Interactions between reducing CO
            <sub>2</sub>
            emissions, CO
            <sub>2</sub>
            removal and solar radiation management

Vaughan, Naomi E.; Lenton, Timothy M.

doi:10.1098/rsta.2012.0188

Cited by 11 publications

(13 citation statements)

References 39 publications

(108 reference statements)

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“…Our land-use change emissions are above the estimated mean but well within the error range (Friedlingstein et al 2010). In previous work (Vaughan and Lenton 2012), a lower estimate of land-use change emissions was used for (Houghton 2008), but the absolute values agree well in 2005.…”

Section: Climate Changesupporting

confidence: 65%

“…For our 'baseline' fossil fuel emissions after 2000 we follow an existing mitigation scenario (Vaughan and Lenton 2012), using estimated fossil fuel (plus cement production) emissions for al 2008), followed by a 1.7% yr −1 increase from 2005 to 2015 (the long term mean growth rate over the last 25 years), after which mitigation activity begins in earnest and it takes 40 years to transition to a 1.7% yr −1 decrease in emissions. This scenario gives peak fossil fuel emissions of 11.35 PgC y −1 in 2035, declining to 10.3 PgC y −1 in 2050.…”

Section: Climate Changementioning

confidence: 99%

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Scenarios for future biodiversity loss due to multiple drivers reveal conflict between mitigating climate change and preserving biodiversity

Powell

Lenton

2013

Environ. Res. Lett.

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We assess the potential for future biodiversity loss due to three interacting factors: energy withdrawal from ecosystems due to biomass harvest, habitat loss due to land-use change, and climate change. We develop four scenarios to 2050 with different combinations of high or low agricultural efficiency and high or low meat diets, and use species-energy and species-area relationships to estimate their effects on biodiversity. In our scenarios, natural ecosystems are protected except when additional land is necessary to fulfil the increasing dietary demands of the global population. Biomass energy with carbon capture and storage (BECCS) is used as a means of carbon dioxide removal (CDR) from the atmosphere (and offsetting fossil fuel emissions). BECCS is based on waste biomass, with the addition of bio-energy crops only when already managed land is no longer needed for food production.Forecast biodiversity loss from natural biomes increases by more than a factor of five in going from high to low agricultural efficiency scenarios, due to destruction of productive habitats by the expansion of pasture. Biodiversity loss from energy withdrawal on managed land varies by a factor of two across the scenarios. Biodiversity loss due to climate change varies only modestly across the scenarios. Climate change is lowest in the 'low meat high efficiency' scenario, in which by 2050 around 660 million hectares of pasture are converted to biomass plantation that is used for BECCS. However, the resulting withdrawal of energy from managed ecosystems has a large negative impact on biodiversity. Although the effects of energy withdrawal and climate change on biodiversity cannot be directly compared, this suggests that using bio-energy to tackle climate change in order to limit biodiversity loss could instead have the opposite effect.

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Section: Climate Changesupporting

confidence: 65%

Section: Climate Changementioning

confidence: 99%

Scenarios for future biodiversity loss due to multiple drivers reveal conflict between mitigating climate change and preserving biodiversity

Powell

Lenton

2013

Environ. Res. Lett.

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“…30 The carbon level is the important indicator of soil laborious rising, as well as a way of mitigating global warming by soil carbon sequestration. 31 Therefore, there are vital production and ecological benefit to degrade straw. It can provide a large number of high quality organic fertilizer for agriculture by straw decomposition using microorganism, It is not only beneficial to the economy, environment and society, but also provides a reasonable way of reusing the straw.…”

Section: Discussionmentioning

confidence: 99%

The isolation and functional identification on producing cellulase ofPseudomonas mendocina

et al. 2016

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The straw can be degraded efficiently into humus by powerful enzymes from microorganisms, resulting in the accelerated circulation of N,P,K and other effective elements in ecological system. We isolated a strain through screening the straw degradation strains from natural humic straw in the low temperature area in northeast of china, which can produce cellulase efficiently. The strain was identified as Pseudomonas mendocina by using morphological, physiological, biochemical test, and molecular biological test, with the functional clarification on producing cellulase for Pseudomonas mendocina for the first time. The enzyme force constant Km and the maximum reaction rate (Vmax) of the strain were 0.3261 g/L and 0.1525 mg/(min.L) through the enzyme activity detection, and the molecular weight of the enzyme produced by the strain were 42.4 k D and 20.4 k D based on SDS-PAGE. The effects of various ecological factors such as temperature, pH and nematodes on the enzyme produced by the strain in the micro ecosystem in plant roots were evaluated. The result showed that the optimum temperature was 28 C, and the best pH was 7.4»7.8, the impact heavy metal was Pb 2C and the enzyme activity and biomass of Pseudomonas mendocina increased the movement and predation of nematodes.

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“…The idea has also informed a range of policy messages. In numerous academic papers (see, e.g., Brovkin et al, ; Clark et al, ; Pidgeon et al, ; Vaughan & Lenton, ) and high‐profile commentary pieces (Appell, ; Dean, ; Klein, ; Pierrehumbert, ; Plumer, ), it is claimed that once deployed, SRM would need to be maintained for centuries or even millennia to avoid the risk of termination shock. It has also been argued that due to the risk of termination shock, SRM should only be considered an option of last resort for emergency use (Llanillo et al, ) or that the cooling from any deployment of SRM should be limited to a level that would not cause a dangerous temperature rebound in the event of termination (Kosugi, ).…”

Section: Introductionmentioning

confidence: 99%

The Risk of Termination Shock From Solar Geoengineering

2018

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If solar geoengineering were to be deployed so as to mask a high level of global warming, and then stopped suddenly, there would be a rapid and damaging rise in temperatures. This effect is often referred to as termination shock, and it is an influential concept. Based on studies of its potential impacts, commentators often cite termination shock as one of the greatest risks of solar geoengineering. However, there has been little consideration of the likelihood of termination shock, so that conclusions about its risk are premature. This paper explores the physical characteristics of termination shock, then uses simple scenario analysis to plot out the pathways by which different driver events (such as terrorist attacks, natural disasters, or political action) could lead to termination. It then considers where timely policies could intervene to avert termination shock. We conclude that some relatively simple policies could protect a solar geoengineering system against most of the plausible drivers. If backup deployment hardware were maintained and if solar geoengineering were implemented by agreement among just a few powerful countries, then the system should be resilient against all but the most extreme catastrophes. If this analysis is correct, then termination shock should be much less likely, and therefore much less of a risk, than has previously been assumed. Much more sophisticated scenario analysis—going beyond simulations purely of worst‐case scenarios—will be needed to allow for more insightful policy conclusions.

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Interactions between reducing CO ₂ emissions, CO ₂ removal and solar radiation management

Cited by 11 publications

References 39 publications

Scenarios for future biodiversity loss due to multiple drivers reveal conflict between mitigating climate change and preserving biodiversity

Scenarios for future biodiversity loss due to multiple drivers reveal conflict between mitigating climate change and preserving biodiversity

The isolation and functional identification on producing cellulase ofPseudomonas mendocina

The Risk of Termination Shock From Solar Geoengineering

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Interactions between reducing CO 2 emissions, CO 2 removal and solar radiation management

Cited by 11 publications

References 39 publications

Scenarios for future biodiversity loss due to multiple drivers reveal conflict between mitigating climate change and preserving biodiversity

Scenarios for future biodiversity loss due to multiple drivers reveal conflict between mitigating climate change and preserving biodiversity

The isolation and functional identification on producing cellulase ofPseudomonas mendocina

The Risk of Termination Shock From Solar Geoengineering

Contact Info

Product

Resources

About

Interactions between reducing CO ₂ emissions, CO ₂ removal and solar radiation management