Revisiting ocean carbon sequestration by direct injection: a global carbon budget perspective

Reith, Fabian; Keller, David P.; Oschlies, Andreas

doi:10.5194/esd-7-797-2016

Cited by 17 publications

(28 citation statements)

References 45 publications

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“…However, it is not clear whether storage can be accessed fast enough or is appropriately located to meet the mitigation demands for fossil fuels with carbon capture and storage and CDR, so the use of more temporary storage sites has also been investigated. Reith et al [104] recently revisited the idea of using the deep ocean as a site to store carbon from DAC and quantified leakage rates and terrestrial and ocean carbon cycle responses. They found that their targeted atmospheric CO 2 reductions, which were equivalent to the amounts of CO 2 injected, were 16–30% lower on decadal to centennial timescales because of leakage and land and ocean carbon back fluxes that occurred in response to lowering atmospheric CO 2 .…”

Section: Cdr Method-specific Carbon Cycle Responsesmentioning

confidence: 99%

The Effects of Carbon Dioxide Removal on the Carbon Cycle

Keller

Lenton

Littleton

et al. 2018

Curr Clim Change Rep

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Increasing atmospheric CO2 is having detrimental effects on the Earth system. Societies have recognized that anthropogenic CO2 release must be rapidly reduced to avoid potentially catastrophic impacts. Achieving this via emissions reductions alone will be very difficult. Carbon dioxide removal (CDR) has been suggested to complement and compensate for insufficient emissions reductions, through increasing natural carbon sinks, engineering new carbon sinks, or combining natural uptake with engineered storage. Here, we review the carbon cycle responses to different CDR approaches and highlight the often-overlooked interaction and feedbacks between carbon reservoirs that ultimately determines CDR efficacy. We also identify future research that will be needed if CDR is to play a role in climate change mitigation, these include coordinated studies to better understand (i) the underlying mechanisms of each method, (ii) how they could be explicitly simulated, (iii) how reversible changes in the climate and carbon cycle are, and (iv) how to evaluate and monitor CDR.

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Section: Cdr Method-specific Carbon Cycle Responsesmentioning

confidence: 99%

The Effects of Carbon Dioxide Removal on the Carbon Cycle

Keller

Lenton

Littleton

et al. 2018

Curr Clim Change Rep

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“…Such open ocean deep convection in the Southern Ocean have been identified in many CMIP5 models (de Lavergne et al, ), the UVic model (Meissner et al, ; Reith et al, ) and also in the Kiel Climate Model, for which the cause could be linked to internal climate variability (Martin et al, ). An important model limitation in this respect is a coarse grid resolution, which for example prevents the correct representation of bottom water formation processes on the continental shelf and thus might favor such events (Bernardello et al, ).…”

Section: Resultsmentioning

confidence: 89%

“…CDR in UVic was simulated by injecting CO 2 at seven separate injections sites, which are located in individual grid boxes near the Bay of Biscay (42.3°N, 16.2°W), New York (36.9°N, 66.6°W), Rio de Janeiro (27.9°S, 37.8°W), San Francisco (31.5°N, 131.4°W), Tokyo (33.3°N, 142.2°E), Jakarta (11.7°S, 102.6°E), and Mumbai (13.5°N, 63°E) (Reith et al, , Figure ). Injections were simulated to be carried out at a 2900 m depth to minimize leakage and maximize retention time.…”

Section: Methodsmentioning

confidence: 99%

“…The simulated injection were based on the OCMIP carbon sequestration protocols and carried out in an idealized manner by adding CO 2 directly to the dissolved inorganic carbon (DIC) pool (Orr et al, ). Thus, we neglected any gravitational effects and assumed that the injected CO 2 instantaneously dissolved into seawater and was transported quickly away from the injection point and distributed homogenously over the entire model grid box with lateral dimensions of a few hundred kilometers and many tens of meters in the vertical direction (Reith et al, ).…”

Section: Methodsmentioning

confidence: 99%

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Integrated Assessment of Carbon Dioxide Removal

et al. 2018

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To maintain the chance of keeping the average global temperature increase below 2°C and to limit long‐term climate change, removing carbon dioxide from the atmosphere (carbon dioxide removal, CDR) is becoming increasingly necessary. We analyze optimal and cost‐effective climate policies in the dynamic integrated assessment model (IAM) of climate and the economy (DICE2016R) and investigate (1) the utilization of (ocean) CDR under different climate objectives, (2) the sensitivity of policies with respect to carbon cycle feedbacks, and (3) how well carbon cycle feedbacks are captured in the carbon cycle models used in state‐of‐the‐art IAMs. Overall, the carbon cycle model in DICE2016R shows clear improvements compared to its predecessor, DICE2013R, capturing much better long‐term dynamics and also oceanic carbon outgassing due to excess oceanic storage of carbon from CDR. However, this comes at the cost of a (too) tight short‐term remaining emission budget, limiting the model suitability to analyze low‐emission scenarios accurately. With DICE2016R, the compliance with the 2°C goal is no longer feasible without negative emissions via CDR. Overall, the optimal amount of CDR has to take into account (1) the emission substitution effect and (2) compensation for carbon cycle feedbacks.

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“…(e.g., Matthews and Caldeira, 2008;Gillet et al, 2011) occurs in these simulations due to past emissions and climate cycle feedbacks. This committed warming is at some point overlaid by leakage of injected CO 2 out of the ocean (e.g., Orr, 2004;Reith et al, 2016), as well as by oceanic and terrestrial carbon cycle feedbacks that lead to a CO 2 increase in the atmosphere and respective additional warming (see section 3.1). To diagnose the contribution from leakage, we design a leakage-free sensitivity simulation (A1_ Comitw), in which CO 2 emissions are set to zero once the 1.5°C target is reached, and no CO 2 is 160 injected into the deep ocean.…”

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confidence: 99%

Meeting climate targets by direct CO<sub>2</sub> injections: What price would the ocean have to pay?

Reith¹,

Koeve²,

Keller³

et al. 2019

Preprint

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We investigate the climate mitigation potential and collateral effects of direct injections of captured CO 2 into the deep ocean as a possible means to close the gap between an intermediate CO 2 emissions scenario and a specific temperature target, such as the 1.5°C target aimed for by the Paris Agreement. For that purpose, a suite of approaches for controlling the amount of direct CO 2 injections at 3000m water depth are implemented in an Earth System Model of intermediate complexi-10 ty.Following the representative concentration pathway RCP4.5, which is a medium mitigation CO 2 emissions scenario, cumulative CO 2 injections required to meet the 1.5°C climate goal are found to be 390 Gt C by the year 2100 and 1562 Gt C at the end of simulations, by the year 3020. The latter includes a cumulative leakage of 602 Gt C that needs to be re-injected in order to sustain the targeted global mean temperature. 15CaCO 3 sediment and weathering feedbacks reduce the required CO 2 injections that comply with the 1.5°C target by about 13 % in 2100 and by about 11 % at the end of the simulation.With respect to the injection-related impacts we find that average pH values in the surface ocean are increased by about 0.13 to 0.18 units, when compared to the control run. In the model, this results in significant increases in potential coral reef habitats, i.e., the volume of the global upper ocean (0 to 130m depth) with omega aragonite > 3.4 and ocean temperatures be-20 tween 21°C and 28°C, compared to the control run. The potential benefits in the upper ocean come at the expense of strongly acidified water masses at depth, with maximum pH reductions of about -2.37 units, relative to preindustrial, in the vicinity of the injection sites. Overall, this study demonstrates that massive amounts of CO 2 would need to be injected into the deep ocean in order to reach and maintain the 1.5°C climate target in a medium mitigation scenario on a millennium timescale, and that there is a trade-off between injection-related reductions in atmospheric CO 2 levels accompanied by reduced upper-25 ocean acidification and adverse effects on deep ocean chemistry, particularly near the injection sites.

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Revisiting ocean carbon sequestration by direct injection: a global carbon budget perspective

Cited by 17 publications

References 45 publications

The Effects of Carbon Dioxide Removal on the Carbon Cycle

The Effects of Carbon Dioxide Removal on the Carbon Cycle

Integrated Assessment of Carbon Dioxide Removal

Meeting climate targets by direct CO<sub>2</sub> injections: What price would the ocean have to pay?

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Revisiting ocean carbon sequestration by direct injection: a global carbon budget perspective

Cited by 17 publications

References 45 publications

The Effects of Carbon Dioxide Removal on the Carbon Cycle

The Effects of Carbon Dioxide Removal on the Carbon Cycle

Integrated Assessment of Carbon Dioxide Removal

Meeting climate targets by direct CO&lt;sub&gt;2&lt;/sub&gt; injections: What price would the ocean have to pay?

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Meeting climate targets by direct CO<sub>2</sub> injections: What price would the ocean have to pay?