Contributions to accelerating atmospheric CO
            <sub>2</sub>
            growth from economic activity, carbon intensity, and efficiency of natural sinks

Canadell, Josep G.; Quéré, Corinne Le; Raupach, Michael; Field, Christopher B.; Buitenhuis, Erik T.; Ciais, Philippe; Conway, T. J.; Gillett, Nathan P.; Houghton, Richard A.; Marland, Gregg

doi:10.1073/pnas.0702737104

Cited by 1,927 publications

(1,391 citation statements)

References 23 publications

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“…The atmospheric removal process includes both dissolution of CO 2 into seawater, and the uptake of carbon by marine organisms. The ocean absorption of anthropogenic CO 2 is not evenly distributed spatially or temporally (Canadell et al 2007). …”

Section: Ocean Acidificationmentioning

confidence: 99%

A safe operating space for humanity

Rockström

Steffen

Noone

et al. 2009

Nature

9,635

5,320

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The article presents a study that investigates on the importance of identifying and quantifying planetary boundaries to prevent human activities in affecting environmental condition. The author states the industrial revolution and advancement in human civilization has caused the unstability of the environmental state that is less conducive for humans to live and affect their health condition. The author notes that planetary boundaries served a control variables to secure the safety of its citizen as well as protect the environment from shifting to dangerous levels. It also cites the different planetary boundaries, along with its impact on climate change and Earth system degradation

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Section: Ocean Acidificationmentioning

confidence: 99%

A safe operating space for humanity

Rockström

Steffen

Noone

et al. 2009

Nature

9,635

5,320

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“…The assessment also helped connect the climate issue to ecosystems services. For example, terrestrial and marine ecosystems have over the past 150 years provided an immense ecosystem service to humanity by absorbing *50% of the global carbon dioxide emissions (Canadell et al 2007).…”

Section: Natural Capital and Social-ecological Resiliencementioning

confidence: 99%

Reconnecting to the Biosphere

Folke

Jansson

Rockström

et al. 2011

AMBIO

508

320

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Humanity has emerged as a major force in the operation of the biosphere, with a significant imprint on the Earth System, challenging social-ecological resilience. This new situation calls for a fundamental shift in perspectives, world views, and institutions. Human development and progress must be reconnected to the capacity of the biosphere and essential ecosystem services to be sustained. Governance challenges include a highly interconnected and faster world, cascading social-ecological interactions and planetary boundaries that create vulnerabilities but also opportunities for social-ecological change and transformation. Tipping points and thresholds highlight the importance of understanding and managing resilience. New modes of flexible governance are emerging. A central challenge is to reconnect these efforts to the changing preconditions for societal development as active stewards of the Earth System. We suggest that the Millennium Development Goals need to be reframed in such a planetary stewardship context combined with a call for a new social contract on global sustainability. The ongoing mind shift in human relations with Earth and its boundaries provides exciting opportunities for societal development in collaboration with the biosphere-a global sustainability agenda for humanity.

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“…In section 1. show (Canadell et al 2007 andFriedlingstein et al 2010 and see Figure 1) that on 114 average terrestrial ecosystems are absorbing more than one-third of the fossil fuel 115 emissions, or ~2.7 of 7.7 Peta (10 15 ) grams carbon per year (PgC yr -1 ) . Estimates of the 116 fossil fuel, atmospheric storage, land use change and ocean uptake components of the 117 global carbon budget are based on various data sources, and are uncertain to varying 118 degrees ( Figure 1); so uncertain that we cannot "close" the global carbon budget.…”

mentioning

confidence: 99%

Characterizing 3D vegetation structure from space: Mission requirements

Hall¹,

Bergen²,

Blair³

et al. 2011

Remote Sensing of Environment

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18Human and natural forces are rapidly modifying the global distribution and 19 structure of terrestrial ecosystems on which all of life depends, altering the global carbon 20 cycle, affecting our climate now and for the foreseeable future, causing steep reductions 21 in species diversity, and endangering Earth's sustainability. 22To understand changes and trends in terrestrial ecosystems and their functioning 23 as carbon sources and sinks, and to characterize the impact of their changes on climate, 24 habitat and biodiversity, new space assets are urgently needed to produce high spatial 25 resolution global maps of the three-dimensional (3D) structure of vegetation, its biomass 26 above ground, the carbon stored within and the implications for atmospheric green house 27 gas concentrations and climate. These needs were articulated in a 2007 National 28Research Council (NRC) report (NRC, 2007) recommending a new satellite mission, 29DESDynI, carrying an L-band Polarized Synthetic Aperture Radar (Pol-SAR) and a 30 multi-beam lidar (Light RAnging And Detection) operating at 1064 nm. The objectives 31 of this paper are to articulate the importance of these new, multi-year, 3D vegetation 32 structure and biomass measurements, to briefly review the feasibility of radar and lidar 33 remote sensing technology to meet these requirements, to define the data products and 34 measurement requirements, and to consider implications of mission durations. The paper 35 addresses these objectives by synthesizing research results and other input from a broad 36 community of terrestrial ecology, carbon cycle, and remote sensing scientists and 37 working groups. We conclude that: 38(1) current global biomass and 3-D vegetation structure information is unsuitable 39 for both science and management and policy. The only existing global datasets of 40 biomass are approximations based on combining land cover type and representative 41 carbon values, instead of measurements of actual biomass. Current measurement attempts 42 based on radar and multispectral data have low explanatory power outside low biomass 43areas. There is no current capability for repeatable disturbance and regrowth estimates. 44(2) The science and policy needs for information on vegetation 3D structure can 45 be successfully addressed by a mission capable of producing (i) a first global inventory of 46 forest biomass with a spatial resolution 1km or finer and unprecedented accuracy (ii) 47 annual global disturbance maps at a spatial resolution of 1 ha with subsequent biomass 48 accumulation rates at resolutions of 1km or finer, and (iii) transects of vertical and 49 horizontal forest structure with 30 m along-transect measurements globally at 25 m 50 spatial resolution, essential for habitat characterization. 51 We also show from the literature that lidar profile samples together with wall-to-52 wall L-band quad-pol-SAR imagery and ecosystem dynamics models can work together 53 to satisfy these vegetation 3D structure and biomass measurement requirements. ...

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Contributions to accelerating atmospheric CO ₂ growth from economic activity, carbon intensity, and efficiency of natural sinks

Cited by 1,927 publications

References 23 publications

A safe operating space for humanity

A safe operating space for humanity

Reconnecting to the Biosphere

Characterizing 3D vegetation structure from space: Mission requirements

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Contributions to accelerating atmospheric CO 2 growth from economic activity, carbon intensity, and efficiency of natural sinks

Cited by 1,927 publications

References 23 publications

A safe operating space for humanity

A safe operating space for humanity

Reconnecting to the Biosphere

Characterizing 3D vegetation structure from space: Mission requirements

Contact Info

Product

Resources

About

Contributions to accelerating atmospheric CO ₂ growth from economic activity, carbon intensity, and efficiency of natural sinks