbon refuges. Aboveground carbon dynamics of Andean forests are driven by abiotic and biotic factors, such as climate and size-dependent mortality of trees. The increasing aboveground carbon stocks offset the estimated C emissions due to deforestation between 2003 and 2014, resulting in a net total uptake of 0.027 Pg C y -1 . Reducing deforestation will increase Andean aboveground carbon stocks, facilitate upward species migrations, and allow for recovery of biomass losses due to climate change.

Published

2021

10. Combining organic and mineral fertilizers as a climate-smart integrated soil fertility management practice in sub-Saharan Africa: A meta-analysis.

Author

Gram G, Roobroeck D, Pypers P, Six J, Merckx R, and Vanlauwe B

Subjects

Africa South of the Sahara, Carbon analysis, Carbon Sequestration physiology, Manure analysis, Minerals, Nitrogen analysis, Phosphorus, Triticum, Zea mays metabolism, Agriculture methods, Fertilizers analysis, Soil chemistry

Abstract

Low productivity and climate change require climate-smart agriculture (CSA) for sub-Saharan Africa (SSA), through (i) sustainably increasing crop productivity, (ii) enhancing the resilience of agricultural systems, and (iii) offsetting greenhouse gas emissions. We conducted a meta-analysis on experimental data to evaluate the contributions of combining organic and mineral nitrogen (N) applications to the three pillars of CSA for maize (Zea mays). Linear mixed effect modeling was carried out for; (i) grain productivity and agronomic efficiency of N (AE) inputs, (ii) inter-seasonal yield variability, and (iii) changes in soil organic carbon (SOC) content, while accounting for the quality of organic amendments and total N rates. Results showed that combined application of mineral and organic fertilizers leads to greater responses in productivity and AE as compared to sole applications when more than 100 kg N ha-1 is used with high-quality organic matter. For yield variability and SOC, no significant interactions were found when combining mineral and organic fertilizers. The variability of maize yields in soils amended with high-quality organic matter, except manure, was equal or smaller than for sole mineral fertilizer. Increases of SOC were only significant for organic inputs, and more pronounced for high-quality resources. For example, at a total N rate of 150 kg N ha-1 season-1, combining mineral fertilizer with the highest quality organic resources (50:50) increased AE by 20% and reduced SOC losses by 18% over 7 growing seasons as compared to sole mineral fertilizer. We conclude that combining organic and mineral N fertilizers can have significant positive effects on productivity and AE, but only improves the other two CSA pillars yield variability and SOC depending on organic resource input and quality. The findings of our meta-analysis help to tailor a climate smart integrated soil fertility management in SSA., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

11. The relationship between bacterial diversity and organic carbon mineralization in soft rock and sand compound soil.

Author

Guo Z, Li J, Ge L, Yang C, and Han J

Subjects

Actinobacteria classification, Actinobacteria metabolism, Bacteria classification, Biodiversity, Chloroflexi classification, Chloroflexi metabolism, Firmicutes classification, Firmicutes metabolism, Microbiota, Organic Chemicals chemistry, Proteobacteria classification, Proteobacteria metabolism, RNA, Ribosomal, 16S genetics, Soil Microbiology, Bacteria metabolism, Carbon Sequestration physiology, Organic Chemicals analysis, Soil chemistry

Abstract

The soil organic carbon (SOC) mineralization rate in sandy soil plays an important role in improving soil quality, and a research is needed to determine management practices that optimize the mineralization rate. When sandy soil is improved by adding soft rock, the specific promotion process of bacterium to SOC mineralization remain unclear. To investigate these mechanisms, we selected four treatments with soft rock to sand volume ratios of 0:1 (CK), 1:5 (C1), 1:2 (C2) and 1:1 (C3) to study. The mineralization rate of organic carbon was measured using the lye absorption method. High-throughput sequencing and scanning electron microscopy were used to determine the bacterial community structure and soil microstructure, respectively. The results showed that the organic carbon content of the sandy soil increased significantly (182.22-276.43%) after using the soft rock treatments. The SOC mineralization rate could be divided into two stages: a rapid decline during days 1-8 and a slow decline during days 8-60. With increased incubation time, the intensity of the cumulative release of organic carbon gradually weakened. Compared with the CK treatment, the SOC mineralization accumulation (Ct) and the potential mineralizable organic carbon content (C 0 ) in the C1, C2, and C3 treatments increased significantly, by 106.98-225.94% and 112.22-254.08%, respectively. The cumulative mineralization rate (Cr) was 18.11% and 21.38% smaller with treatments C2 and C3, respectively. The SOC mineralization rate constant (k) decreased significantly after the addition of soft rock, while the half-turnover period (Th) changed inversely with k. Compared with the CK treatment, the number of gene copies of the soil bacteria increased by 15.38-272.53% after adding soft rock, with the most significant increase in treatment C3. The bacterial diversity index also increased significantly under treatment C3. The three dominant bacteria were Proteobacteria, Actinobacteria, and Chloroflexi. The correlation between C r and one of the non-dominant bacteria, Firmicutes, was large, and the bacteria had a significant positive correlation with k. At the same time, the abundance of Firmicutes under treatments C2 and C3 was small. As the proportion of soft rock increased, the soil particles changed from point contact to surface contact, and the adhesion on the surface of the particles gradually increased. Results from this study show that the retention time of SOC can be increased and the carbon sequestration effect is better when the ratio of soft rock to sand is set to 1:2.

Published

2020

12. Perennial vegetables: A neglected resource for biodiversity, carbon sequestration, and nutrition.

Author

Toensmeier E, Ferguson R, and Mehra M

Subjects

Biodiversity, Carbon metabolism, Climate Change, Crops, Agricultural chemistry, Crops, Agricultural metabolism, Food Supply, Nutrients analysis, Nutrients metabolism, Nutritional Status physiology, Agriculture methods, Carbon Sequestration physiology, Vegetables metabolism

Abstract

Perennial vegetables are a neglected and underutilized class of crops with potential to address 21st century challenges. They represent 33-56% of cultivated vegetable species, and occupy 6% of world vegetable cropland. Despite their distinct relevance to climate change mitigation and nutritional security, perennial vegetables receive little attention in the scientific literature. Compared to widely grown and marketed vegetable crops, many perennial vegetables show higher levels of key nutrients needed to address deficiencies. Trees with edible leaves are the group of vegetables with the highest levels of these key nutrients. Individual "multi-nutrient" species are identified with very high levels of multiple nutrients for addressing deficiencies. This paper reports on the synthesis and meta-analysis of a heretofore fragmented global literature on 613 cultivated perennial vegetables, representing 107 botanical families from every inhabited continent, in order to characterize the extent and potential of this class of crops. Carbon sequestration potential from new adoption of perennial vegetables is estimated at 22.7-280.6 MMT CO2-eq/yr on 4.6-26.4 Mha by 2050., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

13. Interannual and seasonal variations in carbon exchanges over an alpine meadow in the northeastern edge of the Qinghai-Tibet Plateau, China.

Author

Wu J, Wu H, Ding Y, Qin J, Li H, Liu S, and Zeng D

Subjects

Carbon Dioxide analysis, Carbon Sequestration physiology, China, Ecosystem, Humans, Rivers chemistry, Seasons, Soil chemistry, Temperature, Tibet, Time Factors, Carbon pharmacokinetics, Carbon Cycle physiology, Climate Change, Grassland

Abstract

The alpine meadow is highly sensitive to global climate change due to its high elevation and cold environment. To understand the dynamics of ecosystem carbon cycling, CO2 fluxes were measured over the Suli alpine meadow, which is located at the upper reach of the Shule River basin at the northeastern edge of the Qinghai-Tibet Plateau (QTP), China. The measurements were taken from October 2008 to September 2012 using the eddy covariance technique. Obvious seasonal and inter-annual variations were observed in the CO2 flux. The annual net carbon exchange ranged from -195.28 g·CO2·m-2 to -118.49 g·CO2·m-2, indicating that the alpine meadow ecosystem in this area played a role as a carbon sink. The inter-annual variability in the net carbon exchange was significantly related to the length of the growing season for the alpine meadow. The results showed that the months of June, July and August were the strongest CO2 absorption periods, while April, May and October were the strongest CO2 release periods. The annual net exchanges of CO2 in the four years were -118.49 g·CO2·m-2, -130.75 g·CO2·m-2, -195.83 g·CO2·m-2 and -160.65 g·CO2·m-2, and the average value was -151.43 g·CO2·m-2. On a seasonal scale, the monthly CO2 fluxes were largely controlled by temperature. At the annual scale, there was no dominant factor that influenced the interannual variations in the CO2 flux., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

14. Pervasive decreases in living vegetation carbon turnover time across forest climate zones.

Author

Yu K, Smith WK, Trugman AT, Condit R, Hubbell SP, Sardans J, Peng C, Zhu K, Peñuelas J, Cailleret M, Levanic T, Gessler A, Schaub M, Ferretti M, and Anderegg WRL

Subjects

Atmosphere analysis, Carbon Dioxide analysis, Climate Change, Ecology statistics & numerical data, Environmental Monitoring statistics & numerical data, Spatio-Temporal Analysis, Temperature, Uncertainty, Carbon Sequestration physiology, Ecology methods, Forests, Models, Theoretical, Trees physiology

Abstract

Forests play a major role in the global carbon cycle. Previous studies on the capacity of forests to sequester atmospheric CO 2 have mostly focused on carbon uptake, but the roles of carbon turnover time and its spatiotemporal changes remain poorly understood. Here, we used long-term inventory data (1955 to 2018) from 695 mature forest plots to quantify temporal trends in living vegetation carbon turnover time across tropical, temperate, and cold climate zones, and compared plot data to 8 Earth system models (ESMs). Long-term plots consistently showed decreases in living vegetation carbon turnover time, likely driven by increased tree mortality across all major climate zones. Changes in living vegetation carbon turnover time were negatively correlated with CO 2 enrichment in both forest plot data and ESM simulations. However, plot-based correlations between living vegetation carbon turnover time and climate drivers such as precipitation and temperature diverged from those of ESM simulations. Our analyses suggest that forest carbon sinks are likely to be constrained by a decrease in living vegetation carbon turnover time, and accurate projections of forest carbon sink dynamics will require an improved representation of tree mortality processes and their sensitivity to climate in ESMs., Competing Interests: The authors declare no competing interest., (Copyright © 2019 the Author(s). Published by PNAS.)

Published

2019

15. Blue Growth Potential to Mitigate Climate Change through Seaweed Offsetting.

Author

Froehlich HE, Afflerbach JC, Frazier M, and Halpern BS

Subjects

Agriculture, Carbon, Climate Change, Conservation of Natural Resources, Seaweed growth & development, Aquaculture methods, Carbon Sequestration physiology, Seaweed metabolism

Abstract

Carbon offsetting-receiving credit for reducing, avoiding, or sequestering carbon-has become part of the portfolio of solutions to mitigate carbon emissions, and thus climate change, through policy and voluntary markets, primarily by land-based re- or afforestation and preservation [1, 2]. However, land is limiting, creating interest in a rapidly growing aquatic farming sector of seaweed aquaculture [3-5]. Synthesizing data from scientific literature, we assess the extent and cost of scaling seaweed aquaculture to provide sufficient CO 2 eq sequestration for several climate change mitigation scenarios, with a focus on the food sector-a major source of greenhouse gases [6]. Given known ecological constraints (nutrients and temperature), we found a substantial suitable area (ca. 48 million km 2 ) for seaweed farming, which is largely unfarmed. Within its own industry, seaweed could create a carbon-neutral aquaculture sector with just 14% (mean = 25%) of current seaweed production (0.001% of suitable area). At a much larger scale, we find seaweed culturing extremely unlikely to offset global agriculture, in part due to production growth and cost constraints. Yet offsetting agriculture appears more feasible at a regional level, especially areas with strong climate policy, such as California (0.065% of suitable area). Importantly, seaweed farming can provide other benefits to coastlines affected by eutrophic, hypoxic, and/or acidic conditions [7, 8], creating opportunities for seaweed farming to act as "charismatic carbon" that serves multiple purposes. Seaweed offsetting is not the sole solution to climate change, but it provides an invaluable new tool for a more sustainable future., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

16. Detailed global modelling of soil organic carbon in cropland, grassland and forest soils.

Author

Morais TG, Teixeira RFM, and Domingos T

Subjects

Agriculture methods, Carbon Sequestration physiology, Climate, Forests, Grassland, Carbon chemistry, Crops, Agricultural chemistry, Soil chemistry

Abstract

Assessments of the global carbon (C) cycle typically rely on simplified models which consider large areas as homogeneous in terms of the response of soils to land use or consider very broad land classes. For example, "cropland" is typically modelled as an aggregation of distinct practices and individual crops over large regions. Here, we use the process-based Rothamsted soil Carbon Model (RothC model), which has a history of being successfully applied at a global scale, to calculate attainable SOC stocks and C mineralization rates for each of c. 17,000 regions (combination of soil type and texture, climate type, initial land use and country) in the World, under near-past climate conditions. We considered 28 individual crops and, for each, multiple production practices, plus 16 forest types and 1 grassland class (total of 80 classes). We find that conversion to cropland can result in SOC increases, particularly when the soil remains covered with crop residues (an average gain of 12 t C/ha) or using irrigation (4 t C/ha), which are mutually reinforcing effects. Attainable SOC stocks vary significantly depending on the land use class, particularly for cropland. Common aggregations in global modelling of a single agricultural class would be inaccurate representations of these results. Attainable SOC stocks obtained here were compared to long-term experiment data and are well aligned with the literature. Our results provide a regional and detailed understanding of C sequestration that will also enable better greenhouse gas reporting at national level as alternatives to IPCC tier 2 defaults., Competing Interests: The authors have declared that no competing interests exist.

Published

2019

17. Rapid Sequestration of Ecosystem Carbon in 30-year Reforestation with Mixed Species in Dry Hot Valley of the Jinsha River.

Author

Gong Z, Tang Y, Xu W, and Mou Z

Subjects

Biomass, China, Rivers, Trees, Carbon analysis, Carbon Sequestration physiology, Ecosystem, Forests, Soil chemistry

Abstract

Reforestation plays an important role in the carbon cycle and climate change. However, knowledge of ecosystem carbon sequestration through reforestation with mixed species is limited. Especially in dry hot valley of the Jinsha River, no studies cover total ecosystem carbon sequestration level in mature mixed plantations for a limited area of mixed plantations and difficulty in the sampling of plant roots and deep soil. In this study, carbon sequestration of seven mixed plantations of different ages in dry hot valley of the Jinsha River was investigated with analogous sites method. The results are as follows: 1) Deep soil organic carbon (SOC) storage significantly increased with stand age ( p = 0.025), possibly due to fine root exudates and dissolved organic carbon transportation into deep soil and retention. 2) Total biomass carbon storage in the 30-year-old mixed plantation was 77.78 t C ha -1 , 54 times reference wasteland and 9 times reference natural recovery shrub-grassland. However, total biomass carbon storage of 30-year-old mixed plantation was insignificantly lower than that of reference natural forest ( p = 0.429). After 30 years of reforestation, plantation biomass carbon storage recovered to reference level, and its sequestration rate was 2.54 t C ha -1 yr -1 . 3) The total ecosystem carbon storage of 30-year-old mixed plantation was 185.50 t C ha -1 , 2.38 times reference wasteland, 2.29 times reference natural recovery shrub grassland, and 29% lower than reference natural forest. It indicated that niche complementary, good stand structure, and characteristics of dominant species Leucaena leucocephala in mixed plantations facilitate more rapid carbon sequestration, especially biomass carbon in the dry hot valley.

Published

2019

18. Restoring natural forests is the best way to remove atmospheric carbon.

Author

Lewis SL, Wheeler CE, Mitchard ETA, and Koch A

Subjects

Carbon Dioxide analysis, Carbon Dioxide metabolism, Environmental Policy trends, Forestry legislation & jurisprudence, Forestry methods, Forestry statistics & numerical data, Global Warming legislation & jurisprudence, Global Warming statistics & numerical data, International Cooperation, Sustainable Development legislation & jurisprudence, Time Factors, Atmosphere chemistry, Carbon Dioxide isolation & purification, Carbon Sequestration physiology, Forestry trends, Forests, Global Warming prevention & control, Sustainable Development trends, Trees metabolism

Published

2019

19. Comparative analyses of different biogenic CO 2 emission accounting systems in life cycle assessment.

Author

Liu W, Zhu Q, Zhou X, and Peng C

Subjects

Biomass, Carbon Dioxide analysis, Carbon Sequestration physiology, Climate Change, Life Cycle Stages physiology, Models, Theoretical, Plant Development physiology

Abstract

The biomass-derived CO 2 emission is usually treated as neutral to climate change. However, due to the stay of biomass-derived CO 2 in the atmosphere, many researchers believe that biomass-derived CO 2 also has climate change benefit. Therefore, many methods to account the global warming potential of biomass-derived CO 2 (GWP bio ) were proposed. Based on those new methods, we developed an accounting system for climate change impact of biomass utilization in this study, and compared it with the conventional accounting system which follows the carbon neutral assumption. A case study of caragana-to-pellet bioenergy production system was simulated to test the performance of the GWP bio accounting system. The CENTURY model was used to simulate carbon dynamics of caragana plantation in the Loess Plateau in China, and life cycle assessment (LCA) model was developed to estimate the life cycle emissions of the caragana-to-pellet system. Attributed to short rotation of caragana plantation and fast biomass accumulation after harvest, the GWP bio values around 0.044 were obtained. When the GWP bio was applied to LCA, significant high life cycle CO 2 emission was found in comparison to the conventional method. However, the GWP bio accounting system has lower positive climate change impact than the conventional accounting system in assessing the overall impact of biomass utilization. This indicated that the application of GWP bio accounting system would encourage the utilization of biomass and allow a fair comparison with fossil fuels. In the sensitivity analysis, we found the accounting system was sensitive to biomass accumulation and all the corresponding factor affecting biomass accumulation., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2019

20. Variations in carbon source-sink relationships in subalpine fir across elevational gradients.

Author

Shi H, Zhou Q, Liu X, Xie F, Li T, Zhang Q, and Dang H

Subjects

Analysis of Variance, Carbohydrates analysis, China, Seasons, Time Factors, Altitude, Carbon Sequestration physiology, Ecosystem, Picea physiology

Abstract

Cold-adapted trees display acclimation in both carbon source and carbon sink capacity to low-temperature stress at their upper elevational range limits. Hence a balanced carbon source-sink capacity might be required for their persistence and survival at the elevational tree limits. The present study examined the spatial dynamics of carbon source-sink relationship in subalpine fir (Abies fargesii) trees along elevational gradients in the northern slope of the temperate region and in the southern slope of the subtropics in terms of climate in the Qinling Mountain range, north-central China. The results showed that non-structural carbohydrate (NSC) concentrations in both the source and sink tissues increased with the increase in elevation. The ratio of carbon source-sink displayed a consistent decreasing trend with the increase in elevation and during growing season, showing that it was lowest at a ratio of 2.93 in the northern slope and at a ratio of 2.61 in the southern slope at the upper distribution elevations in the late growing season. Such variations of carbon source-sink ratio might be attributable to the balance between carbon source and sink activities, which changed seasonally across the elevational distribution range. We concluded that a ratio of carbon source-sink of at least 2.6 might be essential for subalpine fir trees to persist at their upper range limits. Therefore, a sufficient source-sink ratio and a balanced source-sink relationship might be required for subalpine fir trees to survive and develop at their upper elevational distribution limits., (© 2018 German Society for Plant Sciences and The Royal Botanical Society of the Netherlands.)

Published

2019

21. Natural forests exhibit higher carbon sequestration and lower water consumption than planted forests in China.

Author

Yu Z, Liu S, Wang J, Wei X, Schuler J, Sun P, Harper R, and Zegre N

Subjects

Carbon analysis, China, Climate Change, Environmental Monitoring, Carbon Sequestration physiology, Forests, Trees growth & development, Trees metabolism, Water metabolism

Abstract

Large-scale planted forests (PF) have been given a higher priority in China for improving the environment and mitigating climate change relative to natural forests (NF). However, the ecological consequences of these PF on water resource security have been less considered in the national scale. Moreover, a critically needed comparison on key ecological effects between PF and NF under climate change has rarely been conducted. Here, we compare carbon sequestration and water consumption in PF and NF across China using combination of remote sensing and field inventory. We found that, on average, NF consumed 6.8% (37.5 mm per growing season) less water but sequestered 1.1% (12.5 g C m -2  growing season -1 ) more carbon than PF in the period of 2000-2012. While there was no significant difference in water consumption (p = 0.6) between PF and NF in energy-limited areas (dryness index [DI] < 1), water consumption was significantly (p < 0.001) higher in PF than that in NF in water-limited regions (DI > 1). Moreover, a distinct and larger shift of water yield was identified in PF than in NF from the 1980s to the 2000s, indicating that PF were more sensitive to climate change, leading to a higher water consumption when compared with NF. Our results suggest NF should be properly valued in terms of maximizing the benefits of carbon sequestration and water yield. Future forest plantation projects should be planned with caution, particularly in water-limited regions where they might have less positive effect on carbon sequestration but lead to significant water yield reduction., (© 2018 John Wiley & Sons Ltd.)

Published

2019

22. Influence of the geographic proximity of city features on the spatial variation of urban carbon sinks: A case study on the Pearl River Delta.

Author

Xu Q, Dong YX, and Yang R

Subjects

China, Cities, Ecosystem, Rivers, Carbon Sequestration physiology, Geography, Urbanization

Abstract

Locations of city features, e.g., city centers, roads, railways, and rivers, may impact urban carbon sinks. Therefore, the effects of city features on spatial variations of urban carbon sinks were investigated using geographic proximity data. The main results were as follows. (1) Carbon sink function varied in a complex manner with distance from the city center and with city size. The carbon sink per unit area increased with distance from the prefecture-level city center (0-30 km), with the dominant influence occurring within a 9 km radius. The lowest carbon sink per unit area was observed at a distance of 12 km from the city center of the provincial capital city (Guangzhou) and special economic zone (Shenzhen), which may be suburban industrial zones. (2) Carbon sinks decreased with increases in road grades as a result of the different functions and traffic flow, and carbon sinks were lowest near city express ways. For highways, carbon sinks were lower near highway entrances and exits. Carbon sinks around ordinary railways were higher than those around subways and light rail, but carbon sink characteristics grew more complex with increasing distances from subways and light rail. (3) Rivers were closely related to the urban layout. Grade I (i.e., larger) rivers were associated with lower carbon sinks, and carbon sink characteristics became increasingly complex around larger rivers. Within a 0-1000 m distance of all rivers, the carbon sink per unit area increased rapidly, but carbon sink characteristics differed slightly for grade I rivers. This study implies that it is important to take urbanization spatial position effects into account while assessing regional carbon sinks during urbanization and development., (Copyright © 2018. Published by Elsevier Ltd.)

Published

2018

23. Dynamics of biomass and carbon sequestration across a chronosequence of Caragana intermedia plantations on alpine sandy land.

Author

Li Q, Jia Z, Feng L, He L, and Yang K

Subjects

Biomass, China, Ecosystem, Soil, Temperature, Trees growth & development, Trees physiology, Caragana growth & development, Caragana physiology, Carbon metabolism, Carbon Sequestration physiology

Abstract

Considering the variations in carbon concentrations among different plant components can significantly improve carbon storage estimates. The aim of this study was to estimate the biomass and carbon storage and sequestration in Caragana intermedia Kuang et H. C. Fu plantations for six different ages. The biomass and carbon sequestration in shrub biomass were quantified using a destructive method that involved analysing the carbon concentrations in the leaves, branches, stem bark, stem wood, roots > 5 mm, 2 mm < roots ≤ 5 mm, and roots ≤ 2 mm. The biomass and biomass carbon density of the C. intermedia plantations increased with the age of the stands. The biomass carbon density of the woody components was at its maximum in the 30-year-old plantation (14.27 ± 2.71 t·ha -1 ), indicating that C. intermedia plantations in alpine sandy land are an important carbon pool. The carbon accumulation rate of the woody components was higher during the early stages of plantation development. The carbon concentrations differed significantly among the components but changed only slightly with the stand age. The weighted mean carbon concentration of the woody components, which was found to be 44%, must be considered when estimating the long-term carbon pools in C. intermedia plantations.

Published

2018

24. Carbon stocks of three secondary coniferous forests along an altitudinal gradient on Loess Plateau in inland China.

Author

Liu N and Nan H

Subjects

Altitude, Biomass, China, Ecosystem, Forests, Larix physiology, Linear Models, Picea physiology, Pinus physiology, Soil chemistry, Trees physiology, Water chemistry, Carbon chemistry, Carbon Sequestration physiology, Larix chemistry, Picea chemistry, Pinus chemistry, Trees chemistry

Abstract

Natural forests in inland China are generally distributed in montane area and secondary due to a semi-arid climate and past anthropogenic disturbances. However, quantification of carbon (C) stock in these forests and the role of altitude in determining C storage and its partition among ecosystem components are unclear. We sampled 54 stands of three secondary coniferous forests (Larix principis-rupprechtii (LP) forest, Picea meyerii (PM) forest and Pinus tabulaeformis (PT) forest) on Loess Plateau in an altitudinal range of 1200-2700m a.s.l. C stocks of tree layer, shrub layer, herb layer, coarse wood debris, forest floor and soil were estimated. We found these forests had relatively high total C stocks. Driven by both higher vegetation and soil C stocks, total C stocks of LP and PM forests in the high altitudinal range were 375.0 and 368.4 t C ha-1 respectively, significantly higher than that of PT forest in the low altitudinal range (230.2 t C ha-1). In addition, understory shrubs accounted for about 20% of total biomass in PT forest. The proportions of vegetation to total C stock were similar among in the three forests (below 45%), so were the proportions of soil C stock (over 54%). Necromass C stocks were also similar among these forests, but their proportions to total C stock were significantly lower in LP and PM forests (1.4% and 1.6%) than in PT forest (3.0%). Across forest types, vegetation biomass and soil C stock simultaneously increased with increasing altitude, causing fairly unchanged C partitioning among ecosystem components along the altitudinal gradient. Soil C stock also increased with altitude in LP and PT forests. Forest floor necromass decreased with increasing altitude across the three forests. Our results suggest the important role of the altitudinal gradient in C sequestration and floor necromass of these three forests in terms of alleviated water conditions and in soil C storage of LP and PM forests in terms of temperature change.

Published

2018

25. Biochar alters microbial community and carbon sequestration potential across different soil pH.

Author

Sheng Y and Zhu L

Subjects

Microbiota, Agriculture methods, Carbon Sequestration physiology, Charcoal chemistry, Soil chemistry, Soil Microbiology

Abstract

Biochar application to soil has been proposed for soil carbon sequestration and global warming mitigation. While recent studies have demonstrated that soil pH was a main factor affecting soil microbial community and stability of biochar, little information is available for the microbiome across different soil pH and the subsequently CO 2 emission. To investigate soil microbial response and CO 2 emission of biochar across different pH levels, comparative incubation studies on CO 2 emission, degradation of biochar, and microbial communities in a ferralsol (pH5.19) and a phaeozems (pH7.81) with 4 biochar addition rates (0.5%, 1.0%, 2.0%, 5.0%) were conducted. Biochar induced higher CO 2 emission in acidic ferralsol, largely due to the higher biochar degradation, while the more drastic negative priming effect (PE) of SOC resulted in decreased total CO 2 emission in alkaline phaeozems. The higher bacteria diversity, especially the enrichment of copiotrophic bacteria such as Bacteroidetes, Gemmatimonadetes, and decrease of oligotrophic bacteria such as Acidobacteria, were responsible for the increased CO 2 emission and initial positive PE of SOC in ferralsol, whereas biochar did not change the relative abundances of most bacteria at phylum level in phaeozems. The relative abundances of other bacterial taxa (i.e. Actinobacteria, Anaerolineae) known to degrade aromatic compounds were also elevated in both soils. Soil pH was considered to be the dominant factor to affect CO 2 emission by increasing the bioavailability of organic carbon and abundance of copiotrophic bacteria after biochar addition in ferralsol. However, the decreased bioavailability of SOC via adsorption of biochar resulted in higher abundance of oligotrophic bacteria in phaeozems, leading to the decrease in CO 2 emission., (Copyright © 2017. Published by Elsevier B.V.)

Published

2018

26. Positive biodiversity-productivity relationships in forests: climate matters.

Author

Jactel H, Gritti ES, Drössler L, Forrester DI, Mason WL, Morin X, Pretzsch H, and Castagneyrol B

Subjects

Biomass, Carbon Sequestration physiology, Climate Change, Biodiversity, Climate, Forests

Abstract

While it is widely acknowledged that forest biodiversity contributes to climate change mitigation through improved carbon sequestration, conversely how climate affects tree species diversity-forest productivity relationships is still poorly understood. We combined the results of long-term experiments where forest mixtures and corresponding monocultures were compared on the same site to estimate the yield of mixed-species stands at a global scale, and its response to climatic factors. We found positive mixture effects on productivity using a meta-analysis of 126 case studies established at 60 sites spread across five continents. Overall, the productivity of mixed-species forests was 15% greater than the average of their component monocultures, and not statistically lower than the productivity of the best component monoculture. Productivity gains in mixed-species stands were not affected by tree age or stand species composition but significantly increased with local precipitation. The results should guide better use of tree species combinations in managed forests and suggest that increased drought severity under climate change might reduce the atmospheric carbon sequestration capacity of natural forests., (© 2018 The Author(s).)

Published

2018

27. Thinning Effects on Biomass and Carbon Stock for Young Taiwania Plantations.

Author

Lin JC, Chiu CM, Lin YJ, and Liu WY

Subjects

Biomass, Carbon metabolism, Conservation of Natural Resources methods, Ecosystem, Forests, Soil, Taiwan, Trees metabolism, Carbon Sequestration physiology, Cupressaceae metabolism, Forestry methods

Abstract

Forests play an important role as carbon sinks by sequestrating carbon through photosynthesis. Thinning treatments have large impacts on carbon storage, in addition to strengthening quality and quantity of plantations. This study analyzed the effects of different thinning treatments on carbon stocks in both individual trees and stands of Taiwania (Taiwania cryptomerioides) plantations. Repeated field measurements and allometric equations were used to calculate total C storage and sequestration rates of live trees. The results of this study showed that the total carbon stock of stands with thinning treatments was less than that of the non-thinned stands. The non-thinned 23-year old stands had an estimated carbon stock of 96.8 Mg C ha -1 , which is higher than the carbon stock found in either medium- (84.1 Mg C ha -1 ) or heavily-thinned (74.7 Mg C ha -1 ) treatment plots of the same age. If the objective of Taiwania plantations was to store large amounts of carbon in the young growth stage, without regard to the initial rate of storage, a better option is no-thinning. However, the medium thinned forests seem to be more promising for carbon sequestration than the no-thinned forests if a longer period is considered.

Published

2018

28. Carbon storage in China's terrestrial ecosystems: A synthesis.

Author

Xu L, Yu G, He N, Wang Q, Gao Y, Wen D, Li S, Niu S, and Ge J

Subjects

China, Climate, Ecosystem, Forests, Soil, Temperature, Wetlands, Carbon analysis, Carbon Sequestration physiology

Abstract

It is important to accurately estimate terrestrial ecosystem carbon (C) storage. However, the spatial patterns of C storage and the driving factors remain unclear, owing to lack of data. Here, we collected data from literature published between 2004 and 2014 on C storage in China's terrestrial ecosystems, to explore variation in C storage across different ecosystems and evaluate factors that influence them. We estimated that total C storage was 99.15 ± 8.71 PgC, with 14.60 ± 3.24 PgC in vegetation C (Veg-C) and 84.55 ± 8.09 PgC in soil organic C (SOC) storage. Furthermore, C storage in forest, grassland, wetland, shrub, and cropland ecosystems (excluding vegetation) was 34.08 ± 5.43, 25.69 ± 4.71, 3.62 ± 0.80, 7.42 ± 1.92, and 15.17 ± 2.20 PgC, respectively. In addition to soil nutrients and texture, climate was the main factor regulating the spatial patterns of C storage. Climate influenced the spatial patterns of Veg-C and SOC density via different approaches, Veg-C was mainly positively influenced by mean annual precipitation (MAP), whereas SOC was negatively dependent on mean annual temperature (MAT). This systematic estimate of C storage in China provides new insights about how climate constrains C sequestration, demonstrating the contrasting effects of MAP and MAT on Veg-C and SOC; thus, these parameters should be incorporated into future land management and C sequestration strategies.

Published

2018

29. Recent decrease in carbon sink to Russian forests.

Author

Zamolodchikov DG, Grabovskii VI, Shulyak PP, and Chestnykh OV

Subjects

Biomass, Carbon Sequestration physiology, Russia, Soil, Trees physiology, Carbon Cycle physiology, Ecosystem, Environmental Monitoring, Forests

Abstract

Regional Evaluation of Carbon Budget of Forests (RECBF), was used to study the dynamics of carbon balance in Russian forests in 1988-2015. The carbon sink (excess of absorption over losses) to forests was minimal in 1988. Since the first half of the 1990s, its increase has started. This increase was associated with the reduction of logging volume in connection with socioeconomic reforms. Since 2008, the carbon sink was gradually reduced due to increasing losses in logging operations, forest fires, and decreased carbon absorption.

Published

2017

30. Contribution of seagrass plants to CO2 capture in a tropical seagrass meadow under experimental disturbance.

Author

Deyanova D, Gullström M, Lyimo LD, Dahl M, Hamisi MI, Mtolera MSP, and Björk M

Subjects

Alismatales growth & development, Biomass, Carbon Sequestration physiology, Hydrocharitaceae growth & development, Plant Development, Plant Shoots growth & development, Research Design, Tanzania, Tropical Climate, Aquatic Organisms, Carbon Dioxide metabolism, Ecosystem, Grassland

Abstract

Coastal vegetative habitats are known to be highly productive environments with a high ability to capture and store carbon. During disturbance this important function could be compromised as plant photosynthetic capacity, biomass, and/or growth are reduced. To evaluate effects of disturbance on CO2 capture in plants we performed a five-month manipulative experiment in a tropical seagrass (Thalassia hemprichii) meadow exposed to two intensity levels of shading and simulated grazing. We assessed CO2 capture potential (as net CO2 fixation) using areal productivity calculated from continuous measurements of diel photosynthetic rates, and estimates of plant morphology, biomass and productivity/respiration (P/R) ratios (from the literature). To better understand the plant capacity to coping with level of disturbance we also measured plant growth and resource allocation. We observed substantial reductions in seagrass areal productivity, biomass, and leaf area that together resulted in a negative daily carbon balance in the two shading treatments as well as in the high-intensity simulated grazing treatment. Additionally, based on the concentrations of soluble carbohydrates and starch in the rhizomes, we found that the main reserve sources for plant growth were reduced in all treatments except for the low-intensity simulated grazing treatment. If permanent, these combined adverse effects will reduce the plants' resilience and capacity to recover after disturbance. This might in turn have long-lasting and devastating effects on important ecosystem functions, including the carbon sequestration capacity of the seagrass system.

Published

2017

31. Microbial potential for carbon and nutrient cycling in a geogenic supercritical carbon dioxide reservoir.

Author

Freedman AJE, Tan B, and Thompson JR

Subjects

Carbon metabolism, Carbon Cycle physiology, Carbon Sequestration physiology, Clostridiales classification, Clostridiales genetics, Colorado, Desulfovibrio classification, Desulfovibrio genetics, Ecosystem, Epsilonproteobacteria classification, Epsilonproteobacteria genetics, Genome, Bacterial genetics, Metagenome, RNA, Ribosomal, 16S genetics, Rhizobium classification, Rhizobium genetics, Carbon Dioxide metabolism, Clostridiales metabolism, Desulfovibrio metabolism, Epsilonproteobacteria metabolism, Rhizobium metabolism

Abstract

Microorganisms catalyze carbon cycling and biogeochemical reactions in the deep subsurface and thus may be expected to influence the fate of injected supercritical (sc) CO 2 following geological carbon sequestration (GCS). We hypothesized that natural subsurface scCO 2 reservoirs, which serve as analogs for the long-term fate of sequestered scCO 2 , harbor a 'deep carbonated biosphere' with carbon cycling potential. We sampled subsurface fluids from scCO 2 -water separators at a natural scCO 2 reservoir at McElmo Dome, Colorado for analysis of 16S rRNA gene diversity and metagenome content. Sequence annotations indicated dominance of Sulfurospirillum, Rhizobium, Desulfovibrio and four members of the Clostridiales family. Genomes extracted from metagenomes using homology and compositional approaches revealed diverse mechanisms for growth and nutrient cycling, including pathways for CO 2 and N 2 fixation, anaerobic respiration, sulfur oxidation, fermentation and potential for metabolic syntrophy. Differences in biogeochemical potential between two production well communities were consistent with differences in fluid chemical profiles, suggesting a potential link between microbial activity and geochemistry. The existence of a microbial ecosystem associated with the McElmo Dome scCO 2 reservoir indicates that potential impacts of the deep biosphere on CO 2 fate and transport should be taken into consideration as a component of GCS planning and modelling., (© 2017 The Authors. Environmental Microbiology published by Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2017

32. Edge effects enhance carbon uptake and its vulnerability to climate change in temperate broadleaf forests.

Author

Reinmann AB and Hutyra LR

Subjects

Ecosystem, New England, Carbon metabolism, Carbon Cycle physiology, Carbon Sequestration physiology, Climate Change, Forests, Trees growth & development

Abstract

Forest fragmentation is a ubiquitous, ongoing global phenomenon with profound impacts on the growing conditions of the world's remaining forest. The temperate broadleaf forest makes a large contribution to the global terrestrial carbon sink but is also the most heavily fragmented forest biome in the world. We use field measurements and geospatial analyses to characterize carbon dynamics in temperate broadleaf forest fragments. We show that forest growth and biomass increase by 89 ± 17% and 64 ± 12%, respectively, from the forest interior to edge, but ecosystem edge enhancements are not currently captured by models or approaches to quantifying regional C balance. To the extent that the findings from our research represent the forest of southern New England in the United States, we provide a preliminary estimate that edge growth enhancement could increase estimates of the region's carbon uptake and storage by 13 ± 3% and 10 ± 1%, respectively. However, we also find that forest growth near the edge declines three times faster than that in the interior in response to heat stress during the growing season. Using climate projections, we show that future heat stress could reduce the forest edge growth enhancement by one-third by the end of the century. These findings contrast studies of edge effects in the world's other major forest biomes and indicate that the strength of the temperate broadleaf forest carbon sink and its capacity to mitigate anthropogenic carbon emissions may be stronger, but also more sensitive to climate change than previous estimates suggest., Competing Interests: The authors declare no conflict of interest.

Published

2017

33. Using Prokaryotes for Carbon Capture Storage.

Author

Hicks N, Vik U, Taylor P, Ladoukakis E, Park J, Kolisis F, and Jakobsen KS

Subjects

Air Pollutants isolation & purification, Biodegradation, Environmental, Greenhouse Effect, Air Pollutants metabolism, Biological Assay methods, Carbon Dioxide isolation & purification, Carbon Dioxide metabolism, Carbon Sequestration physiology, Environmental Monitoring methods, Microbiota physiology

Abstract

Geological storage of CO 2 is a fast-developing technology that can mitigate rising carbon emissions. However, there are environmental concerns with the long-term storage and implications of a leak from a carbon capture storage (CCS) site. Traditional monitoring lacks clear protocols and relies heavily on physical methods. Here, we discuss the potential of biotechnology, focusing on microbes with a natural ability to utilize and assimilate CO 2 through different metabolic pathways. We propose the use of natural microbial communities for CCS monitoring and CO 2 utilization, and, with examples, demonstrate how synthetic biology may maximize CO 2 uptake within and above storage sites. An integrated physical and biological approach, combined with metagenomics data and biotechnological advances, will enhance CO 2 sequestration and prevent large-scale leakages., (Crown Copyright © 2016. Published by Elsevier Ltd. All rights reserved.)

Published

2017

34. Carbon is not the enemy.

Author

McDonough W

Subjects

Atmosphere chemistry, Carbon Dioxide adverse effects, Carbon Dioxide economics, Carbon Sequestration physiology, Ecology trends, Goals, Humans, Soil chemistry, Carbon Cycle, Carbon Dioxide metabolism, Ecology methods, Environmental Policy trends, Philosophy, Photosynthesis, Terminology as Topic

Published

2016

35. Engineering de novo disulfide bond in bacterial α-type carbonic anhydrase for thermostable carbon sequestration.

Author

Jo BH, Park TY, Park HJ, Yeon YJ, Yoo YJ, and Cha HJ

Subjects

Catalytic Domain physiology, Kinetics, Temperature, Thermodynamics, Carbon Sequestration physiology, Carbonic Anhydrases metabolism, Disulfides metabolism, Escherichia coli metabolism

Abstract

Exploiting carbonic anhydrase (CA), an enzyme that rapidly catalyzes carbon dioxide hydration, is an attractive biomimetic route for carbon sequestration due to its environmental compatibility and potential economic viability. However, the industrial applications of CA are strongly hampered by the unstable nature of enzymes. In this work, we introduced in silico designed, de novo disulfide bond in a bacterial α-type CA to enhance thermostability. Three variants were selected and expressed in Escherichia coli with an additional disulfide bridge. One of the variants showed great enhancement in terms of both kinetic and thermodynamic stabilities. This improvement could be attributed to the loss of conformational entropy of the unfolded state, showing increased rigidity. The variant showed an upward-shifted optimal temperature and appeared to be thermoactivated, which compensated for the lowered activity at 25 °C. Collectively, the variant constructed by the rapid and effective de novo disulfide engineering can be used as an efficient biocatalyst for carbon sequestration under high temperature conditions.

Published

2016

36. Understory herb layer exerts strong controls on soil microbial communities in subtropical plantations.

Author

Yin K, Zhang L, Chen D, Tian Y, Zhang F, Wen M, and Yuan C

Subjects

Actinobacteria classification, Actinobacteria growth & development, Actinobacteria metabolism, Bacteria classification, Bacteria growth & development, Bacteria metabolism, Ecosystem, Forests, Fungi classification, Fungi growth & development, Fungi metabolism, Mycorrhizae classification, Mycorrhizae growth & development, Mycorrhizae metabolism, Soil chemistry, Carbon Sequestration physiology, Microbial Consortia physiology, Poaceae physiology, Soil Microbiology, Trees physiology

Abstract

The patterns and drivers of soil microbial communities in forest plantations remain inadequate although they have been extensively studied in natural forest and grassland ecosystems. In this study, using data from 12 subtropical plantation sites, we found that the overstory tree biomass and tree cover increased with increasing plantation age. However, there was a decline in the aboveground biomass and species richness of the understory herbs as plantation age increased. Biomass of all microbial community groups (i.e. fungi, bacteria, arbuscular mycorrhizal fungi, and actinomycete) decreased with increasing plantation age; however, the biomass ratio of fungi to bacteria did not change with increasing plantation age. Variation in most microbial community groups was mainly explained by the understory herb (i.e. herb biomass and herb species richness) and overstory trees (i.e. tree biomass and tree cover), while soils (i.e. soil moisture, soil organic carbon, and soil pH) explained a relative low percentage of the variation. Our results demonstrate that the understory herb layer exerts strong controls on soil microbial community in subtropical plantations. These findings suggest that maintenance of plantation health may need to consider the management of understory herb in order to increase the potential of plantation ecosystems as fast-response carbon sinks.

Published

2016

37. Inorganic Nutrients Increase Humification Efficiency and C-Sequestration in an Annually Cropped Soil.

Author

Kirkby CA, Richardson AE, Wade LJ, Conyers M, and Kirkegaard JA

Subjects

Agriculture methods, Carbon chemistry, Climate Change, Fertilizers, Food, Nitrogen chemistry, Phosphorus chemistry, Carbon Dioxide chemistry, Carbon Sequestration physiology, Crops, Agricultural chemistry, Soil chemistry

Abstract

Removing carbon dioxide (CO2) from the atmosphere and storing the carbon (C) in resistant soil organic matter (SOM) is a global priority to restore soil fertility and help mitigate climate change. Although it is widely assumed that retaining rather than removing or burning crop residues will increase SOM levels, many studies have failed to demonstrate this. We hypothesised that the microbial nature of resistant SOM provides a predictable nutrient stoichiometry (C:nitrogen, C:phosphorus and C:sulphur-C:N:P:S) to target using supplementary nutrients when incorporating C-rich crop residues into soil. An improvement in the humification efficiency of the soil microbiome as a whole, and thereby C-sequestration, was predicted. In a field study over 5 years, soil organic-C (SOC) stocks to 1.6 m soil depth were increased by 5.5 t C ha-1 where supplementary nutrients were applied with incorporated crop residues, but were reduced by 3.2 t C ha-1 without nutrient addition, with 2.9 t C ha-1 being lost from the 0-10 cm layer. A net difference of 8.7 t C ha-1 was thus achieved in a cropping soil over a 5 year period, despite the same level of C addition. Despite shallow incorporation (0.15 m), more than 50% of the SOC increase occurred below 0.3 m, and as predicted by the stoichiometry, increases in resistant SOC were accompanied by increases in soil NPS at all depths. Interestingly the C:N, C:P and C:S ratios decreased significantly with depth possibly as a consequence of differences in fungi to bacteria ratio. Our results demonstrate that irrespective of the C-input, it is essential to balance the nutrient stoichiometry of added C to better match that of resistant SOM to increase SOC sequestration. This has implications for global practices and policies aimed at increasing SOC sequestration and specifically highlight the need to consider the hidden cost and availability of associated nutrients in building soil-C.

Published

2016

38. Forest soil carbon is threatened by intensive biomass harvesting.

Author

Achat DL, Fortin M, Landmann G, Ringeval B, and Augusto L

Subjects

Carbon chemistry, Carbon Cycle physiology, Ecosystem, Forests, Trees chemistry, Biomass, Carbon Sequestration physiology, Environmental Monitoring, Forestry methods, Soil chemistry

Abstract

Forests play a key role in the carbon cycle as they store huge quantities of organic carbon, most of which is stored in soils, with a smaller part being held in vegetation. While the carbon storage capacity of forests is influenced by forestry, the long-term impacts of forest managers' decisions on soil organic carbon (SOC) remain unclear. Using a meta-analysis approach, we showed that conventional biomass harvests preserved the SOC of forests, unlike intensive harvests where logging residues were harvested to produce fuelwood. Conventional harvests caused a decrease in carbon storage in the forest floor, but when the whole soil profile was taken into account, we found that this loss in the forest floor was compensated by an accumulation of SOC in deeper soil layers. Conversely, we found that intensive harvests led to SOC losses in all layers of forest soils. We assessed the potential impact of intensive harvests on the carbon budget, focusing on managed European forests. Estimated carbon losses from forest soils suggested that intensive biomass harvests could constitute an important source of carbon transfer from forests to the atmosphere (142-497 Tg-C), partly neutralizing the role of a carbon sink played by forest soils.

Published

2015

39. Comparison of marine macrophytes for their contributions to blue carbon sequestration.

Author

Trevathan-Tackett SM, Kelleway J, Macreadie PI, Beardall J, Ralph P, and Bellgrove A

Subjects

Animals, Carbon Cycle, Nitrogen metabolism, Temperature, Carbon metabolism, Carbon Sequestration physiology, Plants metabolism, Seaweed metabolism, Wetlands

Abstract

Many marine ecosystems have the capacity for long-term storage of organic carbon (C) in what are termed "blue carbon" systems. While blue carbon systems (saltmarsh, mangrove, and seagrass) are efficient at long-term sequestration of organic carbon (C), much of their sequestered C may originate from other (allochthonous) habitats. Macroalgae, due to their high rates of production, fragmentation, and ability to be transported, would also appear to be able to make a significant contribution as C donors to blue C habitats. In order to assess the stability of macroalgal tissues and their likely contribution to long-term pools of C, we applied thermogravimetric analysis (TGA) to 14 taxa of marine macroalgae and coastal vascular plants. We assessed the structural complexity of multiple lineages of plant and tissue types with differing cell wall structures and found that decomposition dynamics varied significantly according to differences in cell wall structure and composition among taxonomic groups and tissue function (photosynthetic vs. attachment). Vascular plant tissues generally exhibited greater stability with a greater proportion of mass loss at temperatures > 300 degrees C (peak mass loss -320 degrees C) than macroalgae (peak mass loss between 175-300 degrees C), consistent with the lignocellulose matrix of vascular plants. Greater variation in thermogravimetric signatures within and among macroalgal taxa, relative to vascular plants, was also consistent with the diversity of cell wall structure and composition among groups. Significant degradation above 600 degrees C for some macroalgae, as well as some belowground seagrass tissues, is likely due to the presence of taxon-specific compounds. The results of this study highlight the importance of the lignocellulose matrix to the stability of vascular plant sources and the potentially significant role of refractory, taxon-specific compounds (carbonates, long-chain lipids, alginates, xylans, and sulfated polysaccharides) from macroalgae and seagrasses for their long-term sedimentary C storage. This study shows that marine macroalgae do contain refractory compounds and thus may be more valuable to long-term carbon sequestration than we previously have considered.

Published

2015

40. Seasonal copepod lipid pump promotes carbon sequestration in the deep North Atlantic.

Author

Jónasdóttir SH, Visser AW, Richardson K, and Heath MR

Subjects

Animals, Atlantic Ocean, Body Size, Animal Migration physiology, Carbon analysis, Carbon Sequestration physiology, Copepoda chemistry, Copepoda physiology, Lipids chemistry

Abstract

Estimates of carbon flux to the deep oceans are essential for our understanding of global carbon budgets. Sinking of detrital material ("biological pump") is usually thought to be the main biological component of this flux. Here, we identify an additional biological mechanism, the seasonal "lipid pump," which is highly efficient at sequestering carbon into the deep ocean. It involves the vertical transport and metabolism of carbon rich lipids by overwintering zooplankton. We show that one species, the copepod Calanus finmarchicus overwintering in the North Atlantic, sequesters an amount of carbon equivalent to the sinking flux of detrital material. The efficiency of the lipid pump derives from a near-complete decoupling between nutrient and carbon cycling—a "lipid shunt," and its direct transport of carbon through the mesopelagic zone to below the permanent thermocline with very little attenuation. Inclusion of the lipid pump almost doubles the previous estimates of deep-ocean carbon sequestration by biological processes in the North Atlantic.

Published

2015

41. Warmer and Wetter Soil Stimulates Assimilation More than Respiration in Rainfed Agricultural Ecosystem on the China Loess Plateau: The Role of Partial Plastic Film Mulching Tillage.

Author

Gong D, Hao W, Mei X, Gao X, Liu Q, and Caylor K

Subjects

Agriculture, Atmosphere, Carbon Dioxide toxicity, China, Humans, Plastics chemistry, Respiration, Seasons, Temperature, Water, Zea mays chemistry, Zea mays metabolism, Carbon Dioxide chemistry, Carbon Sequestration physiology, Ecosystem, Soil chemistry

Abstract

Effects of agricultural practices on ecosystem carbon storage have acquired widespread concern due to its alleviation of rising atmospheric CO2 concentrations. Recently, combining of furrow-ridge with plastic film mulching in spring maize ecosystem was widely applied to boost crop water productivity in the semiarid regions of China. However, there is still limited information about the potentials for increased ecosystem carbon storage of this tillage method. The objective of this study was to quantify and contrast net carbon dioxide exchange, biomass accumulation and carbon budgets of maize (Zea maize L.) fields under the traditional non-mulching with flat tillage (CK) and partial plastic film mulching with furrow-ridge tillage (MFR) on the China Loess Plateau. Half-hourly net ecosystem CO2 exchange (NEE) of both treatments were synchronously measured with two eddy covariance systems during the growing seasons of 2011 through 2013. At same time green leaf area index (GLAI) and biomass were also measured biweekly. Compared with CK, the warmer and wetter (+1.3°C and +4.3%) top soil at MFR accelerated the rates of biomass accumulation, promoted greater green leaf area and thus shortened the growing seasons by an average value of 10.4 days for three years. MFR stimulated assimilation more than respiration during whole growing season, resulting in a higher carbon sequestration in terms of NEE of -79 gC/m2 than CK. However, after considering carbon in harvested grain (or aboveground biomass), there is a slight higher carbon sink (or a stronger carbon source) in MFR due to its greater difference of aboveground biomass than that of grain between both treatments. These results demonstrate that partial plastic film mulched furrow-ridge tillage with aboveground biomass exclusive of grain returned to the soil is an effective way to enhance simultaneously carbon sequestration and grain yield of maize in the semiarid regions.

Published

2015

42. Validating Community-Led Forest Biomass Assessments.

Author

Venter M, Venter O, Edwards W, and Bird MI

Subjects

Biomass, Carbon chemistry, Ecosystem, Forests, Papua New Guinea, Tropical Climate, Carbon Sequestration physiology, Environmental Monitoring methods, Trees growth & development

Abstract

The lack of capacity to monitor forest carbon stocks in developing countries is undermining global efforts to reduce carbon emissions. Involving local people in monitoring forest carbon stocks could potentially address this capacity gap. This study conducts a complete expert remeasurement of community-led biomass inventories in remote tropical forests of Papua New Guinea. By fully remeasuring and isolating the effects of 4,481 field measurements, we demonstrate that programmes employing local people (non-experts) can produce forest monitoring data as reliable as those produced by scientists (experts). Overall, non-experts reported lower biomass estimates by an average of 9.1%, equivalent to 55.2 fewer tonnes of biomass ha(-1), which could have important financial implications for communities. However, there were no significant differences between forest biomass estimates of expert and non-expert, nor were there significant differences in some of the components used to calculate these estimates, such as tree diameter at breast height (DBH), tree counts and plot surface area, but were significant differences between tree heights. At the landscape level, the greatest biomass discrepancies resulted from height measurements (41%) and, unexpectedly, a few large missing trees contributing to a third of the overall discrepancies. We show that 85% of the biomass discrepancies at the tree level were caused by measurement taken on large trees (DBH ≥50 cm), even though they consisted of only 14% of the stems. We demonstrate that programmes that engage local people can provide high-quality forest carbon data that could help overcome barriers to reducing forest carbon emissions in developing countries. Nonetheless, community-based monitoring programmes should prioritise reducing errors in the field that lead to the most important discrepancies, notably; overcoming challenges to accurately measure large trees.

Published

2015

43. Current and potential carbon stocks in Moso bamboo forests in China.

Author

Li P, Zhou G, Du H, Lu D, Mo L, Xu X, Shi Y, and Zhou Y

Subjects

Biomass, Carbon analysis, Carbon Cycle physiology, China, Soil chemistry, Carbon metabolism, Carbon Sequestration physiology, Forests, Poaceae chemistry

Abstract

Bamboo forests provide important ecosystem services and play an important role in terrestrial carbon cycling. Of the approximately 500 bamboo species in China, Moso bamboo (Phyllostachys pubescens) is the most important one in terms of distribution, timber value, and other economic values. In this study, we estimated current and potential carbon stocks in China's Moso bamboo forests and in their products. The results showed that Moso bamboo forests in China stored about 611.15 ± 142.31 Tg C, 75% of which was in the top 60 cm soil, 22% in the biomass of Moso bamboos, and 3% in the ground layer (i.e., bamboo litter, shrub, and herb layers). Moso bamboo products store 10.19 ± 2.54 Tg C per year. The potential carbon stocks reach 1331.4 ± 325.1 Tg C, while the potential C stored in products is 29.22 ± 7.31 Tg C a(-1). Our results indicate that Moso bamboo forests and products play a critical role in C sequestration. The information gained in this study will facilitate policy decisions concerning carbon sequestration and management of Moso bamboo forests in China., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

44. Nitrogen limitation on land: how can it occur in Earth system models?

Author

Thomas RQ, Brookshire EN, and Gerber S

Subjects

Carbon Sequestration physiology, Nitrogen metabolism, Earth, Planet, Ecosystem, Models, Theoretical, Nitrogen analysis, Nitrogen Cycle physiology, Soil chemistry

Abstract

The representation of the nitrogen (N) cycle in Earth system models (ESMs) is strongly motivated by the constraint N poses on the sequestration of anthropogenic carbon (C). Models typically implement a stoichiometric relationship between C and N in which external supply and assimilation by organisms are adjusted to maintain their internal stoichiometry. N limitation of primary productivity thus occurs if the N supply from uptake and fixation cannot keep up with the construction of tissues allowed by C assimilation. This basic approach, however, presents considerable challenges in how to faithfully represent N limitation. Here, we review how N limitation is currently implemented and evaluated in ESMs and highlight challenges and opportunities in their future development. At or near steady state, N limitation is governed by the magnitude of losses from the plant-unavailable pool vs. N fixation and there are considerable differences in how models treat both processes. In nonsteady-state systems, the accumulation of N in pools with slow turnover rates reduces N available for plant uptake and can be challenging to represent when initializing ESM simulations. Transactional N limitation occurs when N is incorporated into various vegetation and soil pools and becomes available to plants only after it is mineralized, the dynamics of which depends on how ESMs represent decomposition processes in soils. Other challenges for ESMs emerge when considering seasonal to interannual climatic oscillations as they create asynchronies between C and N demand, leading to transient alternations between N surplus and deficit. Proper evaluation of N dynamics in ESMs requires conceptual understanding of the main levers that trigger N limitation, and we highlight key measurements and observations that can help constrain these levers. Two of the biggest challenges are the mechanistic representation of plant controls on N availability and turnover, including N fixation and organic matter decomposition processes., (© 2015 John Wiley & Sons Ltd.)

Published

2015

45. Characterization of bacteria isolated from palaeoproterozoic metasediments for sequestration of carbon dioxide and formation of calcium carbonate.

Author

Srivastava S, Bharti RK, and Thakur IS

Subjects

Carbon Radioisotopes analysis, Denaturing Gradient Gel Electrophoresis, Microscopy, Electron, Scanning, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Serratia genetics, Sodium Bicarbonate, Species Specificity, Spectroscopy, Fourier Transform Infrared, X-Ray Diffraction, Calcium Carbonate metabolism, Carbon Dioxide metabolism, Carbon Sequestration physiology, Geologic Sediments microbiology, Global Warming prevention & control, Serratia metabolism, Soil Microbiology

Abstract

Bacterial community of palaeoproterozoic metasediments was enriched in the chemostat in the presence of different concentrations of NaHCO3. Six bacterial isolates were isolated from the chemostat on nutrient agar plates on the basis of distinct morphology. Denaturing gradient gel electrophoresis (DGGE) proved the presence of six operational taxonomic units (OTUs) at 50 and 100 mM NaHCO3. The OTU was reduced to three and one at enrichment concentration of 150 and 200 mM NaHCO3 respectively. These six isolates were tested for sequestration of carbon dioxide by (14)C metabolic labeling of NaH(14)CO3. Among the six isolates, one of the bacterium showed better potency to fix radiolabeled NaH(14)CO3. The isolate (ISTD04) was identified as Serratia sp. by 16S ribosomal RNA (16S rRNA) sequence analysis and was found to be same as the DGGE OTU sequence at 200-mM NaHCO3 concentration. The bacterium was tested for product formation in form of calcite crystals in presence of 5 % CO2. Scanning electron microscopy (SEM) of product formed by the bacterium revealed defined faceted rhombohedral structure which resembled calcite and vaterite phases of the crystal. Formation of calcium carbonate crystals was further confirmed by Fourier transform infrared (FTIR) spectroscopy as carbonate group showing strong vibration at 1,456 cm(-1). Major calcite phase diffraction peaks were determined by X-ray diffraction (XRD) analysis, and energy-dispersive X-ray (EDX) analysis showed the presence of CaO (72 %) and carbon (18 %). Bacterium use bicarbonate as carbon source for their growth as well as by-product formation in form of calcite shows carbon circulation and storage.

Published

2015

46. A large-scale field assessment of carbon stocks in human-modified tropical forests.

Author

Berenguer E, Ferreira J, Gardner TA, Aragão LE, De Camargo PB, Cerri CE, Durigan M, Cosme De Oliveira Junior R, Vieira IC, and Barlow J

Subjects

Brazil, Computer Simulation, Conservation of Natural Resources methods, Fires, Tropical Climate, Carbon Cycle physiology, Carbon Sequestration physiology, Conservation of Natural Resources statistics & numerical data, Forestry statistics & numerical data, Forests, Models, Biological, Soil chemistry

Abstract

Tropical rainforests store enormous amounts of carbon, the protection of which represents a vital component of efforts to mitigate global climate change. Currently, tropical forest conservation, science, policies, and climate mitigation actions focus predominantly on reducing carbon emissions from deforestation alone. However, every year vast areas of the humid tropics are disturbed by selective logging, understory fires, and habitat fragmentation. There is an urgent need to understand the effect of such disturbances on carbon stocks, and how stocks in disturbed forests compare to those found in undisturbed primary forests as well as in regenerating secondary forests. Here, we present the results of the largest field study to date on the impacts of human disturbances on above and belowground carbon stocks in tropical forests. Live vegetation, the largest carbon pool, was extremely sensitive to disturbance: forests that experienced both selective logging and understory fires stored, on average, 40% less aboveground carbon than undisturbed forests and were structurally similar to secondary forests. Edge effects also played an important role in explaining variability in aboveground carbon stocks of disturbed forests. Results indicate a potential rapid recovery of the dead wood and litter carbon pools, while soil stocks (0-30 cm) appeared to be resistant to the effects of logging and fire. Carbon loss and subsequent emissions due to human disturbances remain largely unaccounted for in greenhouse gas inventories, but by comparing our estimates of depleted carbon stocks in disturbed forests with Brazilian government assessments of the total forest area annually disturbed in the Amazon, we show that these emissions could represent up to 40% of the carbon loss from deforestation in the region. We conclude that conservation programs aiming to ensure the long-term permanence of forest carbon stocks, such as REDD+, will remain limited in their success unless they effectively avoid degradation as well as deforestation., (© 2014 The Authors. Global Change Biology Published by John Wiley & Sons Ltd.)

Published

2014

47. Wood production response to climate change will depend critically on forest composition and structure.

Author

Coomes DA, Flores O, Holdaway R, Jucker T, Lines ER, and Vanderwel MC

Subjects

Adaptation, Biological physiology, Biomass, Computer Simulation, Forecasting, New Zealand, Wood growth & development, Biodiversity, Carbon Sequestration physiology, Climate Change, Forests, Models, Biological, Trees growth & development, Wood economics

Abstract

Established forests currently function as a major carbon sink, sequestering as woody biomass about 26% of global fossil fuel emissions. Whether forests continue to act as a global sink will depend on many factors, including the response of aboveground wood production (AWP; MgC ha(-1 ) yr(-1) ) to climate change. Here, we explore how AWP in New Zealand's natural forests is likely to change. We start by statistically modelling the present-day growth of 97 199 individual trees within 1070 permanently marked inventory plots as a function of tree size, competitive neighbourhood and climate. We then use these growth models to identify the factors that most influence present-day AWP and to predict responses to medium-term climate change under different assumptions. We find that if the composition and structure of New Zealand's forests were to remain unchanged over the next 30 years, then AWP would increase by 6-23%, primarily as a result of physiological responses to warmer temperatures (with no appreciable effect of changing rainfall). However, if warmth-requiring trees were able to migrate into currently cooler areas and if denser canopies were able to form, then a different AWP response is likely: forests growing in the cool mountain environments would show a 30% increase in AWP, while those in the lowland would hardly respond (on average, -3% when mean annual temperature exceeds 8.0 °C). We conclude that response of wood production to anthropogenic climate change is not only dependent on the physiological responses of individual trees, but is highly contingent on whether forests adjust in composition and structure., (© 2014 John Wiley & Sons Ltd.)

Published

2014

48. Strong topographic sheltering effects lead to spatially complex treeline advance and increased forest density in a subtropical mountain region.

Author

Greenwood S, Chen JC, Chen CT, and Jump AS

Subjects

Carbon Sequestration physiology, Computer Simulation, Geography, Population Density, Taiwan, Altitude, Forests, Models, Biological, Temperature, Trees growth & development

Abstract

Altitudinal treelines are typically temperature limited such that increasing temperatures linked to global climate change are causing upslope shifts of treelines worldwide. While such elevational increases are readily predicted based on shifting isotherms, at the regional level the realized response is often much more complex, with topography and local environmental conditions playing an important modifying role. Here, we used repeated aerial photographs in combination with forest inventory data to investigate changes in treeline position in the Central Mountain Range of Taiwan over the last 60 years. A highly spatially variable upslope advance of treeline was identified in which topography is a major driver of both treeline form and advance. The changes in treeline position that we observed occurred alongside substantial increases in forest density, and lead to a large increase in overall forest area. These changes will have a significant impact on carbon stocking in the high altitude zone, while the concomitant decrease in alpine grassland area is likely to have negative implications for alpine species. The complex and spatially variable changes that we report highlight the necessity for considering local factors such as topography when attempting to predict species distributional responses to warming climate., (© 2014 John Wiley & Sons Ltd.)

Published

2014

49. Identification of carbohydrates as the major carbon sink of the marine microalga Isochrysis zhangjiangensis (Haptophyta) and optimization of its productivity by nitrogen manipulation.

Author

Wang HT, Yao CH, Ai JN, Cao XP, Xue S, and Wang WL

Subjects

Chromatography, High Pressure Liquid, Haptophyta cytology, Haptophyta metabolism, Microalgae cytology, Microalgae metabolism, Nitrates metabolism, Photosystem II Protein Complex metabolism, Biofuels, Bioreactors, Carbon Sequestration physiology, Glucose physiology, Haptophyta physiology, Microalgae physiology, Nitrogen metabolism

Abstract

Microalgae represent a potential feedstock for biofuel production. During cultivation under nitrogen-depleted conditions, carbohydrates, rather than neutral lipids, were the major carbon sink of the marine microalga Isochrysis zhangjiangensis (Haptophyta). Carbohydrates reached maximum levels of 21.2 pg cell(-1) on day 5, which was an increase of more than 7-fold from day 1, while neutral lipids simultaneously increased 1.9-fold from 4.0 to 7.6 pg cell(-1) during the ten-day nitrogen-depleted cultivation. The carbohydrate productivity of I. zhangjiangensis was improved by optimization of the nitrate supply mode. The maximum carbohydrate concentration was 0.95 g L(-1) under batch cultivation, with an initial nitrogen concentration of 31.0 mg L(-1), which was 2.4-fold greater than that achieved under nitrogen-depleted conditions. High performance liquid chromatography (HPLC) analysis showed that the accumulated carbohydrate in I. zhangjiangensis was composed of glucose. These results show that I. zhangjiangensis represents an ideal carbohydrate-enriched bioresource for biofuel production., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

50. Production of carbon occluded in phytolith is season-dependent in a bamboo forest in subtropical China.

Author

Huang ZT, Jiang PK, Chang SX, Zhang Y, and Ying YQ

Subjects

Bambusa chemistry, Carbon metabolism, China, Forests, Plant Leaves metabolism, Seasons, Trees chemistry, Tropical Climate, Bambusa metabolism, Carbon chemistry, Carbon Sequestration physiology, Plant Leaves chemistry, Soil chemistry, Trees metabolism

Abstract

Carbon (C) occluded in phytolith (PhytOC) is a stable form of C; when PhytOC is returned to the soil through litterfall it is stored in the soil which can be an effective way for long-term C sequestration. However, few estimates on the rate of PhytOC input to the soil are available. To better understand the seasonal dynamics of PhytOC production and the annual rate of stable C sequestration through PhytOC input, we quantified the monthly litterfall, phytolith and PhytOC return to the soil over a year in a typical Lei bamboo (Phyllostachys praecox) forest in subtropical China. The monthly litterfall ranged between 14.81 and 131.18 g m(-2), and the phytolith concentration in the monthly litterfall samples ranged between 47.21 and 101.68 g kg(-1) of litter mass, with the PhytOC concentration in the phytolith ranged between 29.4 and 44.9 g kg(-1) of phytolith, equivalent to 1.8-3.6 g kg(-1) of PhytOC in the litterfall (based on litterfall dry mass). The amount of phytolith input to the soil system was 292.21 ± 69.12 (mean ± SD) kg ha(-1) yr(-1), sequestering 41.45 ± 9.32 kg CO2-e ha(-1) yr(-1) of C in the studied Lei bamboo forest. This rate of C sequestration through the formation of PhytOC found in this study falls within the range of rates for other grass-type species reported in the literature. We conclude that return of C occluded in phytolith to the soil can be a substantial source of stable soil C and finding means to increase PhytOC storage in the soil should be able to play a significant role in mitigating the rapidly increasing atmospheric CO2 concentration.

Published

2014