1 Introduction

The discovery of the ozone hole by Farman et al. (1985) led quickly to the confirmation of the idea put forward by Molina and Rowland (1974) that chlorine radical species, the breakdown products of the chlorofluorocarbons (CFCs), could deplete stratospheric ozone. In the face of the scientific evidence, the Montreal Protocol on substances that deplete the ozone layer was agreed in 1987 and ratified in 1989. The original controls proposed were modest, covering only ${\mathrm{CFCl}}_{\mathrm{3}}$ (CFC-11), ${\mathrm{CF}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$ (CFC-12), three further CFCs, and three brominated compounds (halons). However, in line with the developing scientific understanding, the controls were subsequently strengthened in a series of adjustments and amendments to the Protocol. These included stronger regulation on the phase-down schedules, the addition of many more CFCs, ${\mathrm{CCl}}_{\mathrm{4}}$, and transitional hydrochlorofluorocarbon (HCFC) compounds under the London Amendment in 1990, and the inclusion of many more brominated compounds, including methyl bromide under the Copenhagen Amendment of 1992. The initial replacements for the CFCs, the HCFCs, have shorter lifetimes than the CFCs (Chipperfield et al., 2014), and accordingly their impact on stratospheric ozone is less. They, in turn, are being replaced by hydrofluorocarbons (HFCs), compounds which do not directly lead to ozone depletion but some of which are strong greenhouse gases. Regulations to limit the growth of many HFCs were agreed in the Kigali Amendment in 2016.

In consequence, the atmospheric abundances of ozone-depleting chlorine and bromine species are now declining, following their peaks in the late 1990s (WMO, 2018), leading to the start of ozone recovery. The 2018 Scientific Assessment for the Montreal Protocol (WMO, 2018) reported that the Antarctic ozone hole, while continuing to occur each year, is showing early signs of recovery (e.g. Solomon et al., 2016) and that upper-stratospheric ozone has increased by up to 3 % since 2000 (e.g. LOTUS, 2019). However, there is as yet no significant recovery trend in global column ozone (e.g. Ball et al., 2018; Weber et al., 2018). Furthermore, because many ozone-depleting substances (ODSs) are also greenhouse gases, their control has brought significant climate benefits (Velders et al., 2007, 2012; WMO, 2018). The annual reduction in these greenhouse gas emissions is estimated to be about 5 times larger than the annual emission reduction target for the first commitment period of the Kyoto Protocol (WMO, 2014).

The Montreal Protocol has undoubtedly been successful. Without the Protocol the abundance of ODSs would likely have risen such that, for example, very large ozone depletion could have occurred in the Arctic (Chipperfield et al., 2015). Uncontrolled growth of ODSs would also have severely exacerbated the impact on global warming of the increase in other greenhouse gases, making current climate targets even more challenging to meet. However, there have recently been questions about the completeness of the implementation of the Protocol. The concentrations of some short-lived anthropogenic halocarbons, which are not covered by the Protocol, have increased in the atmosphere (Hossaini et al., 2017; Oram et al., 2017; Fang et al. 2018), with suggestions that they might be by-products in the production of other halocarbons. Furthermore, the concentrations of some of the controlled ODSs have not followed projections based on their phase-out under the Montreal Protocol. For instance, concentrations of carbon tetrachloride, ${\mathrm{CCl}}_{\mathrm{4}}$, have not fallen as rapidly as expected based on its atmospheric lifetime. A detailed reanalysis of ${\mathrm{CCl}}_{\mathrm{4}}$ indicates that inadvertent by-product emissions from the production of chloromethanes and perchloroethylene, and fugitive emissions from the chlor-alkali process, have contributed to this discrepancy (SPARC, 2016; Sherry et al., 2018; WMO, 2018), and recently Lunt et al. (2018) have shown that emissions of ${\mathrm{CCl}}_{\mathrm{4}}$ from east China have increased in the last decade. East China as a source of other short-lived halocarbons was also suggested by Ashfold et al. (2015) and Fang et al. (2018).

Against this background, Montzka et al. (2018) showed that the atmospheric abundance of one of the major chlorine-carrying CFCs, CFC-11, is not declining as expected under full compliance with the Montreal Protocol. Using the NOAA network of ground-based observations, they demonstrated clearly that the rate of decline of CFC-11 in the atmosphere between 2015 and 2017 was about 50 % slower than that observed during 2002–2012 and was also much slower than had been projected by WMO (2014). They inferred that emissions of CFC-11 had been approximately constant at $\sim \mathrm{55}$ Gg yr${}^{-\mathrm{1}}$ between 2002 and 2012 and had then risen after 2012 by 13 Gg yr${}^{-\mathrm{1}}$ to $\sim \mathrm{68}$ Gg yr${}^{-\mathrm{1}}$. Montzka et al. (2018) argued that this increase could not be explained by increased release from pre-existing banks. Instead, they suggested that production of CFC-11 in east Asia, which is inconsistent with full compliance of the Montreal Protocol, was the likely cause. Using inverse modelling, Rigby et al. (2019) have since shown that the increase in CFC-11 emissions from eastern China between 2008–2012 and 2014–2017 is $\sim \mathrm{7}$ Gg yr${}^{-\mathrm{1}}$, corresponding to approximately 40 %–60 % of the global emission increase identified by Montzka et al. (2018) during that period. The increase in CFC-11 emissions after 2012, in conjunction with the expected decline in global CFC-11 emissions which would have resulted from full compliance with the Montreal Protocol, has resulted in global CFC-11 emissions being $\sim \mathrm{35}$ Gg yr${}^{-\mathrm{1}}$ greater than anticipated by the WMO (2014) A1 scenario in 2019.

The exact source of the emissions remains unknown, nor is it known if there is co-production of CFC-12. It is usual that the gases are produced together in an industrial plant (e.g. Siegemund et al., 2000), with the fraction of CFC-11 to CFC-12 production varying between 0.3 to 0.7 (UNEP, 2018). There is currently no evidence that CFC-12 concentrations in the atmosphere are also declining at a slower rate than expected but some co-production of CFC-12 along with CFC-11 is always expected.

Compliance with the Montreal Protocol is essential for its continued success in reducing stratospheric ${\mathrm{Cl}}_y$ and ultimately healing the ozone layer. Any non-compliance will inevitably prolong the period when the Antarctic ozone hole will continue to occur and delay the date at which global total column ozone (TCO) returns to it 1980s values, an important milestone on the road to recovery. Recent studies by Dameris et al. (2019) and Dhomse et al. (2019) have explored a range of different future ODS loadings, enhanced above those expected under full compliance with the Montreal Protocol, and find substantial delays in recovery depending on the scenario. It is essential therefore to understand the likely impact of the current non-compliance. Here the UM-UKCA chemistry–climate model (CCM) is used to assess the possible implications of the change in decline of CFC-11. A number of possible scenarios are explored in a range of sensitivity calculations. These include emissions which cease immediately or which persist for different periods into the future. These scenarios also consider that some of the non-compliant production may be stored in new CFC-11 banks, for later release, and that production of CFC-11 may be associated with co-production of CFC-12.

Until the source of the recent CFC-11 emissions is understood and thoroughly quantified, model calculations can only investigate a range of possible future emissions scenarios. However, models can be used to search for a relationship between the amount of chlorine emitted into the atmosphere and the timing of TCO return dates. Here results from both the UM-UKCA CCM and the TOMCAT chemistry transport model (CTM; recently used to study the impact of increased CFC-11 emissions on the behaviour of the Antarctic ozone hole; Dhomse et al., 2019) are used to investigate the relationship between increased emissions and enhanced ozone depletion. Identification of a robust relationship would allow us to develop a scenario-independent understanding of the impact of uncontrolled CFC emissions on the TCO return date.

In Sect. 2 the UM-UKCA and CFC scenarios used in this study are discussed in detail. Section 3 assesses the impact of these CFC emissions scenarios on stratospheric chlorine loading before the impacts on the TCO return date are examined in Sect. 4. Section 5 investigates the relationship between cumulative CFC emissions and ozone depletion, using both the CCM and CTM. Finally, further discussion of the results and a summary of our conclusions are provided in Sect. 6.

2 Model configuration and simulations

To explore the impacts of potential future CFC-11 emission scenarios on the TCO return date, a total of 10 transient simulations were performed using the UM-UKCA model, which consists of version 7.3 of the HadGEM3-A configuration of the Met Office's Unified Model (Hewitt et al., 2011) coupled with the United Kingdom Chemistry and Aerosol scheme. This configuration of the model has a horizontal resolution of 2.5${}^{\circ }$ latitude $\times \mathrm{3.75}$${}^{\circ }$ longitude, and 60 vertical levels following a hybrid sigma-geometric height coordinate, extending from the surface to a model top at 84 km. The chemical scheme is an expansion of the scheme presented in Morgenstern et al. (2009) in which halogen source gases are considered explicitly and the effects of the solar cycle are considered as described in Bednarz et al. (2016). It includes 45 chemical species, 118 bimolecular reactions, 17 termolecular reactions, 41 photolysis, and 5 heterogeneous reactions occurring on the surfaces of polar stratospheric clouds and sulfate aerosols. This chemistry scheme provides a detailed treatment of stratospheric chemistry including the ${\mathrm{O}}_x$, ${\mathrm{ClO}}_x$, ${\mathrm{BrO}}_x$, ${\mathrm{HO}}_x$, and ${\mathrm{NO}}_x$ catalytic cycles and a simplified tropospheric scheme including the oxidation of a limited number of organic species (${\mathrm{CH}}_{\mathrm{4}}$, CO, ${\mathrm{CH}}_{\mathrm{3}}{\mathrm{O}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{3}}\mathrm{OOH}$, HCHO) alongside detailed ${\mathrm{HO}}_x$ and ${\mathrm{NO}}_x$ chemistry. The chemical tracers ${\mathrm{O}}_{\mathrm{3}}$, ${\mathrm{CH}}_{\mathrm{4}}$, ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$, CFC-11, CFC-12, CFC-113, and HCFC-22 are all interactive with the radiation scheme. The halogenated source gases CFC-11, CFC-12, CFC-113, HCFC-22, halon-1211, halon-1301, ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Br}$, ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Cl}$, ${\mathrm{CCl}}_{\mathrm{4}}$, ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Br}}_{\mathrm{2}}$, and ${\mathrm{CHBr}}_{\mathrm{3}}$ are considered explicitly, the concentration of each prescribed at the surface as a time-evolving lower boundary condition (LBC).

The version of UM-UKCA used in this study is an atmosphere-only configuration, with each simulation using the same prescribed sea surface temperatures (SSTs) and sea ice fields taken from a parent coupled atmosphere–ocean HadGEM2-ES integration. The configuration of the model used for this study includes the effects of the 11-year solar cycle in both the radiation and photolysis schemes. The top-of-the-atmosphere solar flux follows historical observations from 1960 to 2009, after which a repeating solar cycle is imposed which is an amplitude equivalent to the observed cycle 23 (as detailed in Bednarz et al., 2016). Further information on the model configuration used for this study is provided in Keeble et al. (2018). Except for CFC-11 and CFC-12 LBCs, all other chemical forcings in the simulations follow the experimental design of the WCRP/SPARC Chemistry Climate Model Initiative (CCMI) REF-C2 experiment (Eyring et al., 2013), which adopts the RCP6.0 scenario for future greenhouse gas (GHG) and ODS emissions. A baseline experiment (BASE) performed using CFC-11 and CFC-12 LBCs provided by the WMO (2014) A1 scenario was run from 1960 to 2099. A further nine simulations were performed, running from 2012 to 2099, using a range of CFC-11 and CFC-12 LBCs, which were designed to cover a large but plausible range of potential future CFC emissions scenarios given the associated uncertainties.

2.1 CFC-11 scenarios

There are a number of important details associated with the recently reported CFC-11 emissions from East Asia which are poorly understood. A key factor is whether the identified CFC-11 emissions arise from emissive or non-emissive uses. If they arise from a totally emissive use, then the observed CFC-11 changes represent the total new CFC-11 production, with this new source of CFC-11 being released into the atmosphere during either production or use. Conversely, if they arise from a non-emissive use (e.g. foam insulation), then the observed changes to CFC-11 represent only a fraction of the total production, with a large component entering a new bank. In order to address this, two scenario types were created, which reflect the new CFC-11 production which is in addition to that implied in the WMO (2014) A1 scenario. In SCEN1, which represents the emissive use scenario, constant emissions of 35 Gg CFC-11 yr${}^{-\mathrm{1}}$ ($\sim \mathrm{27}$ Gg Cl yr${}^{-\mathrm{1}}$) were assumed while in SCEN2 total production was assumed to be 90 Gg CFC-11 yr${}^{-\mathrm{1}}$ ($\sim \mathrm{70}$ Gg Cl yr${}^{-\mathrm{1}}$), with 15 Gg CFC-11 yr${}^{-\mathrm{1}}$ of this total directly emitted into the atmosphere, while the remaining 75 Gg CFC-11 yr${}^{-\mathrm{1}}$ entered a bank with an assumed release fraction of 3.5 % yr${}^{-\mathrm{1}}$. The SCEN2 scenario is designed to give an additional emission increment of $\sim \mathrm{35}$ Gg CFC-11 yr${}^{-\mathrm{1}}$ in 2019, similar to the emissions value used in SCEN1 and consistent with the CFC-11 emissions increment, in addition to that expected assuming only release from known banks, identified by Montzka et al. (2018.) We emphasis that the 35 Gg CFC-11 yr${}^{-\mathrm{1}}$ and 90 Gg CFC-11 yr${}^{-\mathrm{1}}$ values represent the extra emissions or production increment assumed in addition to those of the WMO (2014) A1 scenario.

A second key factor is the duration of the illegal production. In order to address this question, three sets of simulation were performed for both SCEN1 and SCEN2, in which uncontrolled production either stopped in 2019 or continued into the future until 2027 or 2042, giving total emissions periods of 7, 15, or 30 years, respectively. All simulations assume that uncontrolled production and emission began in 2012. Simulations are named such that the scenario name is followed by the emission period, separated by an underscore (i.e. SCEN1_15 uses SCEN1 emissions from 2012 for 15 years).

A third consideration is the potential co-production of CFC-12. While there is no evidence currently that CFC-12 concentrations in the atmosphere are declining at a slower rate than expected (Montzka et al., 2018), CFC-12 is commonly co-produced alongside CFC-11 at a ratio of 30:70 either way (TEAP, 2019). Accordingly, an additional scenario (SCEN3) was developed in which 90 Gg yr${}^{-\mathrm{1}}$ of both CFC-11 and CFC-12 is produced, i.e. a ratio of $\mathrm{50}:\mathrm{50}$, towards the middle of the expected range. The same assumptions are made about the relative fraction entering the bank and the subsequent bank release rate as for SCEN2. SCEN3 was performed for the three different emissions periods used by SCEN1 and SCEN2, and simulations follow the same naming convention. As we consider both CFC-11 and CFC-12, all future emission or production values will be given in gigagrams of chlorine with 1 Gg CFC-11 equal to $\sim \mathrm{0.77}$ Gg Cl and 1 Gg CFC-12 equal to $\sim \mathrm{0.59}$ Gg Cl.

The emissions for these various scenarios are shown (in Gg Cl) in Fig. 1a, while Fig. 1b shows the cumulative emissions and Fig. 1c shows the size of the newly created bank. The SCEN3 scenarios include both CFC-11 and CFC-12, both scaled to gigagrams of chlorine and summed.

Figure 2

Prescribed global mean, annual mean surface lower boundary mixing ratio of CFC-11 used for the BASE and SCEN simulations. The dashed line represents the 1980 CFC-11 surface mixing ratio in the BASE simulation. Note that the SCEN2 and SCEN3 simulations have the same CFC-11 lower boundary conditions.

[Figure omitted. See PDF]

Increases in stratospheric chlorine will lead to ozone depletion, and so uncontrolled production of CFCs could obviously pose a serious threat to the continued success of the Montreal Protocol. Modelled 40 km stratospheric inorganic chlorine (${\mathrm{Cl}}_y$) mixing ratios, averaged from 10${}^{\circ }$ S–10${}^{\circ }$ N, are shown in Fig. 3, and stratospheric ${\mathrm{Cl}}_y$ return dates (the date at which ${\mathrm{Cl}}_y$ mixing ratios, averaged from 10${}^{\circ }$ S–10${}^{\circ }$ N at 40 km, return to the BASE 1980 value) are given in Table 1. We chose the 10${}^{\circ }$ S–10${}^{\circ }$ N latitude range for calculating ${\mathrm{Cl}}_y$ return dates as this is within the tropical pipe in which air is predominantly moved vertically with limited horizontal mixing (e.g. Waugh, 1996; Neu and Plumb, 1999), a necessary consideration as ${\mathrm{Cl}}_y$ varies latitudinally with age of air. In the BASE simulation, the stratospheric ${\mathrm{Cl}}_y$ mixing ratio is projected to return to its 1980 value by 2058. Only small differences in the stratospheric ${\mathrm{Cl}}_y$ return date are modelled for the SCEN1 simulations, with a maximum delay of 3 years occurring in the SCEN1_30 simulation, which assumes the longest duration of additional CFC-11 emissions. However, large delays in the stratospheric chlorine return date are modelled in the SCEN2 simulations, which assume a large bank is also being produced alongside the direct atmospheric emissions (see Fig. 1). In the SCEN2_7 scenario, which assumes CFC-11 production stops in 2019, the stratospheric ${\mathrm{Cl}}_y$ return date is delayed by 2 years, and for SCEN2_30, which assumes CFC-11 production continues until 2042, the stratospheric ${\mathrm{Cl}}_y$ return date is delayed by 8 years. The delays highlight the potential importance for ozone depletion of any bank produced and its subsequent emission into the atmosphere. The delay in the stratospheric ${\mathrm{Cl}}_y$ return date is larger still if co-production of CFC-12 is considered, with the stratospheric ${\mathrm{Cl}}_y$ return date being delayed by 14 years in the SCEN3_30 scenario considered here.

Table 1

${\mathrm{Cl}}_y$ return date (defined as the date at which ${\mathrm{Cl}}_y$ mixing ratios, averaged from 10${}^{\circ }$ S–10${}^{\circ }$ N at 40 km, return to the BASE simulation 1980 value) and the date TCO returns to the 1960–1980 mean in the BASE and SCEN simulations. Uncertainty estimates for the TCO return date in the BASE simulation are provided by a separate five-member ensemble, as described in the text. TCO return to the 1960–1980 mean occurs after 2080 for the latitude range 90–60${}^{\circ }$ S, and so no uncertainty estimate can be provided for this latitude band, denoted by “$\pm \mathrm{?}$” in the table.

Figure 3

Modelled annual mean 40 km inorganic chlorine (${\mathrm{Cl}}_y$) mixing ratios, averaged from 10${}^{\circ }$ S–10${}^{\circ }$ N, for the BASE and SCEN simulations. The dashed line represents the 1980 ${\mathrm{Cl}}_y$ mixing ratio at 40 km in the BASE simulation, used as the value for calculating the ${\mathrm{Cl}}_y$ return date.

[Figure omitted. See PDF]

Figure 4 shows the annual mean TCO data from the BASE simulation (grey line) from 1960 to 2100, averaged over 60${}^{\circ }$ S–60${}^{\circ }$ N. Consistent with previous studies, TCO values decrease sharply from 1980 to the late 1990s as a result of increasing stratospheric chlorine loadings, before gradually increasing throughout the 21st century. Superimposed on these long-term trends is an 11-year oscillation resulting from the solar cycle. Observed annual mean TCO values from version 2.8 of the Bodeker Scientific total column ozone dataset (Bodeker et al., 2005) are shown in purple. There is generally good agreement between modelled TCO values and the Bodeker dataset; decadal total column ozone changes, the response of column ozone to the solar cycle, and the magnitude of interannual variability are all well captured by the model throughout the time period during which the observations and model data overlap.

4.1 Global total column ozone

Figure 5 shows smoothed TCO values for the BASE and SCEN simulations, averaged from 60${}^{\circ }$ S–60${}^{\circ }$ N. All simulations show a return to the baseline period of the 1960–1980 average between 2054 and 2064 (return dates provided in Table 1). The BASE simulation, which adopts the WMO (2014) LBC for ODSs and as such assumes the lowest anthropogenic ${\mathrm{Cl}}_y$ emissions, returns to the 1960–1980 mean the earliest, in 2054, as discussed above. The impact of the additional CFC-11 and CFC-12 production scenarios investigated here is to delay the return date. For SCEN1_7 and SCEN1_15, the delay is small and within the range of return dates calculated from the five-member ensemble. Only SCEN1_30 of the SCEN1 scenarios shows a significant delay in return date of 3 years. In contrast, for the SCEN2 simulations, which assume the creation of a new bank and subsequent emissions of CFC-11 from that bank, a substantial delay in the return date of global TCO is modelled in both the SCEN2_15 and SCEN2_30 simulations (4 and 7 years, respectively). Only in the case that the assumed production of 90 Gg yr${}^{-\mathrm{1}}$ stops this year (2019) is no significant delay in the return of TCO values to the baseline period modelled. The SCEN3 scenarios, which assume the co-production of CFC-12 alongside CFC-11, all show larger delays in the return date, with this being 10 years for SCEN3_30.

Figure 5

Smoothed TCO (in DU) for the BASE and SCEN simulations, for the global (60${}^{\circ }$ S–60${}^{\circ }$ N) and regional column values. Dashed line denotes the 1960–1980 baseline period, used as the value for calculating the TCO return date.

5.3 TCO return date vs. total cumulative emissions

Figure 8 shows the relationship between the total cumulative additional Cl emissions, in gigagrams, and projected the global TCO return date in the BASE and SCEN simulations. These values represent the additional Cl emissions assumed for each scenario in addition to the WMO (2014) A1 scenario. A robust ($r^{\mathrm{2}}=\mathrm{0.93}$) linear relationship is found, indicating that for every extra 200 Gg of Cl emitted, the global TCO return to the 1960–1980 mean is delayed by 0.56 years. Repeating this analysis for 10${}^{\circ }$ latitude bins gives the latitudinal dependence of the impacts of cumulative Cl emissions on the TCO return date (Fig. 9). Uncertainty estimates are calculated for the regression using the standard error of the estimate, given as ${\mathit{\sigma }}_{\mathrm{est}}=\sqrt{\frac{\mathrm{\Sigma }(y-y{}^{\prime }{)}^{\mathrm{2}}}{N}}$, where $y$ is the TCO return date, $y^{\prime }$ is the predicted TCO return date from the regression mode, and $N$ is the number of simulations. For every 200 Gg of Cl emitted, the date of the TCO return to the 1960–1980 mean is delayed by between 0.18 and 1.60 years, with a marked hemispheric asymmetry evident in the response. Large delays ($\sim \mathrm{1.6}$ years per 200 Gg Cl) are modelled in the Antarctic, where heterogeneous processing of chlorine reservoirs on polar stratospheric cloud (PSC) surfaces allows for large ozone depletion even for relatively small chlorine concentrations. On annual mean timescales these low values mix into the Southern Hemisphere midlatitudes, resulting in larger delays to the return date there (0.5–0.8 years per 200 Gg Cl) than in the Northern Hemisphere midlatitudes and Arctic (0.1–0.5 years per 200 Gg Cl), where the effects of PSC processing are less pronounced due to the higher temperatures and high dynamical variability of the Arctic polar vortex. No values are given south of 80${}^{\circ }$ S, as TCO values do not return to the baseline period by the end of the simulations.

Figure 8

TCO return date (defined as the date at which TCO values return to the BASE 1960–1980 average) for the BASE and SCEN simulations vs. cumulative additional emissions (Gg Cl) from 2012 to the end of the simulation. The dashed line gives the linear fit through the points.