1. Introduction
The Intergovernmental Panel on Climate Change (IPCC) has stressed that the ‘deployment of carbon dioxide removal (CDR) to counterbalance hard-to-abate residual emissions is unavoidable if net zero CO2 [carbon dioxide] or GHG [greenhouse gas] emissions are to be achieved’.Footnote 1 This would necessitate the large-scale deployment of activities to capture CO2 from the atmosphere and store it durably in geological formations, terrestrial and marine ecosystems, or products.Footnote 2 Currently, the European Union (EU) is not on track to deliver the required levels of CDR deployment.Footnote 3 CDR in terrestrial ecosystems has declined in recent years, and no significant industrial CDR is currently operating in the EU.Footnote 4 Extensive investment is required, including from the private sector, to achieve CDR development and deployment on a large scale. One option discussed in policy and literature to provide sufficient financial resources is the integration of carbon removal credits (CRCs) into the EU Emissions Trading System (EU ETS).Footnote 5 Integrating CRCs into the EU ETS, one of the largest compliance markets globally, may provide the CDR sector in the EU with the necessary financial boost to scale up.
CDR refers to ‘anthropogenic activities removing CO2 from the atmosphere and durably storing it in geological, terrestrial or ocean reservoirs, or in products. It includes existing and potential anthropogenic enhancement of biological, geochemical or chemical CO2 sinks, but excludes natural CO2 uptake not directly caused by human activities’.Footnote 6 Numerous CDR technologies are available. The majority of current CDR efforts come from conventional land management, particularly afforestation and soil carbon sequestration.Footnote 7 Only a small fraction stems from novel CDR technologies, such as direct air capture with carbon storage (DACCS) or bioenergy with carbon capture and storage (BECCS), which store carbon in geological formations.Footnote 8
This article investigates two concerns that need to be addressed during the process of integrating CRCs into the EU ETS: permanence and liability.Footnote 9 Available CDR technologies demonstrate different levels of permanence.Footnote 10 Permanence describes the duration for which atmospheric CO2 has been removed through CDR and remains stored.Footnote 11 The level of permanence is determined by the timespan within which CO2 is re-emitted (reversed).Footnote 12 The varying levels of permanence among CDR technologies pose major challenges for the integration of CRCs into the EU ETS. Firstly, more permanent CDR is more significant from a climate repair perspective than less permanent CDR, whereby short-term storage of carbon still entails benefits.Footnote 13 Secondly, it is important to establish some kind of equivalence between CRCs to achieve broad fungibility of carbon assets under the EU ETS.Footnote 14 Fungibility is important in promoting a liquid market that can provide sufficient funds for CDR deployment.Footnote 15 Lastly, if CRCs issued for CDR with low levels of permanence were integrated into the EU ETS, the environmental integrity of the EU ETS could be jeopardized. According to the understanding of this article, environmental integrity is safeguarded if the engagement in trading CRCs under the EU ETS leads to aggregated emissions covered by the EU ETS that are equal to or lower than those in a situation where the transfers did not occur.Footnote 16 The environmental integrity of the EU ETS would be undermined if carbon stored through CDR, for which CRCs were issued, were to be reversed without complete compensation for re-emissions. Considering these aspects collectively, the primary concern of the integration process would be to account for varying levels of permanence while ensuring wide fungibility and preserving the environmental integrity of the EU ETS.
Liability is a legal tool that can recognize and manage permanence issues and becomes relevant when CDR projects reverse. However, liability should not be seen as a general solution to the permanence issue but rather as a legal safeguard for exceptional circumstances. Situations in which liability becomes necessary ideally should be avoided, as liability itself poses many risks. These include enforcement challenges and the risk that the liability system could be overwhelmed if CDRs were to be reversed simultaneously on a large scale.Footnote 17 In the context of this article, ‘liability’ refers only to the narrow obligation of submitting emissions allowances or removal credits under the EU ETS to replace those affected by a reversal event (so-called ‘climate liability’). The author acknowledges that other forms of liability are crucial in addressing potential harm and damage stemming from CDR technologies – in particular, liability related to environmental harm and liability under tort law. These are governed by distinct legal frameworks: liability under tort law is regulated under national legislation; liability in relation to environmental harm is regulated under the EU Environmental Liability Directive.Footnote 18 Both have no direct implications for the EU ETS as the EU ETS does not address these forms of liability. Therefore, they are beyond the scope of this article, which focuses on permanence and liability in the context of a possible integration of CRCs into the EU ETS.
The normative question of whether CRCs should be integrated into the EU ETS requires a broad assessment that exceeds the scope of this research. This study, therefore, is conducted on the assumption that integration of CRCs into the EU ETS will take place. The findings of this study on permanence and liability can be considered not only after integration has been chosen but also in the initial decision process to integrate CRCs into the EU ETS. Additional integration challenges that will be important for an overarching initial assessment have been addressed in dedicated literature, such as moral hazards and mitigation deterrence,Footnote 19 additionality,Footnote 20 monitoring reporting and verification processes,Footnote 21 carbon leakage,Footnote 22 and downward pressure on the overall carbon price.Footnote 23
The article analyzes various approaches to the issues of permanence and liability. These are the Kyoto Protocol's Clean Development Mechanism (CDM),Footnote 24 voluntary carbon markets, and tonne-year accounting. Under the CDM, removal projects in developing countries could generate temporary carbon credits that developed state parties could buy and use towards compliance purposes of their emissions reduction commitments under the Kyoto Protocol.Footnote 25 These temporary credits had an expiration date and needed to be replaced to address concerns regarding the limited permanence of removal projects.Footnote 26 Under voluntary carbon markets, a different approach is used. Participants generally conclude long-term project contracts, typically ranging from 3 to 100 years, to ensure some degree of permanence.Footnote 27 If the stored carbon or parts of it reverse before the project period ends, liability and risk-buffer accounts are intended to ensure that it is being compensated.Footnote 28 Tonne-year accounting is an approach to CDR accounting that involves issuing credits incrementally over the project period.Footnote 29 After a certain number of so-called ‘carbon tonne-years’ of storage have been accumulated, a certain number of permanent credits are issued, which cannot be revoked.Footnote 30 Based on the lessons learned from this analysis, the article formulates legal considerations on the challenges of permanence and liability that may guide a legislative proposal for an EU legislative act to integrate CRCs into the EU ETS.
Section 2 describes CDR technologies, their regulatory status quo in the EU, and the EU ETS. Challenges related to the integration of CRCs into the EU ETS are identified in Section 3, with a specific focus on permanence and liability. Section 4 analyzes the CDM, voluntary carbon markets, and tonne-year accounting to identify lessons for integration. Section 5 presents legal considerations to inform a potential legislative proposal for the integration of CRCs into the EU ETS, and Section 6 concludes.
2. Technical and Regulatory Context
To further delineate the scope of this article, this section will define CDR and differentiate it from related technologies. It will then explain the required scale of CDR deployment to fulfil global climate goals. Following that, it will outline the foundations of the EU ETS and the current regulation of CDR in the EU.
2.1. Distinguishing CDR from Related Technologies
Within the realm of ‘greenhouse gas removal’ or ‘GHG removal’, which refers to the ‘withdrawal of a GHG and/or a precursor from the atmosphere by a sink’,Footnote 31 CDR consists of those measures that target the removal and storage of CO2.Footnote 32 GHG removal encompasses CDR measures but is broader in scope, referring to the set of technologies that remove and store any GHGs from the atmosphere.Footnote 33 This article will generally refer to CDR as distinct from GHG removal, in line with the practice of EU institutions.Footnote 34
Carbon capture and storage (CCS) and carbon capture and utilization (CCU) can form an integral part of CDR technologies when they are applied to CO2 that has been captured from the atmosphere.Footnote 35 The capture of CO2 from the atmosphere can be achieved either indirectly through biomass or directly from the air.Footnote 36 CCS and CCU do not qualify as CDR technologies if they are applied to CO2 from fossil fuel use, as no CO2 is removed from the atmosphere.Footnote 37 CCS can be defined as a ‘process in which a relatively pure stream of CO2 from industrial and energy-related sources is separated (captured), conditioned, compressed and transported to a storage location for long-term isolation from the atmosphere’.Footnote 38 CCU is referred to as a ‘process in which CO2 is captured and then used to produce a new product’.Footnote 39 For example, CCS is an essential part of CDR when used in conjunction with bioenergy (BECCS). In contrast, CCS combined with a coal-fired power plant does not remove any CO2 from the atmosphere and therefore cannot be considered as CDR. Only when CCS and CCU are components of CDR technologies, are they relevant to the scope of this article.
2.2. Required Levels of Carbon Dioxide Removal
Although GHG emissions reductions are the most important measure for climate change mitigation, GHG removal, of which CDR technologies are the most relevant, will be necessary to achieve the global temperature increase targets of the Paris Agreement:Footnote 40 specifically, if we intend to hold ‘the increase in the global average temperature to well below 2°C above pre-industrial levels and pursuing efforts to limit the temperature increase to 1.5°C above pre-industrial levels’.Footnote 41 To reach this objective, the Paris Agreement stipulates that parties must aim to ‘achieve a balance between anthropogenic emissions by sources and removals by sinks of greenhouse gases in the second half of this century’.Footnote 42 Emissions reductions alone are not sufficient to avoid catastrophic climate change, as scientific research indicates.Footnote 43 Of the scenarios in integrated assessment models considered at the time of the Paris Agreement, 87% of those that aim to achieve 2°C, and all those that expect 1.5°C, relied partly on GHG removal to reach the temperature targets of the Paris Agreement.Footnote 44 Without GHG removal, very drastic emissions reductions would be necessary to reach 2°C, while 1.5°C would remain out of reach.Footnote 45 According to a report from the National Academies of Sciences, CDR efforts must annually remove 10 gigatons (Gt) CO2 by the late 2050s and 20 Gt CO2 by the late 2090s globally to limit global warming to below 2°C.Footnote 46 For comparison, global net anthropogenic GHG emissions amounted to 59 Gt CO2-eq in 2019.Footnote 47 The need to scale up CDR was also emphasized in the Paris Agreement's first global stocktake concluded in the United Arab Emirates in 2023. The document ‘calls on Parties’ to contribute to the global efforts to accelerate removal technologies such as CCS and CCU, particularly in hard-to-abate sectors.Footnote 48
CDR technologies are not only essential in helping to reach net zero emissions but also for maintaining a net zero status by removing residual hard-to-abate emissions, including those from sectors such as agriculture and aviation. After complete decarbonization, CDR could deliver genuine removal by drawing down ‘legacy carbon’ remaining in the atmosphere from past emissions.Footnote 49
The Report on the State of Carbon Dioxide Removal by Smith and co-authors finds a ‘yawning gap’ between the extent to which countries are planning CDR deployment and what will be required to achieve the global temperature increase targets of the Paris Agreement.Footnote 50 This also holds for the EU, which is currently not on track to deliver the required level of CDR deployment.Footnote 51
2.3. The European Union Emissions Trading System
The EU ETS was set up in 2005 as the world's first international emissions trading system. It operates in all EU Member States, as well as Liechtenstein, Iceland, and Norway. The EU ETS currently covers installations in the power sector and manufacturing industry, and airlines operating between the participating countries, which make up for approximately 40% of the EU's GHG emissions.Footnote 52 It is one of the largest emissions trading systems worldwide.Footnote 53 The EU agreed in 2023 to expand the EU ETS to other sectors, such as international aviation and maritime transport, and to create a separate emissions trading system for fuel combustion in buildings, road transport, and additional sectors (so-called ‘EU ETS II’), which will become operational from 2027 onwards.Footnote 54 The European Commission referred to the EU ETS as a ‘cornerstone’ of the EU's strategy to reduce GHG emissions.Footnote 55 The EU ETS regulatory framework is set out in the EU ETS Directive, which has been updated over time.
The EU ETS is a ‘cap and trade’ system, which sets a cap on the absolute quantity of certain GHG emissions from entities covered by the system.Footnote 56 Entities covered by the system must annually surrender sufficient emissions allowances to cover their emissions. Failure to do so may result in heavy penalties. The number of allowances available corresponds with the cap.Footnote 57 The cap, and consequently, the total number of allowances, is reduced over time to decrease overall emissions. As a result of supply and demand, the price of emissions allowances is likely to rise, providing an incentive to reduce emissions and invest in low-carbon technologies.Footnote 58 Entities covered by the system buy allowances at auctions or, in certain cases, receive them for free.Footnote 59 Moreover, allowances can be traded among participants. The market approach is intended to ensure that emissions are reduced in the most cost-effective way.Footnote 60 Participants in the EU ETS were able to use international credits from the Kyoto Protocol's CDM to fulfil part of their obligations under the EU ETS until 2020.Footnote 61 This was achieved by linking the EU ETS and the Kyoto project-based mechanism.Footnote 62
Eventually, the cap will reach zero, putting an end to the supply of emissions allowances.Footnote 63 Entities covered by the system could no longer purchase allowances to cover their GHG emissions. This could become problematic as some GHG emissions will be difficult or even impossible to mitigate.Footnote 64 Integrating CRCs into the EU ETS emerges as a solution to cover GHG emissions from these so-called hard-to-abate sectors.Footnote 65
2.4. The Current Regulatory Framework of CDR in the EU
At present, the EU ETS does not include a mechanism for the creation of additional allowances or credits through CO2 removal.Footnote 66 Article 2(1) of the EU ETS Directive limits the scope of the directive to positive emissions, excluding negative emissions technologies.
The European Commission published a legislative proposal for a regulation on a carbon removals certification framework in November 2022.Footnote 67 The proposed regulation aims to establish a voluntary Union certification framework for carbon removals, with the objective of incentivizing the uptake of high-quality carbon removals.Footnote 68 It lays down quality criteria, rules for verification and certification, and rules for the functioning and recognition of certification schemes.Footnote 69 This framework intends to form a foundation that policymakers can draw upon to incentivize and govern CDR technologies. It does not currently facilitate the integration of CRCs into the EU ETS. Nevertheless, it could potentially serve as a regulatory foundation for another legislative proposal aimed at integrating CRCs into the EU ETS that were certified under an EU carbon removals certification framework. Participants in the EU ETS would be able to purchase CRCs and use them towards fulfilling their obligations under the EU ETS, or at least parts of it. This option is already foreseen in the EU ETS Directive.Footnote 70 Article 30(5)(a) of the EU ETS Directive mandates the EU Commission to report by 31 July 2026 ‘how negative emissions resulting from greenhouse gases that are removed from the atmosphere and safely and permanently stored could be accounted for and how those negative emissions could be covered by emissions trading’.Footnote 71
In contrast, CCS is already subject to a detailed regulatory framework. The EU ETS Directive provides incentives for the deployment of CCS because the obligation to surrender allowances does not arise for emissions that are verified as captured and transported to an authorized facility for permanent storage.Footnote 72 The CCS Directive stipulates, inter alia, provisions for permits and obligations for the operation, closure and post-closure of sites.Footnote 73 In the case of carbon leakage, the operator must notify the competent authority and must take corrective measures.Footnote 74 Moreover, the operator must surrender EU ETS allowances as CO2 capture, transport, and storage facilities are covered by the EU ETS.Footnote 75 Further liability rules for operators are stipulated in the Environmental Liability Directive and at the Member State level.Footnote 76 Most liabilities arising in relation to the storage site are transferred to the competent authority after the storage site has been closed and certain conditions apply so-called risk transfer.Footnote 77 These conditions are (i) that all available evidence indicates that the stored CO2 will be completely and permanently contained, and (ii) that a minimum period has passed (not less than 20 years), which is to be determined by the competent authority.Footnote 78 The operator can be held liable, even though the risk transfer has taken place, if the clawback provision pursuant to Article 18(7) applies. This provision allows for the post-transfer recovery of costs if the operator has been at fault, which includes cases of deficient data, wilful deceit, or a failure to exercise due diligence.Footnote 79 Before the risk transfer has taken place, the CCS operator is exclusively liable for any CO2 leakage. For CCS projects under the CDM, a transfer of liability from the project operator to the host state would take place under similar conditions.Footnote 80
3. Challenges for Integrating CRCs into the EU ETS
There are several aspects to consider when integrating CRCs into the EU ETS with regard to permanence and liability, such as the fungibility of CRCs, the benefits of more permanent CDR, the environmental integrity of the EU ETS, and reversal risk management. The following section attempts to identify these aspects and draw conclusions to guide a legislative proposal.
3.1. Why Permanence Matters
Public policy needs to define parameters to determine equivalence between CRCs stemming from different CDR technologies and emissions allowances.Footnote 81 Broad fungibility is important for promoting a liquid market that provides sufficient investments to scale up CDR at a high rate.Footnote 82 The only common parameter that seems to apply to these units is one metric tonne of CO2 equivalent.Footnote 83 However, it is difficult to define scientifically the equivalence between CO2 captured and stored through different CDR technologies and avoided CO2 emissions.Footnote 84 This is because the various CDR technologies available differ significantly regarding their levels of permanence.Footnote 85 For instance, carbon theoretically can be stored indefinitely in terrestrial ecosystems, such as forests, peatlands, and soils.Footnote 86 However, the risk of reversal as a result of human action – such as deforestation, or natural disturbances, including fire and drought – is relatively high.Footnote 87 Carbon stored in biochar in soil, on the other hand, will reverse after a certain period.Footnote 88 Some works suggest it can persist on a centennial scale.Footnote 89 CO2 stored in well-selected and well-managed geological formations through BECCS or DACCS can be stored for a thousand years or longer.Footnote 90 Under these conditions, reversal is much less likely to occur, although it remains a concern.Footnote 91 The quantity of CO2 escaping from appropriately selected and managed geological formations will ‘very likely’ remain below 1% over the first 100 years.Footnote 92
Generally, more permanent CDR technologies are more significant from a climate repair perspective than less permanent technologies.Footnote 93 This is because, in the event of a reversal, the original benefits of the CDR project are reversed to some extent, depending on when the reversal occurs.Footnote 94 However, the value of temporary removal of CO2 is not zero.Footnote 95 A CDR project does not have to remove a tonne of CO2 indefinitely to effectively offset a tonne of CO2 emitted. This is because the bulk of the original emission does not stay in the atmosphere eternally, as atmospheric CO2 is being sequestered through natural processes over time. Only a fraction of the CO2 emitted remains in the atmosphere essentially forever.Footnote 96 Even if the removed CO2 reverses before the original emission has fully decayed, a certain percentage of CO2 has already been taken from the atmosphere, thus reducing the global net atmospheric CO2 concentration. For instance, a CDR project that reverses after 100 years has the net effect of a 39% reduction relative to no CDR. This increases to 66% after 1,000 years.Footnote 97 Moreover, temporary removal of CO2 can buy humanity time to develop methods to permanently remove CO2.Footnote 98 Therefore, CDR technologies with low levels of permanence entail benefits.Footnote 99
In other words, CDR technologies with high levels of permanence are more valuable than those with low levels of permanence, but CDR technologies with low levels of permanence still provide benefits.
3.2. Risks of Low Levels of Permanence for Integration
Integrating CRCs issued for CDR technologies with low levels of permanence into the EU ETS could pose two main challenges.
Firstly, by compensating for emissions with CDR that have low levels of permanence, the environmental integrity of the EU ETS could be jeopardized. For instance, if CRCs can be used for compliance under the EU ETS, one tonne of CO2 can be emitted by submitting a CRC. This would be acceptable from a climate perspective because the tonne of CO2 emitted is offset by the removal. However, this calculation holds only if the removal is sufficiently permanent. If the captured and stored tonne of CO2 reverses after a certain period, a certain net amount of CO2 is added to the atmosphere.Footnote 100 The transfers of CRCs would then lead to an increase in aggregated global emissions and undermine the environmental integrity of the system. This result could be addressed through regulations on liability. However, liability presents its own set of challenges and should not be the primary mechanism to manage permanence issues, as further discussed in the next section.
Secondly, an EU legislative act that does not consider the different levels of permanence would create economic incentives to deploy currently cheaper and less permanent CDR technologies.Footnote 101 Therefore, permanent CDR technologies would not be scaled up and the goal of reaching carbon neutrality in the long term would be threatened. Less permanent CDR technologies, such as afforestation, are generally cheaper, whereas most engineering-based approaches that show high levels of permanence, such as BECCS and DACCS, are currently relatively expensive.Footnote 102 This is problematic, as sufficient investments in engineering-based CDR are critical for reaching net zero emissions and maintaining it.Footnote 103
Therefore, an EU legislative act must consider the different levels of permanence of the CDR technologies when integrating CRCs into the EU ETS.
3.3. Liability as a Risk Management System
A common approach under the CCS Directive,Footnote 104 and under many voluntary carbon schemes,Footnote 105 is to hold the project operator liable for any re-emissions. There are several mechanisms available to hedge reversal risks. In many voluntary carbon schemes, project operators have to retain a certain portion of the received credits in a risk buffer account, often ranging from 10 to 40%.Footnote 106 Under some schemes, the portion relies on the project's ex ante risk rating.Footnote 107 This portion cannot be sold for a predetermined period and should be used to compensate for reversals.Footnote 108 Risk pooling is a variant of risk buffer accounts, where multiple CDR projects keep a common buffer account. An advantage of this pooled approach is that individual contributions may be less than those for individual buffer accounts.Footnote 109 Moreover, there are non-permanence insurances that cover a portfolio of different CDR projects.Footnote 110 A combination of these approaches is also possible.
Situations where liability becomes necessary should be avoided in the first place as liability itself entails many risks. For instance, it can be very challenging to identify the relevant emitter and enforce the liability against them, depending on with whom the liability lies and the time frame.Footnote 111 Companies may be insolvent, untraceable, or no longer exist.Footnote 112
Moreover, if CDR were to reverse simultaneously on a large scale, exacerbated by extreme weather events caused by climate change in the future, the liability system could be at risk of collapsing.Footnote 113 For instance, in the event of catastrophic forest fires, many CDR projects for which CRCs have been issued could be reversed. The liable entities, most likely the project operators, would have to compensate for the climate damage by surrendering CRCs or emissions allowances. If such reversal events were sufficiently large, the demand for CRCs and emissions allowances would soar, most likely driving up prices significantly and potentially pushing many project operators into bankruptcy. This will become even more problematic as the number of emissions allowances in the market will continue to decline. Once there are no more emissions allowances left in the EU ETS, CRCs issued for failed CDR can be replaced only with other CRCs. Depending on the availability of CRCs and demand at the time, this could be a costly undertaking. Risk buffer accounts and non-permanent insurance can increase the resilience of the system, but they too have limitations. The question then becomes, who is going to ensure that the reversed CO2 is compensated for if the project operator fails? Most likely, this will be the responsibility of the Member States. In the event that the reversals are not fully offset, the environmental integrity of the EU ETS would be undermined, as more CO2 would have been emitted than in a situation where there was no trading of CRCs. This is because integrating CRCs would expand the total gross GHG emissions permissible under the EU ETS. This expansion would be acceptable as the additional GHG emissions would be offset by CDR, leaving the net GHG emissions trajectory unaffected. Nonetheless, this reasoning remains valid only if the CO2 is stored permanently. Should the stored CO2 reverse prematurely, the original emission is no longer (fully) offset. In this scenario, more GHG emissions would have occurred than in a scenario where no CRCs were traded under the EU ETS and the environmental integrity of the system would be disrupted.
For these reasons, liability should be seen as a legal safeguard for exceptional circumstances and not as a general solution for the permanence problem. Situations that give rise to liability need to be prevented from the outset to avoid the above issues in advance.Footnote 114
4. Analysis of Approaches to Integration from Practice and Literature
There are various approaches considered to address the permanence issue. This article analyzes the Clean Development Mechanism, voluntary carbon markets, and tonne-year accounting to identify lessons for the EU ETS.
4.1. Clean Development Mechanism
Under the former Clean Development Mechanism of the Kyoto Protocol, removal projects in developing countries (non-Annex I parties) could generate temporary carbon credits.Footnote 115 Each temporary credit would represent a tonne of CO2-equivalent removed. Developed state parties (Annex I parties) could buy and use these temporary credits to meet part of their emissions reduction commitments under the Kyoto Protocol. These temporary credits would expire after a certain time because of concerns regarding the limited permanence of removal projects. Eventually, the temporary credits had to be replaced by the purchaser with permanent credits at a one-to-one ratio.Footnote 116
Only a limited range of CDR technologies, primarily afforestation and reforestation, were eligible under the CDM.Footnote 117 An important reason to make credits temporary was concern about the potential reversibility of the stored carbon. Afforestation and reforestation were considered temporary solutions to gain time in which to develop the technologies to effectively mitigate climate change.Footnote 118 They were not regarded as long-term solutions that could generate credits equivalent to credits from emissions reduction projects. This practice ensured the environmental integrity of the CDM regarding removal projects, as no emissions could be offset by CDR in the long term. This does not pertain to problems regarding the accuracy of monitoring and additionality of removal projects as they are outside the scope of this study.
Temporary credits represented only a marginal piece of the CDM carbon market. They were excluded from most emissions trading schemes, such as the EU ETS, particularly because of concerns about permanence, the accuracy of monitoring, and liability.Footnote 119 For example, temporary credits would have created liability risks under the EU ETS because a company that wanted to cease operations could sell its permanent credits and replace them with cheaper temporary credits. If the company ceased to exist, it could no longer replace the temporary credits with permanent credits. Consequently, the Member State in which the company operated had to cover the expired credits.Footnote 120
Investments in CDR projects under the CDM were very weak;Footnote 121 this was mainly as a result of the restrictive regulatory approach under the CDM.Footnote 122 Temporary credits were complex and not fungible with other carbon assets.Footnote 123 They were not admitted under the EU ETS, which was the largest market for CDM credits.Footnote 124 They were difficult to manage and transfer because of the obligation to replace them.Footnote 125 Perhaps most importantly, temporary carbon sequestration was not valued as the replacement ratio with permanent credits was one-to-one.Footnote 126
4.2. Voluntary Carbon Markets
Many companies purchase carbon credits on voluntary carbon markets to offset their emissions.Footnote 127 Voluntary carbon credits are issued by carbon standardsFootnote 128 for the reduction or removal of GHG emissions.Footnote 129 Each carbon standard sets its own rules with which CDR projects must comply to be certified. The quality and price of the credits can consequently vary significantly, as each project uses a specific technology and shows disparate levels of permanence.Footnote 130 In 2021, the value of voluntary carbon market transactions exceeded US$ 1 billion, more than doubling since 2020.Footnote 131 Currently, they mainly finance nature-based solutions such as afforestation or soil carbon sequestration in the removal sector.Footnote 132
A typical approach taken by participants in voluntary carbon markets to ensure some degree of permanence is through long-term project contracts, typically ranging from 3 to 100 years.Footnote 133 The length of these contract periods is based on contractual realities rather than any notional definition of permanence or atmospheric residence of CO2.Footnote 134 Contractual realities in this sense refer to the period deemed appropriate to require private parties to ensure the safe storage of carbon. The carbon credits are typically issued at the beginning of a project and the carbon must remain stored during the contract period.
If any part of the carbon reverses before the project period ends, liability and risk-buffer accounts are intended to ensure the environmental integrity of the system. Many standards distinguish between intentional and unintentional reversal.Footnote 135 In the case of unintentional reversal, such as wildfires, the credits from the (pooled) risk buffer are generally used to replace the loss. If the reversal was caused intentionally, such as through the resumption of deforestation by the project operator, all previously issued credits must generally be replaced by the project operator. Thus, the project operator loses all the benefits it has received.Footnote 136
The approach of voluntary carbon markets does not ensure that carbon is removed and stored for a significant period in atmospheric terms. Most project contracts stipulate project lengths of up to 100 years, yet many contract periods are significantly shorter.Footnote 137 From an atmospheric perspective, 100 years is a relatively short period because CO2 resides in the atmosphere for much longer.Footnote 138 As mentioned above, the storage of CO2 for 100 years has the effect of reducing atmospheric carbon stock by just 39% compared with no CDR.Footnote 139 However, from a contractual perspective, 100 years is a long period of time as many project operators are not willing to or are not capable of committing further into the future.
The practice of many voluntary carbon standards to issue credits at the beginning of the project period could jeopardize the stability of the system. Large-scale simultaneous reversals could push the risk management system of liability and risk buffer accounts to its limits. The possibility of such a scenario, coupled with relatively short contract periods, forges a vulnerability that questions the environmental integrity of the system.
Furthermore, most voluntary carbon schemes do not reward temporary carbon storage if it is reversed intentionally before the end of the contract period. In this case, temporary carbon storage is worthless even though the project did create some climate benefits and investments were made. Consider, for example, a reforestation project with a contract period of 100 years. The project reverses fully after 90 years as a result of the resumption of deforestation by the project operator. The project operator must then replace all the credits it has received for this project and the investments that it has made are lost. One could argue that this result is justified to prevent project operators from intentionally undoing CO2 storage. However, the project operator might have substantial impending reasons, including a financial crisis, and has already created some benefits by storing CO2 for 90 years. This ‘all-or-nothing approach’ may deter the deployment of CDR projects at the forefront.
4.3. Tonne-Year Accounting
Another approach, referred to in the literature as ‘tonne-year accounting’, involves issuing credits incrementally over the project period. Permanent credits are issued after a certain number of carbon tonne-years of storage have been achieved.Footnote 140 This way, storage periods with varying lengths can be put in equivalent and fungible units. Murray and Kasibhatla describe this approach as ‘less conservative than temporary crediting’, which was practised under the CDM, and ‘more conservative than prepaid credits and buffer provisions’, which are typically used in voluntary carbon markets.Footnote 141
Murray and Kasibhatla suggest that policymakers should stipulate a time period, such as 100 years, for carbon storage after which full permanence is earned. This period must not represent a permanent emissions reduction in atmospheric terms but should serve as a ‘policy-relevant target for de facto permanence’.Footnote 142 Once a certain number of carbon tonne-years have been accumulated, a certain degree of permanence has been achieved and cannot be reversed. The more carbon that is stored for longer periods, the more permanence is gained. Hence, the level of permanence and therefore the value of the project accumulate exponentially over time.
This approach tries to pursue a middle ground between ‘prepaid credits’ that are given out at the beginning of a project, such as in voluntary carbon markets, and the option to receive the credits at the end of the project period. In this case, operators earn credits incrementally over the course of the project. Murray and Kasibhatla claim that this approach ‘seems to reduce vulnerability of the entire system to reversal risk’.Footnote 143 It builds on the rationale that short-term removal of CO2 still entails some benefits and should be rewarded, which is reflected in an incrementally increasing value of the CO2 storage. It seeks to ensure the environmental integrity of the system by allowing no more emissions than have been ‘earned’ through the accumulation of carbon tonne-years. Contrary to voluntary carbon schemes, this approach does not rely on liability. The credits are irrevocable, even though a CDR project might reverse in the future.Footnote 144 Therefore, the system is resilient and challenges relating to liability are being avoided.
It is important to carefully define the period that is considered permanent, after which the full credits are received. If it were too short, the environmental integrity of the system would be low, and it would incentivize the deployment of currently cheaper low permanent CDR technologies. For instance, if the period were to be 100 years, this threshold could be reached through afforestation. CO2 storage beyond this point would not be rewarded, as full credits are earned after 100 years and no liability arises in the event of reversal after that time.
This approach has been criticized on the basis that it is questionable that the delayed revenue stream would provide sufficient financial incentives to scale up CDR rapidly and significantly.Footnote 145 For many CDR technologies, costs are incurred at the beginning of the project, while payment would be made after permanence has been earned. This might deter investors. An EU report on carbon farming flagged a practice in voluntary carbon schemes as problematic from a cash-flow perspective, which issued credits after the carbon has been sequestered.Footnote 146 The report states that the ‘associated lagging stream of revenues is the main structural barrier that has led to the limited uptake of reforestation activities’.Footnote 147 This criticism applies a fortiori to tonne-year accounting as carbon sequestration occurs before a certain degree of permanence has been earned. Moreover, the final report of the Taskforce on Scaling Voluntary Carbon Markets identified the ‘long lag times between investment and return’ and the accompanying ‘lack of financial attractiveness’ as a significant mobilization challenge.Footnote 148 This issue of scattered financial flows could be addressed by reducing the level of liability in proportion to the reduction in the global warming potential of the original emission, as opposed to earning credits once carbon tonne-years have been accumulated. In other words, instead of issuing credits incrementally, the level of liability is decreasing according to the accumulation of carbon tonne-years. In this way, the full number of credits can be issued at the beginning of the project period. CDR deployment, therefore, is made more financially attractive. In the case of a reversal, only the remaining global warming potential of the original emissions at the time of the reversal must be compensated, rather than demanding the submission of all the credits that were originally issued for the project.
However, there are more fundamental criticisms of tonne-year accounting in the scientific community. It has been criticized for the use of subjective economic discount rates and arbitrary time horizons to assess the costs of emissions and the benefits of temporary storage.Footnote 149 Others have argued that equivalence claims between temporary carbon storage and avoided emissions or permanent storage are flawed.Footnote 150 The Article 6.4 Mechanism Supervisory Body stated that it will ‘focus on measures that address reversals on a tonne-for-tonne basis, and not on a tonne-year basis’ because of concerns ‘within the scientific community, regarding its underpinning methods and assumptions, and ecological implications, and insufficient confidence in its suitability for international applications and effectiveness at addressing reversals’.Footnote 151
4.4. Lessons Learned
The restrictive approach to CDR taken under the CDM did ensure that no emissions were permanently offset by non-permanent carbon removal, thereby ensuring the environmental integrity of the system in this respect. However, the CDM failed to encourage extensive investments in CDR. CDR were not sufficiently valued, as temporary credits had eventually to be replaced with permanent credits on a one-to-one ratio. Such an approach might have been satisfactory at this time because afforestation and reforestation were perceived as temporary solutions. However, it will not be sufficient to achieve the current goal of scaling up CDR rapidly and significantly.
The approach of voluntary carbon schemes has the potential to drive investment, as evidenced by high demand and growth rates. However, the contract periods that guarantee safe storage of CO2 are relatively short and the system relies heavily on liability and risk buffer accounts. This approach does not seem to offer the best solution to ensure environmental integrity.
The tonne-year approach does not rely on liability and risk buffer accounts, which avoids challenges regarding execution, and which bolsters the system's resilience. Short-term CDR technologies are valued based on the benefits they provide. However, concerns about the underlying methods and assumptions, as well as the environmental impacts, make this approach less favourable. In addition, the dispersed financial flow would most likely not encourage sufficient investment in CDR.
From the analysis of these approaches, it appears that a right balance must be struck, particularly between encouraging investments and ensuring environmental integrity. Too stringent rules on permanence and liability can present barriers to participation while loose rules can jeopardize environmental integrity.Footnote 152
5. Legal Considerations to Guide a Legislative Proposal
This section aims to inform a potential legislative proposal for the integration of CRCs into the EU ETS.Footnote 153
5.1. Permanence
The EU intends to create a certification framework for all types of carbon removal, not all of which will be eligible for integration into the EU ETS because of their varying levels of permanence. Therefore, the article argues that the EU should create a distinct, more stringent definition of permanence, specifically for the purpose of integrating CRCs into the EU ETS.
The Commission's proposal for a carbon removals certification framework defines permanent carbon storage as ‘a carbon removal activity that, under normal circumstances and using appropriate management practices, stores atmospheric or biogenic carbon for several centuries’.Footnote 154 This definition must be further elaborated. The EU should explicitly define a time frame that it deems permanent. Currently, it is not specified what exactly is meant by ‘several centuries’. This could lead to uncertainties about whether specific CRCs are eligible for integration into the EU ETS, and therefore hinder investment and deployment.
This article proposes to define permanent CDR as technologies that have a relatively low risk of significant CO2 reversals prior to the end of the period considered permanent. This definition uses three variables to determine the permanence of CDR technologies: (i) what storage period is deemed permanent; (ii) what constitutes a significant reversal of the stored CO2; and (iii) what constitutes a low reversal risk. Depending on the exact definition of these variables, many nature-based solutions could be considered non-permanent, whereas engineered CDR technologies (such as BECCS and DACCS) could be regarded as permanent.
Firstly, the EU must determine the permanent storage period. Defining the permanent storage period is about finding the right balance between ensuring the environmental integrity of the EU ETS and scaling as many CDR activities as possible. If the permanent storage period is too long, many CDR technologies would be excluded from the market, which otherwise could provide valuable (temporary) storage. If it is too short, the level of environmental integrity of the EU ETS would diminish. There is no uniform definition of permanence.Footnote 155 Murray and Kasibhatla define permanence ‘as the point in time at which stored carbon has essentially fulfilled its role as offsetting the global warming potential of the original emission’.Footnote 156 This definition should guide the determination of the permanent storage period. The stored carbon must offset a significant percentage of the global warming potential of the original emission, rather than fully offset it. This approach does not guarantee complete environmental integrity as a certain percentage of the original emission will remain in the atmosphere. However, it is necessary to draw a line because a certain percentage of the original emission will inevitably remain in the atmosphere nearly forever, making it almost impossible for it to be fully offset. In addition, the temporary removal offers other benefits, such as buying humanity time in which to develop more permanent CDR technologies.
Secondly, the EU must stipulate what constitutes a significant reversal of the stored CO2 in addition to what is considered a high versus low reversal risk. A possible problem in that respect is the lack of information regarding the reversal risks of certain CDR technologies.Footnote 157 To address this knowledge gap, the precautionary principleFootnote 158 should apply. When the reversal risk is not sufficiently clear, a CDR technology shall be deemed non-permanent in order to ensure the environmental integrity of the system. Further research is required to better understand the reversal risks of CDR technologies.
The Commission's proposal suggests that the ‘validity of the certified carbon removals should depend on the expected duration of the storage and the different risks of reversal associated with the given carbon removal activity’.Footnote 159 CDR technologies that store carbon in geological formations should not be subject to an expiry date as they provide enough certainty on the long-term duration of the stored carbon. The validity of the certified carbon removals from carbon farming or carbon storage in products, conversely, should be subject to an expiry date as they are more exposed to the risk of re-emission. After the expiration date, the carbon should be considered as re-emitted unless the operator demonstrates the maintenance of carbon storage through continuous monitoring activities. This article argues that CRCs with an expiration date should not be integrated into the EU ETS, as the experiences with temporary credits under the Kyoto Protocol have demonstrated.Footnote 160 The expiry of certain credits would make them not fungible with indefinite CRCs and emissions allowances, thus increasing complexity and administrative work. Therefore, CRCs with an expiration date are likely to be unattractive to market participants. Instead, this article proposes a clear cut between permanent and non-permanent CDR technologies. Only CRCs issued for permanent CDR technologies should be integrated into the EU ETS. Non-permanent CDR technologies, particularly those with strong co-benefits, should be promoted through other mechanisms such as the Innovation Fund,Footnote 161 the Common Agricultural Policy,Footnote 162 the Regional Development Fund,Footnote 163 or by means of a distinct market for non-permanent CRCs. This is because the benefits of short-term removal and storage of CO2 cannot outweigh the risks that their inclusion would pose for the environmental integrity of the EU ETS as a result of potential large-scale reversal events. It is crucial to remember that the EU ETS is a cornerstone, if not the leading mechanism, in the EU ambition to reduce its emissions. Therefore, the standard of environmental integrity must be high.
5.2. Liability
The Commission's proposal for a carbon removals certification framework does not specify what a liability system could look like. It only calls for ‘appropriate liability mechanisms’, which could include discounting of carbon removal units, collective buffers, or up-front insurance mechanisms.Footnote 164 With regard to the geological storage of CO2, the liability mechanisms and corrective measures of the EU ETS Directive and the CCS Directive should apply to avoid double regulation.Footnote 165 The Commission's proposal makes it clear that the project operator or a group of operators should be liable for any re-emission of a CDR project.Footnote 166 This is compelling as the project operator is the best place to address any reversal, both with regard to knowledge of the project and access to the site.Footnote 167 Passing the liability risk to the purchaser of the removal unit would provide a ‘perverse incentive’ to the project operator not to bear responsibility for safe storage.Footnote 168
One way of establishing a liability regime is to include CDR technologies in Annex I of the EU ETS Directive, which lists the activities covered by the EU ETS. In the event of a reversal, allowances or CRCs would have to be submitted as for any other source of GHG emissions. This approach has been taken for CCS activities.Footnote 169 This liability regime would be robust if only CRCs issued for permanent CDR technologies were integrated into the EU ETS. Large-scale, simultaneous reversals that overwhelm the system would then be unlikely. Liability should become relevant only when a CDR project reverses before the permanent storage period ends. It should not apply after that period, as a significant percentage of the original emission will have decayed by that time.
This article distinguishes between two reversal scenarios: disastrous and non-disastrous. A ‘disastrous reversal’ should be defined as a kind of reversal caused by catastrophes beyond the control of the project operator, such as drought, wildfires, flooding, earthquakes, storms, tornados, or human-induced events. A ‘non-disastrous reversal’ could be defined as a reversal that does not fall within the category of disastrous reversals, particularly because the project operator had been at fault. This applies, for instance, in situations where the project operator acted intentionally or failed to exercise due diligence. The distinction between these scenarios is practised widely in voluntary carbon schemes.Footnote 170 The clawback provision of Article 18(7) of the CCS Directive introduces a similar differentiation.
This article proposes that the project operator should be liable in the event of a non-disastrous reversal until the end of the permanent storage period. In the case of a disastrous reversal, the liability risk should be transferred from the project operator to the competent authority when certain conditions apply. Lessons can be drawn from the CCS liability regime because both CCS and permanent CDR demonstrate high levels of permanence. BECCS and DACCS, which most likely fall within the category of permanent CDR, rely on CCS for the storage of removed CO2. Under the CCS Directive, a transfer of liability risk from the operator to the competent authority takes place.Footnote 171 For CDR, a risk transfer should apply under similar conditions because liability periods that are too long are unpredictable and uninsurable, and therefore are likely to discourage the deployment of and investment in CDR.Footnote 172 The conditions for a risk transfer should be, alongside other possible requirements, that (i) all information available must indicate that the bulk of the stored CO2 will be safely contained until the end of the permanent storage period, and (ii) that a minimum period has passed. The allocation of part of the liability to the Member State would be justified by the public interest in the widespread application of CDR to tackle climate change.Footnote 173 Moreover, large reversals that force the Member State to make payments under the liability scheme are unlikely to occur when only CRCs issued for CDR technologies with high levels of permanence are integrated.
6. Conclusion
Permanence and liability will be pivotal elements in discussions surrounding the potential integration of CRCs into the EU ETS. This article has highlighted several key challenges to these discussions, including the necessity of achieving fungibility among CRCs derived from diverse CDR technologies and emissions allowances to create a liquid market that provides sufficient investments to scale up CDR. Achieving fungibility currently faces difficulties as the various CDR technologies available demonstrate different levels of permanence. Accounting for these differences is essential because CDR with high levels of permanence holds greater climate value compared with CDR with low levels of permanence, albeit that the latter still yields benefits. Integrating non-permanent CRCs into the EU ETS could also compromise the environmental integrity of the EU ETS as large-scale reversal events could overwhelm the liability system, particularly once the supply of emissions allowances ends.
The CDM, voluntary carbon markets, and tonne-year accounting provide mechanisms to address these issues, but are found to be insufficient. The CDM failed to stimulate investments in CDR as credits were issued temporarily and not sufficiently valued. The approach adopted under many voluntary carbon markets does not appear to offer optimal solutions to ensure environmental integrity. The contract periods that guarantee safe storage of CO2 are relatively short and the system relies extensively on liability and risk buffer accounts for managing reversals. With regard to the tonne-year approach, the dispersed financial flow would most likely not encourage sufficient investment in CDR, and the underlying methods and assumptions are questionable.
Integrating CRCs into the EU ETS revolves around accommodating the requirements, needs, and interests involved, despite being seemingly contradictory at times. These factors encompass, among many others, environmental integrity, the interests of project operators and investors, and the imperative to rapidly and substantially scale up CDR. An EU legislative act must strike a balance that considers all of these to the greatest extent possible. Based on these insights, the article formulates legal considerations that may guide a proposal for a future EU legislative act. It argues that only CRCs issued for permanent CDR technologies should be integrated into the EU ETS to ensure its environmental integrity. The project operator's liability should transfer to the Member State under certain conditions to encourage CDR investments by making liability risks more predictable and insurable. If the EU were to integrate CRCs into the EU ETS, this could influence climate policies around the world and ultimately lead to the establishment of a global standard. If the international trade of CRCs is to be a way forward in scaling CDR technologies globally, the consideration of permanence and liability could determine its success.
Acknowledgements
The author wishes to thank Navraj Singh Ghaleigh for his valuable guidance and Kai Currie for her helpful feedback. The author is also grateful to the five TEL reviewers for additional feedback.
Funding statement
Not applicable.
Competing interests
The author declares none.