African tropical rainforest net carbon dioxide fluxes in the twentieth century

The African humid tropical biome constitutes the second largest rainforest region, significantly impacts global carbon cycling and climate, and has undergone major changes in functioning owing to climate and land-use change over the past century. We assess changes and trends in CO 2 fluxes from 1901 to 2010 using nine land surface models forced with common driving data, and depict the inter-model variability as the uncertainty in fluxes. The biome is estimated to be a natural (no disturbance) net carbon sink (−0.02 kg C m −2 yr −1 or −0.04 Pg C yr −1 , p < 0.05) with increasing strength fourfold in the second half of the century. The models were in close agreement on net CO 2 flux at the beginning of the century ( σ 1901 = 0.02 kg C m −2 yr −1 ), but diverged exponentially throughout the century ( σ 2010 = 0.03 kg C m −2 yr −1 ). The increasing uncertainty is due to differences in sensitivity to increasing atmospheric CO 2 , but not increasing water stress, despite a decrease in precipitation and increase in air temperature. However, the largest uncertainties were associated with the most extreme drought events of the century. These results highlight the need to constrain modelled CO 2 fluxes with increasing atmospheric CO 2 concentrations and extreme climatic events, as the uncertainties will only amplify in the next century.

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Stable carbon isotopes as powerful tools for studying land-atmosphere flux exchanges and improving land surface models

10.5194/egusphere-egu21-11232 ◽

2021 ◽

Author(s):

Aliénor Lavergne ◽

Laia Andreu-Hayles ◽

Soumaya Belmecheri ◽

Rossella Guerrieri ◽

Heather Graven

Keyword(s):

Carbon Isotopes ◽

Land Surface ◽

Stable Carbon Isotopes ◽

Environmental Changes ◽

Carbon Sink ◽

Stable Carbon ◽

Land Surface Models ◽

Terrestrial Plants ◽

Plant Materials ◽

Surface Models

The stable isotopic compositions of carbon and oxygen in terrestrial plants can provide valuable insights into plant eco-physiological responses to environmental changes at seasonal to annual resolution. Yet, the potential of these datasets to study land-atmosphere interactions remains under-exploited. Here, we present some examples of how stable carbon isotopes (&#948;13C) measured in plant materials (leaves and tree-rings) can be used to explore changes in the magnitude and variability of carbon and water flux exchanges between the vegetation and the atmosphere and to improve land surface models. First, we show that the discrimination against 13C (&#916;13C), calculated as the difference in &#948;13C between the source atmospheric CO2 and the plant material studied, varies strongly between regions and biomes and is useful for better understanding the CO2 fertilisation effect of plant growth. For example, tree-ring &#916;13C records from boreal evergreen forests in North America increased linearly with rising CO2 during the 20th century, suggesting that those forests have actively contributed to the land carbon sink by removing CO2 from the atmosphere at a relatively constant rate. However, such an increase in&#160;&#916;13C with rising CO2 is not observed everywhere. We found that over the same time period, while some forests had a fairly constant &#916;13C, others exhibited a slight decrease in &#916;13C over time, which might indicate a reduction of the capacity of trees to absorb CO2. Using a response function approach, we show that the differences between sites and regions are most likely the result of different evaporative demands and soil water availability conditions experienced by forests. We then discuss how predictions of the coupled carbon and water cycles by vegetation models can be improved by incorporating stable carbon isotopes to constrain the model representation of carbon-water fluxes regulation by leaf stomata. Specifically, we examine and evaluate simulations from the JULES vegetation model at different eddy-covariance forest sites where stable carbon isotopic data and canopy flux measurements are available. Overall, our analyses have strong implications for the understanding of historical changes in the strength of the CO2 fertilisation effect and in the water use efficiency of terrestrial ecosystems across regions.&#160;

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Land surface air temperature variations over Eurasia and possible causes in the past century

International Journal of Climatology ◽

10.1002/joc.5306 ◽

2017 ◽

Vol 38 (4) ◽

pp. 1925-1937 ◽

Cited By ~ 1

Author(s):

Zhiyan Zuo ◽

Song Yang ◽

Kang Xu ◽

Renhe Zhang ◽

Qiong He ◽

...

Keyword(s):

Air Temperature ◽

Land Surface ◽

Surface Air Temperature ◽

Past Century ◽

Temperature Variations ◽

The Past ◽

Air Temperature Variations

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Forest structure and vegetation dynamics as a driver of global carbon uptake

10.5194/egusphere-egu2020-11676 ◽

2020 ◽

Author(s):

Ben Poulter ◽

Leo Calle ◽

Thomas Pugh ◽

Nathan McDowell ◽

Philippe Ciais ◽

...

Keyword(s):

Land Use ◽

Land Cover Change ◽

Forest Structure ◽

Land Surface ◽

Vegetation Dynamics ◽

Carbon Uptake ◽

Forest Age ◽

Land Surface Models ◽

Surface Models ◽

Global Carbon

The drivers for terrestrial carbon uptake remain unclear despite a clear signal that the land removes the equivalent of up to 25-30% of fossil fuel CO2 emissions each year. Recent work has confirmed sustained carbon uptake by the land that is proportional to anthropogenic emissions, meaning that the land 'sink' has strengthened over the past five decades, and with interannual variability driven by climate. Drivers responsible for sustained uptake include hypotheses related to lengthening growing season length, increasing nitrogen deposition, changes in the ratio of diffuse to direct radiation, and land-use and land cover change. More recently, land-use and land-cover change has been investigated as a driver of land carbon uptake owing to an emergence of global-scale datasets related to canopy disturbance, land use, and forest age. At the same time, land-surface models have increased their realism in terms of moving beyond 'big-leaf' model representation of ecosystems to including vertical structure and horizontal heteorogeneity via size-and-age structured approaches. This presentation will address recent work identified forest structure and vegetation dynamics as a driver for global carbon uptake and provide examples of how remote sensing observations have led to new datasets for initialization land-surface models. Compared to inventory-based approaches, land-surface models initialized with forest age show a lessor role in explaining net terrestrial carbon uptake at global scales, but at regional scales, vegetation structure is a key determinant of carbon exchange. New satellite missions improving forest structure observations are expected to reduce uncertainties and contribute substantially to ongoing land-surface model development.

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The contribution of trees and grasses to productivity of an Australian tropical savanna

Biogeosciences ◽

10.5194/bg-13-2387-2016 ◽

2016 ◽

Vol 13 (8) ◽

pp. 2387-2403 ◽

Cited By ~ 20

Author(s):

Caitlin E. Moore ◽

Jason Beringer ◽

Bradley Evans ◽

Lindsay B. Hutley ◽

Ian McHugh ◽

...

Keyword(s):

Land Surface ◽

Carbon Flux ◽

Temporal Dynamics ◽

Carbon Sink ◽

Tropical Savanna ◽

Wet Season ◽

Carbon Dioxide Fluxes ◽

Dynamic Partitioning ◽

Eddy Covariance Measurements ◽

Competition For Resources

Abstract. Savanna ecosystems cover 20 % of the global land surface and account for 25 % of global terrestrial carbon uptake. They support one fifth of the world's human population and are one of the most important ecosystems on our planet. Savanna productivity is a product of the interplay between trees and grass that co-dominate savanna landscapes and are maintained through interactions with climate and disturbance (fire, land use change, herbivory). In this study, we evaluate the temporally dynamic partitioning of overstory and understory carbon dioxide fluxes in Australian tropical savanna using overstory and understory eddy covariance measurements. Over a 2-year period (September 2012 to October 2014) the overall net ecosystem productivity (NEP) of the savanna was 506.2 (±22 SE) g C m−2 yr−1. The total gross primary productivity (GPP) was 2267.1 (±80 SE) g C m−2 yr−1, of which the understory contributed 32 %. The understory contribution was strongly seasonal, with most GPP occurring in the wet season (40 % of total ecosystem in the wet season and 18 % in the dry). This study is the first to elucidate the temporal dynamics of savanna understory and overstory carbon flux components explicitly using observational information. Understanding grass productivity is crucial for evaluating fuel loads, as is tree productivity for quantifying the tree carbon sink. This information will contribute to a significant refinement of the representation of savannas in models, as well as improved understanding of relative tree-grass productivity and competition for resources.

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The Bases of International Relations

The American Journal of International Law ◽

10.2307/2190455 ◽

1937 ◽

Vol 31 (3) ◽

pp. 431-448

Author(s):

Denys P. Myers

Keyword(s):

International Relations ◽

Land Surface ◽

Water Area ◽

Past Century ◽

Entire Surface ◽

The Past ◽

The Earth

There are estimated to be 2,077,000,000 people now alive at a given moment on the 51,104,000 square miles of the continents, subcontinents and islands which constitute the earth’s inhabited land surface. They make extensive use of the 144,478,000 square miles of the world’s water area. Within the past century the living generations have come to control the entire surface of the earth with substantial completeness through the mechanisms of society which they have created; but they do not even yet utilize its land areas fully.

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Net carbon sink of China was overestimated by more than 35%

10.21203/rs.3.rs-1063386/v1 ◽

2021 ◽

Author(s):

Chaochao Du ◽

Xiaoyong Bai ◽

yangbing Li ◽

Qiu Tan ◽

Cuiwei Zhao Zhao ◽

...

Keyword(s):

Forest Fires ◽

Atmospheric Carbon Dioxide ◽

Carbon Sink ◽

Terrestrial Ecosystems ◽

Carbon Neutrality ◽

Relative Contribution ◽

Reactive Carbon ◽

Source Sink ◽

Global Carbon ◽

Net Carbon Sink

Abstract As a carbon source/sink of atmospheric carbon dioxide, the net regional carbon budget (NRCB) of terrestrial ecosystems is very important to effect global warming, especially China with the largest emissions at present. However, the carbon consumption is difficult to measure accurately, which is caused by the emissions of CH4 and CO, the utilization of agriculture, forestry and grass, and the emissions from rivers and other physical processes, such as forest fires. Therefore, the spatial patterns and driving factors of NRCB are not clear. Here, we used multi-source data to estimate the NRCB of 31 provincial administrative divisions of China and to develop NRCB datasets from 2000 to 2018. We found that the average of NRCB was 669 TgC yr−1, and it significantly decreased at a rate of 2.56 TgC yr−1. The relative contribution rates of fluxes of emissions from anthropogenic (FEAD), reactive carbon and creature ingestion (FERCCI), autotrophic respiration (Ra), heterotrophic respiration (Rh) and natural disturbances (FEND) were 35.17%, 26.09%, 19.68%, 17.38% and 1.68% respectively. In addition, NRCB datasets of the different administrative regions of China were mapped. These datasets will provide support for China's carbon neutrality and the study of the global carbon cycle.

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Increased vulnerability of European ecosystems to two consecutive extreme summers

10.5194/egusphere-egu21-1964 ◽

2021 ◽

Author(s):

Ana Bastos ◽

René Orth ◽

Markus Reichstein ◽

Philippe Ciais ◽

Nicolas Viovy ◽

...

Keyword(s):

Central Europe ◽

Land Surface ◽

Vegetation Index ◽

Legacy Effects ◽

The Past ◽

Surface Models ◽

Summer Temperatures ◽

The Impact ◽

Observational Record

Extreme summer temperatures in western and central Europe have become more frequent and heatwaves more prolonged over the past decades. The summer of 2018 was one of the driest and hottest in the observational record and led to losses in vegetation productivity in central Europe by up to 50%. Legacy effects from such extreme summers can affect ecosystem functioning over several years, as vegetation slowly recovers. In 2019 an extremely dry and hot summer was registered again in the region, imposing stress conditions at a time when ecosystems were still recovering from summer 2018.Using Enhanced Vegetation Index (EVI) fields from MODIS, we evaluate how ecosystems in central Europe responded to the occurrence of two consecutive extreme summers. We find that only ca. 21% of the area negatively impacted by drought in summer 2018 fully recovered in 2019.We find that the strongest EVI anomalies in 2018/19 diverge from the long-term relationships between EVI and climate, indicating an increase in ecosystem vulnerability to heat and drought events. Furthermore, 18% of the area showed a worsening of plant status during summer 2019 in spite of drought alleviation, which could be explained by interannual legacy effects from 2018, such as impaired growth and increased biotic disturbances.Land-surface models do not simulate interannual legacy effects from summer 2018 and thereby underestimate the impact of drought in 2019 on ecosystems. The poor representation of drought-induced damage and mortality and lack of biotic disturbances in these models may result in an overestimation of the resilience and stability of temperate ecosystems in the future.

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The Terrestrial Carbon Sink

Annual Review of Environment and Resources ◽

10.1146/annurev-environ-102017-030204 ◽

2018 ◽

Vol 43 (1) ◽

pp. 219-243 ◽

Cited By ~ 35

Author(s):

T.F. Keenan ◽

C.A. Williams

Keyword(s):

Land Surface ◽

Carbon Sink ◽

Life Forms ◽

Atmospheric Composition ◽

Common Element ◽

Terrestrial Carbon ◽

The Past ◽

Terrestrial Carbon Sink ◽

Life On Earth ◽

Review Current

Life on Earth comes in many forms, but all life-forms share a common element in carbon. It is the basic building block of biology, and by trapping radiation it also plays an important role in maintaining the Earth's atmosphere at a temperature hospitable to life. Like all matter, carbon can neither be created nor destroyed, but instead is continuously exchanged between ecosystems and the environment through a complex combination of physics and biology. In recent decades, these exchanges have led to an increased accumulation of carbon on the land surface: the terrestrial carbon sink. Over the past 10 years (2007–2016) the sink has removed an estimated 3.61 Pg C year−1from the atmosphere, which amounts to 33.7% of total anthropogenic emissions from industrial activity and land-use change. This sink constitutes a valuable ecosystem service, which has significantly slowed the rate of climate change. Here, we review current understanding of the underlying biological processes that govern the terrestrial carbon sink and their dependence on climate, atmospheric composition, and human interventions.

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Substantial decrease in CO2 emissions from Chinese inland waters due to global change

Nature Communications ◽

10.1038/s41467-021-21926-6 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Lishan Ran ◽

David E. Butman ◽

Tom J. Battin ◽

Xiankun Yang ◽

Mingyang Tian ◽

...

Keyword(s):

Global Change ◽

Carbon Budget ◽

Carbon Sink ◽

Inland Waters ◽

The Tibetan Plateau ◽

The Past ◽

Widespread Implementation ◽

Lakes And Reservoirs ◽

Terrestrial Carbon Sink ◽

Global Carbon

AbstractCarbon dioxide (CO2) evasion from inland waters is an important component of the global carbon cycle. However, it remains unknown how global change affects CO2 emissions over longer time scales. Here, we present seasonal and annual fluxes of CO2 emissions from streams, rivers, lakes, and reservoirs throughout China and quantify their changes over the past three decades. We found that the CO2 emissions declined from 138 ± 31 Tg C yr−1 in the 1980s to 98 ± 19 Tg C yr−1 in the 2010s. Our results suggest that this unexpected decrease was driven by a combination of environmental alterations, including massive conversion of free-flowing rivers to reservoirs and widespread implementation of reforestation programs. Meanwhile, we found increasing CO2 emissions from the Tibetan Plateau inland waters, likely attributable to increased terrestrial deliveries of organic carbon and expanded surface area due to climate change. We suggest that the CO2 emissions from Chinese inland waters have greatly offset the terrestrial carbon sink and are therefore a key component of China’s carbon budget.

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100 Years of Earth System Model Development

Meteorological Monographs ◽

10.1175/amsmonographs-d-18-0018.1 ◽

2019 ◽

Vol 59 ◽

pp. 12.1-12.66 ◽

Cited By ~ 4

Author(s):

David A. Randall ◽

Cecilia M. Bitz ◽

Gokhan Danabasoglu ◽

A. Scott Denning ◽

Peter R. Gent ◽

...

Keyword(s):

Land Surface ◽

Model Development ◽

Ice Sheets ◽

Past Century ◽

Earth System ◽

The Past ◽

Technological Advances ◽

The Many ◽

Earth System Models ◽

Physical Realism

Abstract Today’s global Earth system models began as simple regional models of tropospheric weather systems. Over the past century, the physical realism of the models has steadily increased, while the scope of the models has broadened to include the global troposphere and stratosphere, the ocean, the vegetated land surface, and terrestrial ice sheets. This chapter gives an approximately chronological account of the many and profound conceptual and technological advances that made today’s models possible. For brevity, we omit any discussion of the roles of chemistry and biogeochemistry, and terrestrial ice sheets.

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