Introduction

Emissions from the burning of fossil fuels, deforestation, agricultural activities and the production of synthetic greenhouse gases (GHGs) are the primary reasons for the observed increases in GHG concentrations, defined as mole fractions in dry air. The elevated GHG concentrations induce a radiative forcing that in turn would cause more than the observed recent global warming if it were not for the cooling effect by aerosols (Fig. TS.10 in IPCC WG1 AR5; IPCC, 2013). An accurate quantification of anthropogenic and natural climate drivers is crucial for general circulation and Earth system models (ESMs). Simulations by these models for the historical time periods, e.g. since 1850, can only be meaningfully compared to observations (e.g. surface temperature, ocean heat uptake) to the degree that input forcings are an accurate representation of the past. The difficulty with many anthropogenic climate drivers is that their global-mean magnitude, their latitudinal gradient and seasonal cycle are uncertain further back in time, even for the main GHGs carbon dioxide (${\mathrm{CO}}_{\mathrm{2}}$), methane (${\mathrm{CH}}_{\mathrm{4}}$) and nitrous oxide (${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$). Systematic observational efforts started in 1957–1958, measuring ${\mathrm{CO}}_{\mathrm{2}}$ at the South Pole and Mauna Loa observatories (Keeling et al., 2001). Measurements of archived air, firn air and ice cores from both polar regions provide records for the pre-observational time. To date, reconstructions of millennial global-mean time series based on ice and firn data have been performed, e.g. for ${\mathrm{CO}}_{\mathrm{2}}$ over recent millennia (Ahn et al., 2012; MacFarling Meure et al., 2006; Rubino et al., 2013). For the more recent past, several studies investigated firn and ice data to constrain halocarbons (Buizert et al., 2012; Martinerie et al., 2009; Mühle et al., 2010; Sturrock et al., 2002; Trudinger et al., 2016), some of them with hemispheric resolution. In terms of latitudinally resolved monthly data, there have only been a few synthesis products, namely for ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ over the instrumental record over the past 20–40 years (NOAA, 2013; NOAA ESRL GMD, 2014a, b, c). For this recent past, the World Data Centre for Greenhouse Gases (WDCGG) (ds.data.jma.go.jp/gmd/wdcgg/) also provides a synthesis with global and hemispheric means for ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ (Tsutsumi et al., 2009). In light of the observational gaps further back in time, some studies, such as Keeling et al. (2011), used linear regressions between fossil fuel use and latitudinal ${\mathrm{CO}}_{\mathrm{2}}$ concentration trends to separate natural from anthropogenically induced effects, which allows us to infer latitudinal gradients back in time.

In previous climate model inter-comparison projects (Meehl et al., 2005), global-mean concentrations have been prescribed (Meinshausen et al., 2011), with some models constraining internally generated fields of GHG concentrations to match those global-mean values. Here, we update those global-mean and annual-mean GHG concentration time series for the historical period over years 0–2014, with “historical” simulations in the CMIP6 model intercomparison (Eyring et al., 2016) focussed on the most recent period, 1850–2014. In addition, we provide hemispheric and latitudinal monthly-resolved fields for 43 GHGs in total. In the past, the large latitudinal and seasonal gradient of GHG radiative forcing has not been consistently applied to model radiative forcing and climate change. The new datasets provide a more consistent starting point for climate model experiments. The monthly and latitudinal resolution of this new GHG dataset is designed to have a similar resolution to the monthly solar forcing (Matthes et al., 2016) and monthly and latitudinally resolved ozone and aerosol abundances. Many GHGs also have significant longitudinal (land–ocean) and diurnal variations but we do not attempt to resolve them. Neither do we provide vertical gradients of the GHG concentrations, and we only discuss possible vertical extension methods (Sect. 4.1) in case models do not have their own methods to derive vertical gradients.

In this study, we compile one possible reconstruction of latitudinally and monthly resolved fields, as well as global annual means of surface GHG concentrations for 43 gases from year 0 to 2014, as input for the forthcoming model inter-comparison experiments that are part of the Phase-6 Coupled Model Intercomparison Project (CMIP6) (Eyring et al., 2016). Specifically, we provide the pre-industrial control runs at 1850 forcing levels (“picontrol”), the experiment with abruptly quadrupled ${\mathrm{CO}}_{\mathrm{2}}$ concentrations (“abrupt4x”), the standard experiment of a 1 % annual ${\mathrm{CO}}_{\mathrm{2}}$ concentration increase (“1pct2co2”), and the historical runs that are driven with best-guess estimates of historical forcings since 1850. Species that are radiatively less important than ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ (“importance” here being measured as radiative forcing exerted in year 2014 compared to 1750) are provided individually as well as aggregated as HFC-134a and CFC-12 equivalent concentrations. The description of the datasets geared towards CMIP6 modelling groups is provided in Sect. 4, including a description of available data formats and CMIP6 minimum recommendations.

The design principle for this long-term dataset is to provide a plausible reconstruction of past GHG concentrations to be used in climate models. Using various gap-filling procedures, reconstruction and extensions, this dataset aims to reflect observational evidence of both recent flask and in situ observations from the worldwide network of NOAA ESRL and AGAGE stations, as well as Antarctic and Greenland ice core and firn data over the last 2000 years, where available. Furthermore, many detailed literature studies (Arnold et al., 2013, 2014; Aydin et al., 2010; Butler et al., 1999; Ivy et al., 2012; Martinerie et al., 2009; Montzka et al., 2015; Mühle et al., 2010; Oram et al., 2012; Sturrock et al., 2002; Trudinger et al., 2004, 2016; Velders and Daniel, 2014; Vollmer et al., 2016; Worton et al., 2006) for radiatively less important species are compared with our data product in the fact-sheet figures for the specific gases (Table 12 and Figs. S1–S40 in Supplement), or synthesized where direct observational records from the above networks were not available.

The predominant climate effect of GHG increases is captured by the global- and annual-mean concentrations throughout the atmosphere. The surface global- and annual-mean concentrations provided here, in combination with the models' approximations for the vertical concentration profile, are the minimum standard for CMIP6 models. Assimilating a latitudinally and seasonally resolved data product serves two purposes. Firstly, to derive the global and annual means from sparse observations rests on knowledge or assumptions about spatial and seasonal distributions. Secondly, to open the opportunity for some modelling groups to go beyond the prescription of global- and annual-mean concentrations.

Undoubtedly, some of the assumptions stretch into unknown territory, such as the seasonality of the ${\mathrm{CO}}_{\mathrm{2}}$ concentrations in pre-observational times or the time variability of latitudinal gradients, let alone the higher-frequency fluctuations of global-mean concentrations during the time when only ice core data are available. Errors in the historical forcing do propagate and can hinder the comparison between observations and models. This study therefore had to find a workable compromise between providing a complete dataset that covers the whole time and space domain and being as close as possible to sometimes sparse observations. Hence, the remaining uncertainties in concentration gradients should be kept in mind, although they might not be of primary concern in regard to the inter-comparison aspect of the multi-model ensemble runs. Thus, while our CMIP6 community dataset will improve on the global- and annual-mean time-series prescribed for the last set of CMIP5 experiments on a number of key aspects, many research questions remain open.

The underlying reasons for meridional gradients of annual-mean concentrations are manifold (Keeling et al., 1989a, b; Tans et al., 1989). For one, the sources of anthropogenic GHGs from fossil fuel burning and cement production or industrial activities are not evenly distributed with latitude, but concentrated in the mid-northern land masses. In the case of ${\mathrm{CO}}_{\mathrm{2}}$, emissions from deforestation are not uniformly distributed with latitude either. The pattern of land-use-related emissions is even less stationary, with ${\mathrm{CO}}_{\mathrm{2}}$ uptakes and sources predominantly focussed in the mid-northern latitudes up until earlier in the 20th century, shifting more towards lower latitudes in recent decades (Hurtt et al., 2011). This study uses an approach based on simple regressions that implicitly rest on the assumption of a fixed pattern approximation (such as Keeling et al., 2011). One complication to retrieving the latitudinal pre-industrial ${\mathrm{CO}}_{\mathrm{2}}$ concentration profile is that ${\mathrm{CO}}_{\mathrm{2}}$ fertilization and temperature effects on the carbon cycle, over both ocean and land, change both the magnitude and spatial patterns of natural ${\mathrm{CO}}_{\mathrm{2}}$ fluxes. Lastly, both the diurnal and seasonal cycle of photosynthesis and its covariance with vertical atmospheric mixing can have a pronounced effect on measured surface concentrations (the so-called “rectifier” effect), increasing annual mean northern hemispheric ${\mathrm{CO}}_{\mathrm{2}}$ surface concentrations by up to 2.5 $\mathrm{ppm}$ (Denning et al., 1999).

To dissect and analyse the different causes for temporal and spatial heterogeneity in surface concentrations, a rich body of literature has analysed observed latitudinal and seasonal gradients with various inversion techniques. Recent research provides a clearer picture in regard to the causes of the change in seasonality of ${\mathrm{CO}}_{\mathrm{2}}$ concentrations (Forkel et al., 2016), a topic researched already in 1989 (Kohlmaier et al., 1989) based on the ${\mathrm{CO}}_{\mathrm{2}}$ fertilization effect on northern hemispheric terrestrial biota. Generally, the research into meridional and seasonal variations employs various atmospheric inversion techniques (Enting and Mansbridge, 1991, 1989; Enting et al., 1995; Enting, 1998; Rayner et al., 1999) to match observed concentrations with source and sink pattern estimates (Baker et al., 2006; Enting et al., 1995; Gurney et al., 2002, 2003, 2004; Keeling et al., 1989a, b; Peylin et al., 2013; Rayner et al., 1999; Tans et al., 1989, 1990a). Similarly to ${\mathrm{CO}}_{\mathrm{2}}$, the spatial variation in ${\mathrm{CH}}_{\mathrm{4}}$ concentrations is used for model inversions to infer sources and sinks (Fung et al., 1991; Kirschke et al., 2013).

There is a substantial lack of observational evidence of both seasonality and latitudinal ${\mathrm{CO}}_{\mathrm{2}}$ gradients in pre-industrial times. Given that atmospheric ${\mathrm{CO}}_{\mathrm{2}}$ is not well preserved in the Greenland ice (Anklin et al., 1995; Barnola et al., 1995), the pre-observational north–south gradient cannot be inferred or derived from the Greenland and Antarctic ice core records. Alternatively, understanding biospheric sink and source dynamics could provide vital evidence to infer pre-industrial surface concentration patterns. In this study, we do not employ any such inversion models or results, and only note that our pre-industrial meridional and seasonal variations should be regarded as highly uncertain. However, some plausibility of the ${\mathrm{CO}}_{\mathrm{2}}$ gradients is gained by comparison with some model studies (Sect. 5). High-latitude records of ${\mathrm{CH}}_{\mathrm{4}}$ are available from both hemispheres (MacFarling Meure et al., 2006; Mitchell et al., 2013; Rhodes et al., 2013), allowing us to estimate pre-industrial large-scale ${\mathrm{CH}}_{\mathrm{4}}$ concentration gradients.

Methods

To achieve the goals of this study, several analytical steps were taken to assimilate the observational data. Global-mean and annual-mean concentrations are of primary interest, but the discussion also covers latitudinal and seasonal variations. The assimilation procedure for sparse observational data requires this spatio-temporal heterogeneity to be accounted for to derive global and annual means.

We consider a total of 43 GHGs: ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$, ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$, a group of 17 ozone-depleting substances (ODSs) made up of 5 CFCs (CFC-12, CFC-11, CFC-113, CFC-114, CFC-115), 3 HCFCs (HCFC-22, HCFC-141b, HCFC-142b), 3 halons (Halon-1211, Halon-1301, Halon-2402), methyl chloroform (${\mathrm{CH}}_{\mathrm{3}}{\mathrm{CCl}}_{\mathrm{3}}$), carbon tetrachloride (${\mathrm{CCl}}_{\mathrm{4}}$), methyl chloride (${\mathrm{CH}}_{\mathrm{3}}\mathrm{Cl}$), methylene chloride (${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$), chloroform (${\mathrm{CHCl}}_{\mathrm{3}}$), and methyl bromide (${\mathrm{CH}}_{\mathrm{3}}\mathrm{Br}$), and 23 other fluorinated compounds made up of 11 HFCs (HFC-134a, HFC-23, HFC-32, HFC-125, HFC-143a, HFC-152a, HFC-227ea, HFC-236fa, HFC-245fa, HFC-365mfc, HFC-43-10mee), 9 PFCs (${\mathrm{CF}}_{\mathrm{4}}$, ${\mathrm{C}}_{\mathrm{2}}{\mathrm{F}}_{\mathrm{6}}$, ${\mathrm{C}}_{\mathrm{3}}{\mathrm{F}}_{\mathrm{8}}$, ${\mathrm{C}}_{\mathrm{4}}{\mathrm{F}}_{\mathrm{10}}$, ${\mathrm{C}}_{\mathrm{5}}{\mathrm{F}}_{\mathrm{12}}$, ${\mathrm{C}}_{\mathrm{6}}{\mathrm{F}}_{\mathrm{14}}$, ${\mathrm{C}}_{\mathrm{7}}{\mathrm{F}}_{\mathrm{16}}$, ${\mathrm{C}}_{\mathrm{8}}{\mathrm{F}}_{\mathrm{18}}$, and c-${\mathrm{C}}_{\mathrm{4}}{\mathrm{F}}_{\mathrm{8}}$), ${\mathrm{NF}}_{\mathrm{3}}$, ${\mathrm{SF}}_{\mathrm{6}}$, and ${\mathrm{SO}}_{\mathrm{2}}{\mathrm{F}}_{\mathrm{2}}$.

All concentrations given here are dry air mole fractions and we use “mole fractions” and “concentrations” interchangeably and synonymously with “molar mixing ratios”. For simplicity, we denote the dry air mole fractions “$\mathrm{\mu }\mathrm{mol}{\mathrm{mol}}^{-\mathrm{1}}$”, “$\mathrm{nmol}{\mathrm{mol}}^{-\mathrm{1}}$” and “$\mathrm{pmol}{\mathrm{mol}}^{-\mathrm{1}}$” as parts per million (ppm), parts per billion (ppb) and parts per trillion (ppt), respectively. Note that dry air mole fractions are independent of temperature and pressure, while volume mixing ratios (e.g. ppmv) for mixtures of non-ideal real gases are not, and at standard temperature and pressure conditions can differ significantly from their corresponding mole ratios.

Summary of assimilation approach

We perform three consecutive steps to synthesize the global mole fraction fields over the full-time horizon from year 0 to year 2014. First, we aggregate the available observational data over the recent instrumental period. Second, we estimate three components of the global surface concentration fields from these data, namely global-mean mole fractions, latitudinal gradients and seasonality. Third, we extend those components back in time with – inter alia – ice core or firn data. The full historical GHG concentration field can then be generated by the time-varying components.

Under this basic assimilation model, the concentration $\widehat{C}\left(l,,,t\right)$ at any point in time $t$ and in a latitudinal band $l$ can be written as follows: $${\displaystyle }\widehat{C}\left(l,,,t\right)=\stackrel{\mathrm{‾}}{C_{\mathrm{global}}}\left(t\right)+{\widehat{S}}_{l,m}\left(y\right)+{\widehat{L}}_l\left(y\right),$$ where $\stackrel{\mathrm{‾}}{C_{\mathrm{global}}}\left(t\right)$ is the global-mean dry air mole fraction at time $t$, ${\widehat{S}}_{l,m}$ is the seasonality in each latitude $l$ and month $m$, and ${\widehat{L}}_l\left(y\right)$ is the latitudinal annual-mean deviation in year $y$ at latitude $l$. With this assimilation model, and the optimal low rank approximations of seasonality and latitudinal gradients, a regularization of the data is performed by a principal components analysis, which creates a degree of robustness against data gaps or outliers. Other methods, like a harmonic representation of station data, have, in principle, a similar smoothing and regularization effect (Masarie and Tans, 1995), although quantitative differences exist (Sect. 5.4).

A detailed data-flow diagram of how the historical GHG mole fractions are derived in this study is provided in Fig. 1. The subsequent section will describe the method step-by-step as indicated by the green circles in Fig. 1 and also tabulated for the three main GHGs in Table 1.

Data-flow diagram of how historical GHG concentrations are derived in this study. See text.

[Figure omitted. See PDF]

Step 1: aggregating raw station data

Atmospheric measurements are taken in remote environments or locations that are closer to pollution sources, in continental or marine areas, at different times of the day or night, at different altitudes, and in different seasons of the year, often using different calibration scales. This poses challenges for any synthesis of observational data.

Derivation and construction of CMIP6 concentration fields for ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$, as shown in Fig. 1 and described in Sect. 2.

Raw data used for ${\mathrm{CO}}_{\mathrm{2}}$ surface concentration field derivation.

${}^{*}$ See station descriptions here: http://www.esrl.noaa.gov/gmd/dv/site/site_table.html.

The observational station data over the recent decades used in this study are predominantly sourced from the networks operated by NOAA (Earth System Research Laboratories: ESRL) and AGAGE. In general, we use monthly station data provided by the respective networks as a starting point. In the case of the AGAGE network, monthly averages are provided with and without pollution events (http://agage.eas.gatech.edu/data_archive/agage/ and http://cdiac.ornl.gov/ftp/ale_gage_Agage/AGAGE/). We chose the monthly averages that include pollution events (file-endings “.mop”, with the exception of ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$, in which case data issues warranted the use of monthly station averages without pollution events). The approach that we do not restrict our source data to background conditions is consistent with our approach elsewhere – and the NOAA network monthly station averages – which do not screen out pollution events (although the dominant number of NOAA flask measurements will likely be biased towards background conditions rather than pollution events owing to their location and sampling protocols at most sites focussed on collecting background air). In total, ${\mathrm{CO}}_{\mathrm{2}}$ data from 81 stations from the NOAA flask network and 3 stations from the NOAA in situ data stations are used (Table 2). For ${\mathrm{CH}}_{\mathrm{4}}$, 87 sampling stations from the NOAA flask network and 5 stations from the AGAGE in situ network are compiled (Table 3). For ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$, data from flask and in situ measurements at 13 stations of the NOAA HATS global network are combined with data from 5 stations from the AGAGE network (Table 4). For other gases, the AGAGE and NOAA coverage and time frames vary, with individual station's codes provided in the “f” panels of the individual gases' fact sheets (Figs. S1–S40). We provide references to the used NOAA and AGAGE data in Table 12.

Raw data used for ${\mathrm{CH}}_{\mathrm{4}}$ surface concentration field derivation.

${}^{\mathrm{a}}$ NOAA station descriptions here: http://www.esrl.noaa.gov/gmd/dv/site/site_table.html. ${}^{\mathrm{b}}$ AGAGE station descriptions here: https://agage.mit.edu/global-network.

Raw data used for ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ surface concentration field derivation.

${}^{\mathrm{a}}$ NOAA station descriptions here: http://www.esrl.noaa.gov/gmd/dv/site/site_table.html. ${}^{\mathrm{b}}$ AGAGE station descriptions here: https://agage.mit.edu/global-network.

Calibration scales, i.e. the standardized gas mixtures that allow us to calibrate the instrumentation used for in situ or flask measurements, differ between the NOAA and AGAGE networks. Gas measurements on different measurement scales, even when using the same scales by different laboratories, are subject to uncertainties (Hall et al., 2014). For halocarbons, the difference in calibration scales has been estimated as small, but not negligible, i.e. within 2.5 %, often within 1 % (Rhoderick et al., 2015).

While we use the station data that have already been converted to the latest scales of the respective networks, some older comparison data products use previous scales (like the one published in the latest ozone assessment report; WMO, 2014). Thus, where necessary, we convert those older data to the newer scales. For 7 gases, we use scale conversion factors to convert to the SIO14 scale, specifically 1.0826 for HFC-125 (from University of Bristol scale: UB98), 1.1226 for HFC-227ea (from Empa-2005), 1.1970 for HFC-236fa (from Empa-2009-p) and 1.1909 for HFC-245fa (from Empa-2005), 1.1079 for HFC-365-mfc (from Empa-2003), 1.0485 for HFC-43-10-mee (from SIO-10-p) and 0.9903 for ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$ (from UB98), with all conversion factors taken from the Appendix in WMO (2012).

Apart from those scale conversions to the latest NOAA and SIO scales mentioned above, we only make sure that the three main gases are each on a unified scale. In the case of ${\mathrm{CO}}_{\mathrm{2}}$, we source all our ${\mathrm{CO}}_{\mathrm{2}}$ station data from the NOAA network, which means no scale conversion is necessary. In the case of ${\mathrm{CH}}_{\mathrm{4}}$, we account for different calibration scales by converting AGAGE ${\mathrm{CH}}_{\mathrm{4}}$ data (Tohuko University scale) to the NOAA scale (NOAA04) (multiplication by 1.0003). In the case of ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$, both the AGAGE (SIO1998) and NOAA network calibration scales (NOAA-2006) are compatible without the need for a conversion factor (WMO, 2012). The Law Dome data used here (Etheridge et al., 1998, 1996; MacFarling Meure et al., 2006; Rubino et al., 2013) have been updated for minor dating changes and placed on current NOAA scales (http://www.esrl.noaa.gov/gmd/ccl/index.html).

Apart from those three main gases, we do not apply further scale conversions. Thus, given that our results are based on a mixture of the AGAGE and NOAA networks, they are de facto a weighted average between the respective two standard scales (SIO and NOAA) for each gas. The effective weight in this “weighted mean” depends on the station numbers and each network's station distribution, given that our assimilation method implicitly gives less weight to stations that are geographically close, i.e. in the same latitude–longitude box. This mixture of scales is different from previous studies that either applied empirical scale conversions (so that global-mean or station averages are identical) or used both scales in parallel to estimate a measurement uncertainty (WMO, 2014), for example when estimating emissions with inverse techniques. Mathematically, our approach is similar to an approach where a station-by-station scale conversion would be applied towards an intermediate scale between NOAA and AGAGE. However, for some applications, this approach is clearly a limitation as it hides the uncertainty and would for example warrant a new data assimilation if one network updates its scales (Sect. 6). The reason this “weighted mean” approach is chosen in the context of this study is that we intend to reconstruct a single concentration history making use of the station data from both major measurement networks without giving preference to one or the other measurement scale. Given that different scales between the two major networks result in differences that are generally less than 2 % (and are often for radiatively less important substances), this “middle of the road” approach seems justified given the other uncertainties in climate model forcings (vertical distributions, radiative forcing routines, other radiative forcings such as aerosols). Any conversion to a single scale would ease comparisons, but would not be able to address the inherent measurement uncertainty, and might even face a stronger bias (if the two scales SIO and NOAA are equally plausible representations of the “truth”) (Sect. 6).

However, in regard to the time of the day, month or year, we do not apply interpolation or adjustment techniques other than a simple monthly binning of all available data (see Sect. 2.1.2). The spatial and temporal coverages of the raw data used in this study are depicted in Figs. 2, 3 and 4 for ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ data, respectively.

Availability of instrumental carbon dioxide data from 1968 to 2015 from the NOAA ESRL network, shown as data samples per month, per latitudinal band (a–l) and per longitudinal bin within each latitudinal band.

[Figure omitted. See PDF]

Availability of instrumental ${\mathrm{CH}}_{\mathrm{4}}$ data from 1983 to 2015 from the AGAGE and NOAA ESRL networks, shown as data samples per month, per latitudinal band (a–l) and per longitudinal bin within each latitudinal band.

[Figure omitted. See PDF]

Availability of instrumental ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ data from 1983 to 2015 from the AGAGE and NOAA ESRL networks, shown as data samples per month, per latitudinal band (a–l) and per longitudinal bin within each latitudinal band.

[Figure omitted. See PDF]

Step 2–4: binning and spatial interpolation

We employ a simple monthly mean binning of all available data, separately averaged for each station. Stations with more than one measurement program, e.g. with flask and in situ programs, are treated as distinct stations. Thus, the monthly average of an in situ data series with 1000 measurement points gets the same weight as the monthly average from a flask measurement program with few observations. In each latitudinal–longitudinal box, all available monthly mean station data are averaged, with the mean being assigned to the grid box centre before employing a 2-D spatial interpolation to extend available data points to longitudinal and latitudinal grid points that do not have observed data for any particular month. Our method provides equal weight to each station within a longitude–latitude box, no matter whether the station reports a few flask measurement samples or sub-hourly in situ instrument readings in each month. The chosen assimilation grid has 72 boxes with 12 equal-latitude bands of 15${}^{\circ }$ and 6 longitudinal bands of 30${}^{\circ }$. Following the temporal monthly binning and subsequent spatial linear interpolation, we average all data across the longitudes to obtain 12 latitudinally resolved monthly time series of surface concentrations.

Step 5: global-mean mole fractions

The annual global mean concentration $\stackrel{\mathrm{‾}}{C_{\mathrm{global}}}\left(y\right)$ is derived as the area-weighted arithmetic mean of the binned latitudinal data (small grey “5” in Fig. 1). In addition to the annual global mean, a time series of monthly values is derived as a smooth spline interpolation between the annual data points, with the constraint of being mean-preserving, i.e. that the average of the 12-monthly values is again the global annual average value initially derived. Thus, the trend in the mole fraction data is reflected in the global-mean time series from month to month.

Step 6: latitudinal gradient

The annual-mean latitudinal gradients are derived as first and second empirical orthogonal function (EOFs) from the annual-average residuals per latitude after subtracting the global annual mean (step 6 in Fig. 1). Let $\mathbf{G}$ be the $n\times m$ matrix of $n$ years of observations and $m$ latitudinal boxes, then $\mathbf{G}$ can be decomposed into its EOFs and scores by calculating the singular value decomposition of $\mathbf{G}={\mathbf{UDV}}^T$, where $\mathbf{U}$ and $\mathbf{V}$ are orthogonal matrices in $R_n$ and $R_m$, respectively, and $\mathbf{D}$ is the $n\times m$ matrix with non-zero elements only on the diagonal. EOF${}_i$ is the $i$th column of $\mathbf{V}$, and the score $S_i\left(y\right)$ of EOF${}_i$ in year $y$ is given as the ($y$, $i$) entry of the $\mathbf{UD}$ matrix. In other words, the EOFs are the eigenvectors of the Gram matrix $\mathrm{1}/m\times \left({\mathbf{G}}^{\prime }\mathbf{G}\right)$, and the scores are the projections of the observations $\mathbf{G}$ onto the EOFs.

Those EOF scores are regressed with suitable predictors or extended as constants. Thus, the term $\widehat{L}\left(y\right)$ is the optimal low rank approximation of the latitudinal deviations from the global mean in year $y$. It is composed of the leading EOFs of latitudinal annual-mean variation multiplied with the observed or regressed scores $S$ of that year $y$. $${\displaystyle }\widehat{L}\left(y\right)={\sum }_{i=\mathrm{1}}^{\mathrm{imax}}{\text{EOF}}_i{S}_i\left(y\right),$$ with imax being 1 or 2 if only the leading or the two leading EOFs are taken into account, respectively.

Step 7–10: seasonality

The seasonality fulfils the condition that the sum of seasonal variations at each latitude is zero over the year, i.e. $${\displaystyle }\sum _{m=\mathrm{1}}^{\mathrm{12}}{\widehat{S}}_{l,m}=\mathrm{0}.$$ This seasonality ${\widehat{S}}_{l,m}\left(t\right)$ at time t is calculated for most gases as the relative seasonality $\frac{\mathrm{d}{\widehat{S}}_{l,m}}{\mathrm{d}{C}_{\mathrm{global}}}$, i.e. the monthly deviation in mole fraction divided by the global-mean mole fraction, multiplied by the global-mean mole fraction at time $t$ (steps 7 and 10 in Fig. 1).

An exception is the case of ${\mathrm{CO}}_{\mathrm{2}}$ (steps 8 and 9 in Fig. 1). In this case, the seasonality pattern over the observational period is held fixed as absolute mole fractions, i.e. not relative to the global mean. However, the residuals between this fixed seasonality and the seasonality, which is derived from the observations by subtracting the latitudinal averages, are used for a singular value decomposition. Let $R_{l,m}\left(t\right)$ be the residuals at latitude $l$ and month $m$ at time $t$; the optimal lower rank representation of this seasonal change is then given by the first EOF of the gram matrix $\mathrm{1}/n\times {\mathbf{R}}^{\prime }\mathbf{R}$, with $n$ being the number of observational data points. The derived score, i.e. the projection of the residuals onto the first EOF, is regressed against a time series $P$, a composite of global-mean ${\mathrm{CO}}_{\mathrm{2}}$ concentration and historical observed global-mean surface air temperatures. This simplified choice is made because previous studies identified warmer temperatures and elevated ${\mathrm{CO}}_{\mathrm{2}}$ mole fractions as dominant reasons for increased seasonality (Forkel et al., 2016; Graven et al., 2013; Welp et al., 2016), although anthropogenically induced cropland productivity increases are also suggested to play some role (Gray et al., 2014). Specifically, $P$ is assumed to be a composite of the product and the sum of normed global-mean surface air temperature and normed ${\mathrm{CO}}_{\mathrm{2}}$ mole fraction deviations from pre-industrial levels. The temperature and mole fraction deviations are normalized such that the 2000–2010 deviation from the 1850–1880 base period is set to 1. Thus, the regressor $P$ can be described as follows: $${\displaystyle }P\left(t\right)={\displaystyle \frac{\mathrm{\Delta }T\left(t\right)\cdot \mathrm{\Delta }C\left(t\right)}{\mathrm{2}}}+{\displaystyle \frac{\mathrm{\Delta }T\left(t\right)+\mathrm{\Delta }C\left(t\right)}{\mathrm{2}}},$$ with $\mathrm{\Delta }T$ being the temperature deviation from the 1850–1880 period, specifically $$\begin{array}{cc}{\displaystyle }& {\displaystyle }\mathrm{\Delta }T\left(t\right)\\ & {\displaystyle }& {\displaystyle }=\left(T,\left(t\right),-,\sum _{t=\mathrm{1850}}^{\mathrm{1880}},T,\left(t\right)\right)/\sum _{t=\mathrm{2000}}^{\mathrm{2010}},\left(T,\left(t\right),-,\sum _{i=\mathrm{1850}}^{\mathrm{1880}},T,\left(i\right)\right).\end{array}$$ And $\mathrm{\Delta }C$ being the normed mole fraction deviation. Note that this regressor $P$ is one of multiple options that were tested and could be regarded as a plausible regressor for seasonality changes. Specifically, we tested global-mean ${\mathrm{CO}}_{\mathrm{2}}$ concentrations, global-mean annual average surface air temperatures and lagged averages of surface air temperatures as regressors (see Fig. 5). The $R$-squared values of the regressions over the 1984–2014 period are relatively similar across all regressors, around 0.8. The marked difference is that the regression with only ${\mathrm{CO}}_{\mathrm{2}}$ concentrations would result in a stronger reduction of seasonality around 1940–1960 and before 1900. By 1850, the reduction of summertime ${\mathrm{CO}}_{\mathrm{2}}$ concentrations in the zonal band around 52.5${}^{\circ }$ N would be around 8.6 $\mathrm{ppm}$ compared to 2014 (multiply the differences of the seasonality scaling difference between 1850 and 2014, about 21, with the 0.41 ppm maximum of the EOF pattern, shown in Fig. 9a.2). In contrast, the other regression options would limit the maximal seasonality change to about 5.7 $\mathrm{ppm}$, closer to the maximal seasonality change detected within the period 1984–2014, of 4.5 $\mathrm{ppm}$ (cf. Fig. 5e). Given the uncertainty in regard to pre-1960 seasonality, we opted for the more conservative extrapolation method that implies a less significant change outside the observational period and chose the regressor with the least variability, namely our composite regressor combining temperature and ${\mathrm{CO}}_{\mathrm{2}}$ concentrations.

Comparison of various scaling options for the change of seasonality of ${\mathrm{CO}}_{\mathrm{2}}$ concentrations over time. The first EOF of the residual fields of observations minus the mean 1984–2014 ${\mathrm{CO}}_{\mathrm{2}}$ seasonality (Fig. 9a.2) is scaled with an EOF score. Before 1984, this EOF score is regressed against a composite of global-mean ${\mathrm{CO}}_{\mathrm{2}}$ concentrations and global-mean surface air temperatures (see text and panel b). Alternative regressors include global-mean ${\mathrm{CO}}_{\mathrm{2}}$ concentrations (a), lagged averages of monthly global-mean surface air temperatures (c) and raw global-mean annual average surface air temperatures (HadCRUT4v) (Morice et al., 2012) (d). The regressed EOF score back in time is shown in (e). A comparison to the first ${\mathrm{CO}}_{\mathrm{2}}$ measurements of higher northern latitudes at so-called Station P (STP) and Point Barrow in Alaska (PTB), where the seasonality change is most pronounced, is provided in (f) and (g), respectively (see text for discussion).

[Figure omitted. See PDF]

Despite the differences in the regressors, it should be noted that early ${\mathrm{CO}}_{\mathrm{2}}$ observations are too sparse to come to a definite conclusion in regard to which regressor is best suited – given that the induced differences around the 1960s and 1970s are fairly small compared to the noise in the observations (see Fig. 5f and g). Furthermore, seasonality changes in the case of ${\mathrm{CO}}_{\mathrm{2}}$ depend on a number of factors, inter alia complex interaction of ${\mathrm{CO}}_{\mathrm{2}}$ fertilization of temperate, seasonal gross primary productivity, the influence of temperature, precipitation on biomass growth and respiration, and directly human-induced changes in land use areas and their productivity. Therefore, this extension of the observed seasonality changes beyond the observational period based on a regression with temperatures and ${\mathrm{CO}}_{\mathrm{2}}$ concentrations is just that: a plausible extrapolation that needs to be refined by further research to replace this study's ad hoc assumption.

The measured seasonality of ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ over the observational time period is found to be closely approximated by our default assumption of a seasonality that is proportional to global-mean mole fractions. For several other substances, however, seasonality has been assumed to be zero – either because the diagnosed seasonality was very small or due to a lack of observational data.

Step 11–13: extension of latitudinal gradients and global means with ice core and firn data

Historical GHG records from ice and firn provide high-latitude estimates of atmospheric GHG mole fractions before the instrumental record from air sampling stations. We rely mainly on the Law Dome data (Etheridge et al., 1998, 1996; MacFarling Meure et al., 2006; Rubino et al., 2013), updated for minor dating changes and placed on current NOAA scales, and, for northern hemispheric ${\mathrm{CH}}_{\mathrm{4}}$, Greenland NEEM ice core data (Rhodes et al., 2013). Although we did not directly use their data, we acknowledge multiple other efforts, including but not limited to Mitchell et al. (2013), Bauska et al. (2015), Schilt et al. (2010b), Fluckiger et al. (2002) and Sowers et al. (2003) (Fig. 6). Law Dome atmospheric composition records have the advantage of a very narrow air age spread that provides measurements with high temporal resolution and mean air ages up to the 1970s, where they overlap with the beginning of atmospheric observations for many gases.

Having obtained estimates of the latitudinal gradients over the observational period and having derived approximations back in time by regressing latitudinal gradients EOF scores with emissions (step 11 in Fig. 1, Table 4), we can estimate global-mean mole fractions based on the Law Dome data for both ${\mathrm{CO}}_{\mathrm{2}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ (step 12 in Fig. 1). In the case of ${\mathrm{CH}}_{\mathrm{4}}$, the advantage is that there are northern hemispheric data available from NEEM (Greenland) (Rhodes et al., 2013) over the past 2000 years. This NEEM record hence allows an optimization of both the EOF scores and global means at past time points to match both the Law Dome and NEEM records (step 13 in Fig. 1). Some data gaps in the NEEM record are filled by linearly interpolating the optimized EOF scores of the latitudinal gradient. With an interpolated EOF score, the global-mean mole fraction can then be directly inferred from the Law Dome record. All optimizations are performed by minimizing area-weighted squared residuals.

The Law Dome ice core data are smoothed with a piecewise local third-degree polynomial median regression, using ad hoc expert judgement assumptions of errors and smoothing window widths specific to each gas in order to approximately reflect their long-term median evolution. In the case of ${\mathrm{CO}}_{\mathrm{2}}$, a random error of 2 $\mathrm{ppm}$ was assumed, a percentage age error (reaching a maximum of 60 years at age 2000 years before present) with a bagging of 250 ensembles, a kernel width of 120 years, minimal number of data points of 7 and maximum of 25 (Fig. 8a). Likewise, ${\mathrm{CH}}_{\mathrm{4}}$ Law Dome data ice core data are smoothed with a third-degree polynomial median regression with a maximum kernel width of 100 years, 4 minimal data points (a constraint that overwrites the maximum kernel width, if necessary) and 10 maximal data points. As for ${\mathrm{CO}}_{\mathrm{2}}$, 250 ensembles were averaged, after adding noise of 3 $\mathrm{ppb}$, and an age uncertainty of 50 years per 2000 years. For ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$, a kernel width of 300 years was chosen with a minimum number of 7 and maximum number of 15 data points to be included in the piecewise third-degree polynomial regression. As for ${\mathrm{CO}}_{\mathrm{2}}$ and ${\mathrm{CH}}_{\mathrm{4}}$, 250 ensembles were used for bagging after injecting a random noise of 3 $\mathrm{ppb}$ and an age-dependent $x$ axis uncertainty of 90 years per 2000 years. The higher age uncertainty for ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ in comparison to ${\mathrm{CO}}_{\mathrm{2}}$ and ${\mathrm{CH}}_{\mathrm{4}}$ was chosen to account for the larger age gaps in the ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ Law Dome data that required a stronger horizontal smoothing for the median regression to converge. For ${\mathrm{CO}}_{\mathrm{2}}$, the slightly higher age uncertainty in comparison to ${\mathrm{CH}}_{\mathrm{4}}$ was chosen so that the smoothed record displays a comparable time evolution to the WAIS ${\mathrm{CO}}_{\mathrm{2}}$ record (Fig. 6).

Atmospheric ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ concentrations over different timescales, from 800 000 years ago until today (a), over the last 2000 years (panel b) and over 1850–2014 (c, d, e). The shown data is for ${\mathrm{CO}}_{\mathrm{2}}$: Mauna Loa data by Keeling et al. (1976); the Law Dome ice record (Etheridge et al., 1998; MacFarling Meure et al., 2006; Rubino et al., 2013), updated for minor dating changes and placed on current NOAA scales; NOAA ESRL station data (NOAA, 2013; NOAA ESRL GMD, 2014a, b, c); the EPICA composite data (Ahn and Brook, 2014; Bereiter et al., 2015; Bereiter et al., 2012; Lüthi et al., 2008; MacFarling Meure et al., 2006; Marcott et al., 2014; Monnin et al., 2004; Petit et al., 1999; Rubino et al., 2013; Schneider et al., 2013; Siegenthaler et al., 2005); and the WAIS data (Bauska et al., 2015). For ${\mathrm{CH}}_{\mathrm{4}}$, the shown data is the Law Dome data (Etheridge et al., 1998; MacFarling Meure et al., 2006), the instrumental data from the NOAA and AGAGE networks (see Table 3), NEEM ice core measurements (Rhodes et al., 2013), the EPICA Dronning Maud Land ice core record (Barbante et al., 2006; Capron et al., 2010; Schilt et al., 2010b), and the long record by Loulergue et al. (2008) as well as the GISP2D, WDC05A and WDC06A records by Mitchell et al. (2013). In case of ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$, the shown data is the Law Dome record (MacFarling Meure et al., 2006), the Talos Dome record (Schilt et al., 2010b), the GISPII record (Sowers et al., 2003) and the EPICA Dome C record (Fluckiger et al., 2002; Schilt et al., 2010a; Spahni et al., 2005; Stauffer et al., 2002) in addition to the H15 ice core record from Antarctica (Machida et al., 1995), the South Pole firn record (Battle et al., 1996), the Law Dome firn record “Park” (Park et al., 2012) and a modelling synthesis by Ishijima (2007). For data sources behind “this study's” composite product, see Tables 2, 3 and 4.

[Figure omitted. See PDF]

The Greenland NEEM ice core ${\mathrm{CH}}_{\mathrm{4}}$ data (Rhodes et al., 2013) exhibits some outliers in the recent period (Fig. 6d) due to the incursion of modern air into still-open pores of shallow ice. Spikes in deeper ice are likely due to impurities. Hence we use the 5-year smoothed data provided by Rhodes et al. (2013) as a proxy for Greenland atmospheric background mole fractions (open red circles in Fig. 6b and d). We used the NEEM ${\mathrm{CH}}_{\mathrm{4}}$ firn measurements from Buizert et al. (2012) (2008 campaign), with effective ages from Ghosh et al. (2015) based on the iterative dating method of Trudinger et al. (2002b), corrected for the effect of gravity (as applied in other firn data) and put onto the NOAA 2006 primary calibration scale.

Options for reducing the number of GHGs to be taken into account in climate models to approximate full radiative forcing of all GHGs. The GHGs are ranked by their radiative forcing, with ${\mathrm{CO}}_{\mathrm{2}}$ having the highest radiative effect change between 1750 and 2014. The stated percentages in this table's rows are cumulative, i.e. the radiative forcing stated in a row is the radiative forcing of the GHG stated in that row plus the sum of all higher-ranked GHGs in the rows above, expressed as percentage of total anthropogenic GHG radiative forcing. In Option 1, a climate model explicitly resolves actual GHG concentrations. With 8 and 15 species, 99.1 and 99.7 % of the total radiative effect can be captured, respectively. In Option 2, only CFC-12 is modelled next to ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$; all other gases are summarized in a CFC-11-equivalence concentration. In Option 3, all ODSs are summarized in a CFC-12-equivalence concentration, and all other fluorinated substances are summarized in HFC-134a-equivalence concentrations. Note that below shares are approximations, as linear radiative forcing efficiencies are assumed here for all gases, and also for ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ and ${\mathrm{CH}}_{\mathrm{4}}$.

Step 14: extension of latitudinal gradients and global means with literature data

For several gases, including ODSs, halons and PFCs, the available AGAGE and NOAA station data is spatially sparse. Before the start of systematic instrumental measurements, we use literature studies which make use of various data sources, such as air sample archives or firn records (step 14 in Fig. 1). Specifically, if a global mean is provided, we use that global mean in conjunction with our derived and regressed latitudinal gradients. In the case of hemispheric data points, we adapt the latitudinal gradient to match the literature studies, as in the case of ${\mathrm{C}}_{\mathrm{4}}{\mathrm{F}}_{\mathrm{10}}$, ${\mathrm{C}}_{\mathrm{5}}{\mathrm{F}}_{\mathrm{12}}$, ${\mathrm{C}}_{\mathrm{6}}{\mathrm{F}}_{\mathrm{14}}$, ${\mathrm{C}}_{\mathrm{7}}{\mathrm{F}}_{\mathrm{16}}$ or ${\mathrm{C}}_{\mathrm{8}}{\mathrm{F}}_{\mathrm{18}}$, where we based both the global mean and latitudinal gradients on the data of Ivy et al. (2012). Other key studies used were Velders and Daniel (2014), the data underlying the WMO Ozone Assessment Report (2014), Arnold et al. (2013, 2014), Trudinger et al. (2004), Mühle et al. (2010, 2009), Montzka et al. (2011), updated time series by Montzka et al. (1999) (updated at ftp://ftp.cmdl.noaa.gov/hats/Total_Cl_Br/), the recent study by Vollmer et al. (2016) in regard to Halons and by Trudinger et al. (2016) in regard to PFCs, and others (Arnold et al., 2013, 2014; Butler et al., 1999; Ivy et al., 2012; Montzka et al., 2015; Mühle et al., 2010; Oram et al., 2012; Trudinger et al., 2016; Velders and Daniel, 2014; Vollmer et al., 2016; Worton et al., 2007), as indicated in the gas-specific fact-sheet figures (Figs. S1–S40 with references provided in Table 12). In the case of ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ and ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$, we assumed a constant latitudinal gradient back in time before ongoing measurement records are available (Figs. 12 and S7, respectively).

Step 15: extrapolation

For some limited data segments, an extrapolation has been used: either a piecewise smoothing spline to converge concentrations back to zero or pre-industrial background concentrations, e.g. before the WMO (2014) or Velders and Daniel (2014) data started in 1978 or 1951, respectively. The three radiatively most important fluorinated species, CFC-12, CFC-11 and HCFC-22 (Table 5), follow the global mean concentrations provided by Velders and Daniel (2014), in conjunction with separately derived latitudinal gradients and seasonality. Furthermore, a linear extrapolation was applied when there were not sufficient 2014 data available.

Step 16–19: creating the composite surface concentration field

Following Eq. (1), the surface mole fraction fields over the full-time span are now synthesized from the lower rank representations of seasonality, latitudinal gradient and the smooth monthly representation of global-mean mole fractions. As per the original station data aggregation, the latitudinal resolution is 15${}^{\circ }$ and the time resolution is monthly. In order to assist with application in climate models with finer grids, we also produced a finer grid interpolation to 0.5${}^{\circ }$ latitudinal resolution using a mean-preserving smoothing. This finer grid interpolation should not be mistaken as a mole fraction field containing actual information at 0.5${}^{\circ }$ level. The purpose is simply to offer a smooth interpolation that avoids errors that will arise from, for example, a linear interpolation between the provided 15${}^{\circ }$ latitude points, as the mean across those (linearly) interpolated values would not match the original field. The mean-preserving smoothing code is available from the authors on request. Finally, the 15${}^{\circ }$ fields are aggregated into global, Northern and Southern Hemisphere monthly and annual means.

Step 20: aggregating equivalent mole fractions

It is computationally inefficient to model the radiative effect of 43 individual GHGs in today's ESMs or general circulation models. Climate models use different pathways to approximate the radiative effects of the full set of GHGs. As one strategy, only the radiatively major GHGs are explicitly modelled, such as ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$, ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$, CFC-12 and CFC-11, which together cause 94.5 % of the GHG warming effect (measured in radiative forcing) in 2014 relative to 1750 and 98 % of the total radiative effect compared to the full set of 43 GHGs (Table 5). Alternatively, radiatively minor GHGs can be approximated by equivalent GHG concentrations of a marker gas. In this way, the radiative effect of the group of gases is expressed by a single gas mole fraction. One definitional issue is whether the radiative forcing since 1750, i.e. only the changes since pre-industrial levels, are expressed by the marker gas (here called “marginal equivalence” $C_{\mathrm{eq},i})$. In this case, the marker gas' concentrations $C_{\mathrm{eq},i}$ are sought that would exert the same aggregate radiative forcing since 1750 as the group of summarized gases. Thus, let $C_j\left(t\right)$ be the concentration (mole fraction in dry air) of a GHG and $C_{\mathrm{0},j}$ the pre-industrial level, i.e. in year 1750, which is routinely used as base year for radiative forcing (IPCC, 2013). A marker equivalence mole fraction by gas $C_{\mathrm{eq},\mathrm{1}}$ for group $C_j$ with $j=\mathrm{1},\mathrm{\dots }n$ is then given by the following: $${\displaystyle }{C}_{\mathrm{eq},i}\left(t\right)=R_i^{-\mathrm{1}}\left(R_i,\left(,C_{\mathrm{0},i},\right),+,\sum _{j=\mathrm{1}}^n,\left(R_j,\left(C_j,\left(t\right)\right),-,R_j,\left(C_{\mathrm{0},j}\right)\right)\right),$$ with $R_j\left(C\right)$ being the radiative forcing function relating concentrations $C\left(t\right)$ at time $t$ to radiative forcing for gas $j$, in the linear case $R_j\left(C\right)=C\cdot E_j$, with $E_j$ being the radiative efficiency. $R_i^{-\mathrm{1}}\left(F\right)$ is the inverse of this radiative forcing function, so that the concentration $C$ that corresponds to a forcing $F$ is given by $C=R_i^{-\mathrm{1}}\left(F\right)$.

In contrast, equivalent concentrations can express the radiative effects of the summarized GHGs including their natural background levels (here called “full equivalence” ${C^{\prime }}_{\mathrm{eq},i})$. $${\displaystyle }{C^{\prime }}_{\mathrm{eq},i}\left(t\right)=R_i^{-\mathrm{1}}\left({\sum }_{j=\mathrm{1}}^n,R_j,\left(C_j,\left(t\right)\right)\right)$$ While the former definition, “marginal equivalence”, is often used to express the total GHG forcing in ${\mathrm{CO}}_{\mathrm{2}}$ equivalence concentrations, the latter “full equivalence” is the more appropriate quantity to drive climate models, given that natural background concentrations of not-explicitly-considered gases should nevertheless exert a radiative effect even in a pre-industrial control, even though that radiative effect does not count under a radiative forcing definition that looks at changes from 1750.

In the linear case, in which case radiative forcing is proportional to the gas' concentrations, Eq. (7) can be written as follows: $${\displaystyle }{C^{\prime }}_{\mathrm{eq},i}\left(t\right)={\displaystyle \frac{\sum _{j=\mathrm{1}}^n{r}_j^{\mathrm{eff}}\cdot C_j\left(t\right)}{r_i^{\mathrm{eff}}}},$$ with $r_i^{\mathrm{eff}}$ being the radiative efficiency of gas $i$ ($\mathrm{W}{\mathrm{m}}^{-\mathrm{2}}$ per ppb).

Thus, climate models have the option to reduce the complexity of 43 GHGs and the associated computational burden by reducing the number of GHGs that are taken into account. With the top 5 GHGs, ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$, ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$, CFC-11 and CFC-12, climate models would capture 98 % of the total radiative effect in year 2014 and 94.5 % of the radiative forcing since 1750, i.e. the change of the radiative effect between 1750 and 2014 (see Table 5). As an alternative, there is the option to use equivalent concentrations. For two such equivalence options, this study provides input datasets. Modelling groups should indicate the combination of files they employed:

• Option 1: climate models implement a subset of 43 GHGs.

• Option 2: climate models implement the four most important GHGs with their actual mole fractions explicitly, namely ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$, ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ and CFC-12, and summarize the effect of all other 39 gases in an equivalence concentration of CFC-11. For this purpose, we provide CFC-11 eq. concentrations (“full equivalence”).

• Option 3: like option 2, but with a different split up of gases other than ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$. Climate models implement the three most important GHGs with their actual mole fractions explicitly, namely ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$, and summarize the radiative effect of the ODSs in a CFC-12 eq. concentration and the radiative effect of all other fluorinated gases as a HFC-134a eq. concentration. For this purpose, we provide CFC-12 eq. and HFC-134a eq. concentrations (“full equivalence”).

Data analysis for comparison with CMIP5 ESMs

We compare our results to various other datasets (see Sect. 5), inter alia to ${\mathrm{CO}}_{\mathrm{2}}$ fields from CMIP5 ESMs (Sect. 5.3). Here, we briefly describe the analytical steps that we performed for retrieving the ESM data. We analyse 10 CMIP5 ESMs that have an interactive carbon cycle model and provided the mole fraction of carbon dioxide in the air as function of different pressure surfaces for the esmhistorical experiment. We diagnosed those esmhistorical experiments in terms of the simulated ${\mathrm{CO}}_{\mathrm{2}}$ mole fraction at surface pressure (1 $\mathrm{bar}$ $=$ 100 000 $\mathrm{Pa}$) for 10 CMIP5 ESMs, for which data were available: (1) BNU-ESM (BNU, China), (2) CanESM2 (CCCMA, Canada), (3) CESM1-BGC (NSF-DOE-NCAR, USA), (4) FIO-ESM (FIO, China), (5) GFDL-ESM2G (NOAA GFDL, USA), (6) GFDL-ESM2M (NOAA GFDL), (7) MIROC-ESM (MIROC, Japan), (8) MPI-ESM-LR (MPI, Germany), (9) MRI-ESM1 (MRI, Japan) and (10) NorESM1-ME (NCC, Norway). For the models CanESM2, MIROC-ESM and MPI-ESM-LR more than one realization is available. We calculated an ensemble mean based on all available ensemble members. The climatological seasonal cycle (Figs. S43 and S44) is calculated relative to the linear trend of the corresponding 30-year periods.

Comparison of 1950–1990 ${\mathrm{CO}}_{\mathrm{2}}$ concentrations with early Scripps station data (Keeling et al., 2001) for each 15${}^{\circ }$ latitudinal band. Also, the Law Dome ice record data is shown (k) with our third-degree polynomial smoothing. This study's monthly ${\mathrm{CO}}_{\mathrm{2}}$ zonal means were derived from station data from 1984 onwards. Before that, this study used Mauna Loa MLO annual average and smoothed Law Dome data (see Table 1 and Sect. 2). The shown comparison with monthly Scripps station data before 1984 is a qualitative validation of the applied methodology to regress latitudinal gradient and seasonality changes to times before 1984. See text.

[Figure omitted. See PDF]

Historical GHG concentrations from 1750 to 2014 as global-mean (right panels), northern hemispheric (middle panels) and southern hemispheric averages (right panels). The top row comprises all GHGs, the middle row comprises HFCs, PFCs, ${\mathrm{SF}}_{\mathrm{6}}$, ${\mathrm{NF}}_{\mathrm{3}}$ and ${\mathrm{SO}}_{\mathrm{2}}{\mathrm{F}}_{\mathrm{2}}$. The lower row comprises all ozone-depleting substances, expressed as equivalent CFC-12 eq. concentrations. In the narrow boxes, the last data year from 15 January 2014 to 15 December 2015 is shown, indicating the intra-annual trend (top row), increasing gradient (middle row) or relatively flat concentration levels (lower row).

[Figure omitted. See PDF]

Results

Here, we describe the historical concentrations of the main GHGs and provide a fact sheet for all 43 individual gases.

Carbon dioxide

The 800 000-year EPICA composite ice core record (Ahn and Brook, 2014; Bereiter et al., 2015, 2012; Lüthi et al., 2008; MacFarling Meure et al., 2006; Marcott et al., 2014; Monnin et al., 2004; Petit et al., 1999; Schneider et al., 2013; Siegenthaler et al., 2005. Available at ftp://ftp.ncdc.noaa.gov/pub/data/paleo/icecore/antarctica/antarctica2015co2.xls) indicates that ${\mathrm{CO}}_{\mathrm{2}}$ concentrations have fluctuated between 170 and 270 $\mathrm{ppm}$ (Fig. 6a) in conjunction with glacial and inter-glacial temperature variations. From the year 0 to 1000, our piecewise fit of the third-degree polynomial of Law Dome ice core data allows a derivation of global mean concentrations of around 278.6 $\mathrm{ppm}$ (minimum–maximum range of 277.0–280.2 $\mathrm{ppm}$).

Our smoothed Law Dome results do not reflect the higher-frequency variations suggested by the individual data points (Etheridge et al., 1996; MacFarling Meure et al., 2006; Rubino et al., 2013) and are comparable to the frequency spectrum that would result from a smoothed median estimate of WAIS data by Bauska et al. (2015) and Ahn et al. (2012). The WAIS record is generally 3–6 $\mathrm{ppm}$ higher than the Law Dome record and is also higher than South Pole and EPICA DML ice cores (Ahn et al., 2012) and the Dronning Maud Land ice (Rubino et al., 2016). The cause for this difference is not yet known (Fig. 6b). The differences between the WAIS and the Law Dome record persist in 1850–1890 with subsequent data points being more aligned with each other (Fig. 6c). CMIP6 modelling groups might want to test an alternative dataset that captures those higher-frequency characteristics of the Law Dome record (data can be generated by the authors on request). In that higher-frequency dataset, the minimum of global mean ${\mathrm{CO}}_{\mathrm{2}}$ concentrations is close to 270 $\mathrm{ppm}$ around the year 1610. The smoother version provided for CMIP6 has its minimum in year 1666 at 276.27 $\mathrm{ppm}$ (Fig. 6b). The reason for the 1610 dip in the Law Dome record and why this does not show in the WAIS record is not yet fully understood. The current understanding of how the age kernel (to estimate the distribution of age of air at the time of bubble trapping) is different for the two sites cannot yet explain this difference in concentrations around 1610.

In regard to the latitudinal gradient, we explored various options. If we regress the scores of the first EOF of the latitudinal gradient (Fig. 9d) against global fossil ${\mathrm{CO}}_{\mathrm{2}}$ emissions, the pre-industrial latitudinal minimum of surface ${\mathrm{CO}}_{\mathrm{2}}$ concentrations would be estimated in the mid-northern latitudes (approximately 1.8 $\mathrm{ppm}$ below the global mean), where the maximum was observed in recent decades (e.g. 4.8 $\mathrm{ppm}$ above the global mean in 2010). Previously a similar regression approach between concentrations and ${\mathrm{CO}}_{\mathrm{2}}$ emissions was used by Keeling et al. (2011) to separate the anthropogenic from the natural component in the concentration difference between Mauna Loa and the South Pole. This approach is not perfect due to the covariance of regional fossil fuel emissions with natural sinks over the same period, different patterns of anthropogenic land-use emissions and a latitudinal gradient component that merely results from seasonal ${\mathrm{CO}}_{\mathrm{2}}$ exchange (e.g. Denning et al., 1995). Nevertheless, this regression approach can provide a first indication of the influence of anthropogenic emissions on the latitudinal gradient. Furthermore, this approach would result in an approximately 0.4 $\mathrm{ppm}$ higher pre-industrial Antarctic ${\mathrm{CO}}_{\mathrm{2}}$ concentration compared to the global mean, coinciding with the assumption taken by Rubino et al. (2013). The Scripps station data not used in this calibration (i.e. all Scripps stations except for Mauna Loa) turn out to be matched rather closely by our approach over the 1950–1990 period (see Fig. 7).

However, given the evidence by CMIP5 ESMs of a slight tropical local maximum (Fig. 9b) and large uncertainties regarding pre-industrial sinks and source distributions and hence the latitudinal gradients of ${\mathrm{CO}}_{\mathrm{2}}$, we assumed a zero pre-industrial latitudinal gradient. Thus we performed a zero-intercept regression of the scores of the latitudinal gradient EOF1 with global fossil ${\mathrm{CO}}_{\mathrm{2}}$ emissions and converged the score of the second EOF towards zero, resulting in a flat latitudinal gradient in pre-industrial times.

The second EOF of the latitudinal gradient of ${\mathrm{CO}}_{\mathrm{2}}$ does not exhibit the same linearity over time as the first EOF, and the reasons are currently unknown. Potential candidates for this pronounced spike (Fig. 9c) of mid-northern latitude concentrations in the case of ${\mathrm{CO}}_{\mathrm{2}}$ are a shift in station sampling locations with more “polluted” land stations coming online after 1995, the “rectifier” effect due to an enhanced seasonal cycle (Denning et al., 1995) and the rise of Chinese emissions (the onset around year 2003 of the recent surge in Chinese ${\mathrm{CO}}_{\mathrm{2}}$ emissions is approximately coinciding with the respective EOF score becoming strongly positive; Fig. 9d; Francey et al., 2013). One suggested explanation for this 2010 change in north–south gradients are changes in interhemispheric transport (Francey and Frederiksen, 2016). Recently, i.e. after 2010, this spike in mid-latitude northern concentrations seemed to somewhat subside again according to our analysis (see scores for EOF1 and EOF2 in Fig. 9d). Future research could address the underlying reasons of this change in latitudinal patterns, and a physical explanation will allow a more appropriate backward extension in time.

The diagnosed average seasonality of atmospheric ${\mathrm{CO}}_{\mathrm{2}}$ concentrations over the observational period reflects the standard carbon cycle pattern of strong ${\mathrm{CO}}_{\mathrm{2}}$ uptake in spring and release in autumn due to photosynthesis and heterotrophic respiration in the Northern Hemisphere's ecosystems. Our EOF analysis of the residuals shows (Fig. 9a.2 and 9a.3) that the seasonality has increased over recent decades in line with previous studies, which explore the link to increased ecosystem productivity (Forkel et al., 2016; Graven et al., 2013; Welp et al., 2016) and increased cropland productivity (Gray et al., 2014). Specifically, our analysis shows a slight shift of the seasonality to earlier months in the year, i.e. the negative and positive deviations of the EOF pattern are shifted by a month compared to the average seasonality (cf. Fig. 9a.1 and 9a.2). The strongest change in ${\mathrm{CO}}_{\mathrm{2}}$ seasonality is derived for the latitudinal bins centred at 37.5${}^{\circ }$ N and up to 67.5${}^{\circ }$ N bins with a maximum strengthening of negative deviations in the latitudinal band centred at 52.5${}^{\circ }$ N in July by around 4 $\mathrm{ppm}$ over 1984–2013 (4 ppm results from multiplying the EOF pattern value in July in the 52.5${}^{\circ }$ bin with the EOF score difference of around 10, see Fig. 9a.2 and a.3). The maximum strengthening of the seasonal cycle happens in July in the 52.5${}^{\circ }$ latitudinal band; however, the maximum seasonal cycle deviation is still observed slightly later in August and also extends slightly more towards the northern latitudes (Fig. 9a.1).

In 1850, the start of the historical CMIP6 simulations, the estimated global-mean ${\mathrm{CO}}_{\mathrm{2}}$ concentration is 284.32 $\mathrm{ppm}$, rising to 295.67 $\mathrm{ppm}$ in 1900, 312.82 $\mathrm{ppm}$ in 1950, 369.12 $\mathrm{ppm}$ in year 2000 up to 397.55 $\mathrm{ppm}$ in 2014 (Table 6). Here and elsewhere (e.g. Table 6) we provide more significant figures than is customary – not to claim a 5-digit precision of the data, but to avoid unnecessary (even if small) step changes in concentrations between the pre-industrial run and the historical and other runs. Our methodology does not include a formal uncertainty analysis. As a minimum uncertainty for the 1850 pre-industrial values, we refer to the 1.2 ppm variability stated by Etheridge et al. (1996), also used in Rubino et al. (2013) and Trudinger et al. (2002a), as minimum uncertainty for that period.

Overview of historical ${\mathrm{CO}}_{\mathrm{2}}$ concentrations. (a.1) The average seasonality of ${\mathrm{CO}}_{\mathrm{2}}$ over the observational period, (a.2) the change of seasonality over time. (a.3) The observationally derived and extended EOF score of the seasonality change. The first EOF1's score is almost linearly increasing over the time of instrumental data from 1984 to 2014. (b) The latitudinal variation of mole fractions (dashed lines), shown for example years from 1500 to 2014, including (for comparison) the average of three CMIP5 ESMs (solid lines). (c) The first and second EOF of latitudinal variation. The second EOF exhibits a strong signal around mid-northern latitudes (d), the EOF scores derived from the observational data (dots) and regression (dashed line) as well as the ultimately used EOF score (solid line). The second EOF's score indicates that the mid-latitude northern spike was only a recent phenomenon and the score is here assumed to linearly converge to zero. The first EOF's score is more linearly increasing, and regressed against global fossil emissions. (e) The resulting latitudinal-monthly concentration field, here shown between 1950 and 2014. (f) Global and hemispheric means of the derived concentration field over the same time period 1950–2014 in comparison to monthly station data (grey dots), latitudinal average station data (coloured circles) and various literature studies (see legend). (g) Same as (f), except for time period 1750–2014. (h) Same as (f) but for time period 2005–2010.

[Figure omitted. See PDF]

Annual growth rate of ${\mathrm{CO}}_{\mathrm{2}}$ concentrations for global-mean, northern hemispheric average and southern hemispheric average concentrations. Before 1960, the smooth growth rate results from interpolated global mean values. After 1960, the growth rates are diagnosed from the surface station data, as shown in Fig. 9f. Noticeable are fluctuations of the annual growth rate around 1973, 1981 and 1992.

[Figure omitted. See PDF]

Global-mean surface ${\mathrm{CO}}_{\mathrm{2}}$ concentration growth slightly flattens off in the 1930s, and a stronger flattening occurs during World War II until the 1950s (Bastos et al., 2016). The increase from 1970 onwards has a slightly positive curvature (accelerating trend) with small deviations around 1973, 1981 and the temporary flattening of ${\mathrm{CO}}_{\mathrm{2}}$ concentrations after the 1991 Pinatubo eruption (Jones and Cox, 2001; Peylin et al., 2005) (Figs. 9 and 10).

Historical: global- and annual-mean surface concentrations for the historical CMIP6 experiments. The year-to-year and monthly resolved global, hemispheric and latitudinally resolved concentrations for 43 GHGs and three aggregate equivalent concentrations are provided in the accompanying datasets over the time horizon year 0 (1 BC) to year 2014 AD. The complexity reduction options for capturing all GHGs with fewer species than 43 are indicated in the table as Option 1, Option 2 and Option 3, with “x” denoting relevant columns under each option (Sect. 2.1.10).

Continued.

Continued.

Methane

Over the 800 000 years before year 0, atmospheric ${\mathrm{CH}}_{\mathrm{4}}$ concentrations varied between 348.7 and 728.4 $\mathrm{ppb}$ according to the EPICA ice core composite (Barbante et al., 2006; Capron et al., 2010; Loulergue et al., 2008) (Figs. 6c and 11). The Law Dome record (Etheridge et al., 1998; MacFarling Meure et al., 2006) indicates an onset of increasing concentrations around the year 1720 (Figs. 6d and 11). From year 1850 with slightly higher than 800 ppb concentrations, a slight rise is observed until the 1950s, when ${\mathrm{CH}}_{\mathrm{4}}$ concentrations markedly increase first in the latter half of the 1950s, then again from 1965 onwards. The Greenland firn and ice core data (Rhodes et al., 2013) are more difficult to interpret because part of the record is affected by high-frequency ice core ${\mathrm{CH}}_{\mathrm{4}}$ signals, possibly of non-atmospheric origin. ${\mathrm{CH}}_{\mathrm{4}}$ spikes are accompanied by elevated concentrations of black carbon, ammonium and nitrate, suggesting that biological in situ production may be responsible – particularly in the later years of the record since 1940. We use the 5-yearly average measurement values, that have outliers removed (Rhodes et al., 2013), and which approximate the lower bounds of the raw data points until 1942. Using these values, we can then infer global gradients back in time and derive an estimate of global-mean concentrations. These global-mean concentrations are estimated to be around 30 $\mathrm{ppb}$ higher than the Law Dome record by 1850, with the difference growing to 45 $\mathrm{ppb}$ by 1940s, increasing further from there (Fig. 6d). This approximately matches the findings by Mitchell et al. (2013) of interpolar differences between about 35 and 45 $\mathrm{ppb}$ between 800 BC and 1700 AD.

Overview of historical ${\mathrm{CH}}_{\mathrm{4}}$ concentrations. (a.1) The relative seasonality of ${\mathrm{CH}}_{\mathrm{4}}$ over the observational period. (b) The latitudinal variation of concentrations (dashed lines), shown for example years. (c) The first and second EOF of latitudinal variation. (d) The EOF scores derived from the observational data (dots) and regression against global emissions (dashed line) as well as the ultimately used EOF score (solid line). (e) The resulting latitudinal-monthly concentration field, here shown between 1950 and 2014. (f) Global and hemispheric means of the derived concentration field over the same time period 1950–2014 in comparison to monthly station data (grey dots), latitudinal average station data (coloured circles), and various literature studies (see legend). (g) Same as (f), except for time period 1750–2014. (h) Same as (f) but for time period 2005–2010.

[Figure omitted. See PDF]

Our analysis of ${\mathrm{CH}}_{\mathrm{4}}$ concentrations in the recent decades is based on a large number of stations (Table 3 and Fig. 11f). While the annual increase of global ${\mathrm{CH}}_{\mathrm{4}}$ concentrations slowed over the 1980s and slowed markedly after 1992 towards stabilized concentrations between 1999 and 2005, ${\mathrm{CH}}_{\mathrm{4}}$ increased again after 2006 at about 5.4 $\mathrm{ppb}{\mathrm{yr}}^{-\mathrm{1}}$ (Fig. 11f; Nisbet et al., 2016, 2014).

We retrieve a recent seasonal cycle of ${\mathrm{CH}}_{\mathrm{4}}$ that is similar in the latitudinal–temporal seasonality pattern as that of ${\mathrm{CO}}_{\mathrm{2}}$ (Fig. 11a). Each hemisphere exhibits its lowest ${\mathrm{CH}}_{\mathrm{4}}$ concentrations just after the summer solstice, up to 1.6% or 28 ppb lower than the global mean in the case of the high-latitude northern summer (Fig. 11a). Quantifying the underlying reasons is beyond the scope of this study, although the seasonally varying atmospheric sink by OH oxidization is likely the main contributor to that seasonal pattern – in combination with seasonally varying natural and anthropogenic sources.

The latitudinal annual-mean gradient of ${\mathrm{CH}}_{\mathrm{4}}$ concentrations is separated into its first two EOFs, with the first EOF being a continuous north–south gradient of about 90 $\mathrm{ppb}$ in the recent observational period (combination of EOF and its score, see Fig. 11c and d). The second EOF is a distinct mid-northern latitude local maximum with a high-latitude low, showing a slight but marked rise in 2008 within the 1985–2014 observational data window. Quantifying the reasons for this hump are again beyond the scope of this study, with the possibility of a shift in locations of sampling stations or coal-seam gas-fracking-related fugitive emissions being possible contributors. We optimize the first EOF, which is the general north–south gradient, to match the firn and ice-core Greenland and Antarctic Law Dome data. The second EOF of the latitudinal gradient is kept constant at its 1985 value.

As a result of the constant extrapolation of the second EOF, and the optimization of the first EOF's score (Fig. 11d), we yield a total annual-mean meridional gradient for recent decades that features around 80 ppb higher surface ${\mathrm{CH}}_{\mathrm{4}}$ concentrations in mid-to-high northern latitudes compared to the global mean and around 60 ppb lower ${\mathrm{CH}}_{\mathrm{4}}$ concentrations at the high southern latitudes (Fig. 11b). In pre-industrial times, our approach of regressing the score of EOF1 with global emissions (Gütschow et al., 2016) suggests that this gradient is smaller, with only approximately 20–30 ppb higher northern and 20 ppb lower southern latitude surface concentrations (Fig. 11b). These mean interpolar differences and their variations have earlier been quantified by Etheridge et al. (1998) and Mitchell et al. (2013), yielding similar results (between 30 and 60 $\mathrm{ppb}$) compared to our 40–50 ppb estimate.

Nitrous oxide

${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ concentrations from ice cores dating back 800 000 years (Fluckiger et al., 2002; Schilt et al., 2010b) varied approximately between 200 and 300 $\mathrm{ppb}$, with most recent glacial concentration minima of 180 $\mathrm{ppb}$ around 23 000 years ago (Sowers et al., 2003) (Fig. 6a). The ice core record over the last 2000 years indicates a marked difference between the Law Dome and GISPII record (Sowers et al., 2003), with the latter being up to 10 $\mathrm{ppb}$ lower. Here, as with ${\mathrm{CH}}_{\mathrm{4}}$, we use again a median quantile piecewise polynomial regression on the Law Dome record, assuming constant ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ concentrations between year 0 and the first Law Dome data point in year 154. In contrast to ${\mathrm{CH}}_{\mathrm{4}}$, there is not a monotonic increase of concentrations, but rather an initial slight decrease until year 630 down to a minimum concentration of 265 $\mathrm{ppb}$ in our smoothed time series, with a subsequent slow increase until the 9th century AD, then a slight decrease until 1650 in the smoothed global-mean mole fraction. A temporary local maximum indicated by individual Law Dome data in the 15th century is not resolved by our smoothing, and a similar spike in the 17th century is only just reflected (Fig. 6b). Several data points indicate a small decrease after a 1750 maximum with a minimum in 1850 of around 273.02 $\mathrm{ppb}$. This maximum around 1750 and subsequent minimum around 1800–1850 is also apparent in the H15 ice core record by Machida et al. (1995) (we scale-corrected the Machida data downwards by 1 $\mathrm{ppb}$ as in Battle et al., 1996) (Fig. 6b). After 1850, ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ concentrations increased markedly, reaching 1900, 1950, 2000 and 2014 values of 279.5, 289.7, 315.8 and 327.0 $\mathrm{ppb}$, respectively (Table 6). Comparing the different firn and ice records, the 1920–1940 period seems particularly uncertain, with some high measurements close to and beyond 290 $\mathrm{ppb}$ from both Law Dome and H15, while some of the Law Dome data is still at levels around 285 $\mathrm{ppb}$ or even 280 $\mathrm{ppb}$ in the case of H15 (Fig. 6e). The South Pole firn data (Battle et al., 1996) suggest lower ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ concentrations in the 1920s and around 1960 – compared to both the smoothed Law Dome data (thin dashed line in Fig. 6e) and consequently our even higher global-mean estimate. Although the Ishijima estimate (Ishijima et al., 2007) (their Fig. 6a) around 1952 is almost identical to our global mean, their modelling study suggests slightly lower values around 1960 before being closely matched again from 1970 onwards. The Law Dome firn record (Park et al., 2012) suggests slightly higher ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ concentrations for the high southern latitudes compared to our global mean (Fig. 6e).

The variability of our derived ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ global-mean concentrations, in particular the steps in the 1920s and 1940s, reflect the smoothing algorithm choices to noisy data (Sect. 2.1.6), but should not be over-interpreted. Our algorithm does not, for example, include information on the lifetime of ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ that would guard against inferring too-rapid declines of ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ mole fractions and mole fraction growth rates. The fit of the smoothing algorithm was chosen to balance the resolution of smaller-scale features with the uncertainty present in the input data sources for the full-time horizon from year 0 to year 2014. Given overall uncertainties (Fig. 6e), a smoother representation between 1900 and 1980 seems equally justified.

Compared to ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{CO}}_{\mathrm{2}}$, the seasonality and latitudinal gradient of ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ are relatively small. The ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ seasonality is only 0.1 % of global mole fractions and is almost symmetric and seasonally time-synchronized between the Northern and Southern Hemispheres, with minima in the Southern Hemisphere late autumn and northern Hemisphere summer–autumn (Fig. 12a). The seasonality is currently of the same size as the underlying trend, leading to global mean ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ mole fractions increasing in the latter months of any year, with a subsequent flattening in the first half of any calendar year (e.g. Fig. 12h). Given a counter-intuitive slight decrease of the north–south gradient with flat or slightly increasing global ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ emissions (Gütschow et al., 2016) in recent years (Fig. 12d), we assumed constant scores for the latitudinal gradient EOFs for times before 1996 (Fig. 12d). Due to measurement fluctuations in the first years when systematic measurements started in 1978 that are larger compared to the recent period, we chose to interpolate ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ global-mean mole fractions over 1966–1987. For the period between 1978 and 1987, this interpolation is closely aligned with a smooth representation of the atmospheric measurements (Fig. 12f, cf. ALE/GAGE/AGAGE data as shown at http://agage.eas.gatech.edu/data_archive/data_figures/gcmd_month/n2o_monS5.pdf).

Overview over historical ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ concentrations. As Fig. 11, but for ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$.

[Figure omitted. See PDF]

Ozone-depleting substances (ODSs) and other chlorinated substances

ODSs, i.e. the substances destroying ozone and being controlled under the Montreal Protocol, also have a large warming effect (Velders et al., 2007, 2009). In particular, CFC-12 and CFC-11 are important GHGs, as well as the replacement substance HCFC-22, which, unlike CFCs, continues to increase in the atmosphere, albeit at a declining rate. The radiative forcing of CFC-12 alone since 1750 is equivalent to that of ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$, which is usually considered the third most important GHG after ${\mathrm{CO}}_{\mathrm{2}}$ and ${\mathrm{CH}}_{\mathrm{4}}$ (Table 5). The impact of ODSs on climate is somewhat complicated by their destruction of stratospheric ozone, which induces dynamical effects on circulation patterns, and has a net cooling effect on the global climate. The latest estimates suggest that this cooling might offset roughly two-thirds of the warming of the entire class of ODSs (Shindell et al., 2013). Note that here we also consider methylene chloride and methyl chloride, although these chlorinated substances are not controlled by the Montreal Protocol and are hence often not termed ODSs (WMO, 2014).

The most abundant ODSs in the atmosphere (in 2014) were CFC-12 (520.6 $\mathrm{ppt}$), CFC-11 (233.1 $\mathrm{ppt}$) and HCFC-22 (229.5 $\mathrm{ppt}$), with their mole fractions being about 6 orders of magnitude lower than current measurements for ${\mathrm{CO}}_{\mathrm{2}}$ (Table 7). In addition, methyl chloride ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Cl}$ has a high mole fraction (539.54 $\mathrm{ppt}$), although it is not considered an ODS here as it is not controlled by the Montreal Protocol. Out of the 17 considered chlorinated and ODSs, only 6 have currently increasing concentrations. Those are the three HCFCs, of which the increase in HCFC-22 alone has offset the reducing radiative forcing of all other ODSs over the past decade (Fig. 8m). The other three substances that are still increasing are Halon-1301, methylene chloride (${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$) and chloroform (${\mathrm{CHCl}}_{\mathrm{3}}$). Chloroform had been decreasing in the 1990s and stabilized in the 2000s, but again recently showed an increase (Fig. S11).

Four of the considered chlorinated and ODSs are assumed to have natural emissions and hence above-zero pre-industrial concentrations. We estimate those pre-industrial natural background concentrations using a simple budget equation under the assumption of a constant lifetime (IPCC, 2013) of 1 year for ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Cl}$ and 0.8 years for ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Br}$ – minimizing the error term when taking into account anthropogenic emission and atmospheric concentration estimates over 1950 to 1990 by Velders and Daniel (2014). Specifically, methyl chloride (${\mathrm{CH}}_{\mathrm{3}}\mathrm{Cl}$) is assumed to have pre-industrial global-mean concentrations of 457 $\mathrm{ppt}$, and methyl bromide (${\mathrm{CH}}_{\mathrm{3}}\mathrm{Br}$) with that of 5.3 $\mathrm{ppt}$. Chloroform (${\mathrm{CHCl}}_{\mathrm{3}}$) is assumed to have a pre-industrial concentration of about 6 $\mathrm{ppt}$, approximately in line with findings by Worton et al. (2006) and the estimation by Aucott et al. (1999) that in 1990 ${\mathrm{CHCl}}_{\mathrm{3}}$ was at about 8 $\mathrm{ppt}$, with 80 % of emissions assumed to be of natural origin. Lastly, in the absence of other information (a good understanding of the natural versus anthropogenic source fraction or historical industrial production records) the available firn measurements (e.g. Trudinger et al., 2004) supplying information about methylene chloride (${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$) mole fractions in the early 20th century are used to suggest a 6.9 ppt pre-industrial mean concentration with a strong latitudinal gradient that results in northern (southern) hemisphere average concentrations of 12.8 (1.0) $\mathrm{ppt}$. The transition of concentrations of some species between the observational station data and pre-industrial levels are also uncertain. For ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$, our derivation is in line with the smooth trajectory of Trudinger et al. (2004), indicating an almost monotonic transition between 1997 values and pre-industrial concentrations (Fig. S7f). Our assimilation approach (which is based on the Walker et al., 2000 data) causes our carbon tetrachloride (${\mathrm{CCl}}_{\mathrm{4}}$) reconstruction to have a near-zero pre-industrial concentration of 0.025 $\mathrm{ppt}$ (0.025 % of its peak value of 100 $\mathrm{ppt}$). We note that Walker et al. (2000) suggest zero pre-industrial concentrations before 1910, although the lowest empirical evidence from firn records suggest $<$ 5 $\mathrm{ppt}$ (Butler et al., 1999) or 3–4 $\mathrm{ppt}$ as measured by S. Montzka for 1863 firn air and reported in Liang et al. (2016).

The seasonal cycle of ODSs and other synthetic GHGs can be influenced by seasonally varying stratospheric–tropospheric air exchanges, interhemispheric transport, tropopause heights, emissions and, for those substances with OH-related sinks, the seasonally varying OH concentrations. For 11 out of the 17 considered ODSs we find some indication of seasonal cycles based on the analysed station data, namely for ${\mathrm{CCl}}_{\mathrm{4}}$, CFC-11, CFC-12, CFC-113, ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Br}$, ${\mathrm{CH}}_{\mathrm{3}}{\mathrm{CCl}}_{\mathrm{3}}$, ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Cl}$, ${\mathrm{CHCl}}_{\mathrm{3}}$, Halon-1211 and HCFC-22. Our analysis indicates that HCFC-141b also shows some signs of a seasonal cycle, although we here assumed a zero seasonal cycle due to data sparsity (see Fig. S16a). We find the strongest seasonal cycles in the case of the short-lived species ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Cl}$, ${\mathrm{CHCl}}_{\mathrm{3}}$, ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Br}$ and ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$ with absolute maximal seasonal deviations of $-$11, $-$12 and $\pm$9, $-$32 % compared to the annual mean, respectively. For the radiatively important and longer-lived species CFC-12, CFC-11 and HCFC-22, the seasonal cycle is much smaller, with $\pm$0.2, $\pm$0.4, $\pm$0.8 %, respectively.

Similar to the seasonality, the latitudinal gradient is found to be especially pronounced for the short-lived substances. Specifically, ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$ with a lifetime of 0.4 years, ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Br}$ with a lifetime of 0.8 years, ${\mathrm{CH}}_{\mathrm{3}}{\mathrm{CCl}}_{\mathrm{3}}$ with a lifetime of 5 years, ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Cl}$ with a lifetime of approximately 1 year and ${\mathrm{CHCl}}_{\mathrm{3}}$ with a lifetime of 0.4 years show substantial latitudinal gradients due to spatially heterogeneous sinks and sources (lifetimes following Table 8.A.1 in IPCC WG1 AR5, 2013). While chemicals with predominantly anthropogenic sources normally exhibit the highest mole fractions at mid-northern to high northern latitudes, the observations for several substances with substantial natural sources exhibit highest mole fractions in the tropics or lower northern latitudes in the recent observational period (e.g. ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Cl}$ in Fig. S10b and c).

Other fluorinated GHGs

The 23 other gases in this study are the hydrofluorocarbons (HFCs), which have recently been added to the substances controlled under the Montreal Protocol (Kigali amendment in October 2016), and those substances whose production and consumption is not controlled under the Montreal Protocol, namely perfluorocarbons (PFCs) as well as sulfur hexafluoride (${\mathrm{SF}}_{\mathrm{6}}$), nitrogen trifluoride (${\mathrm{NF}}_{\mathrm{3}}$) and sulfuryl fluoride (${\mathrm{SO}}_{\mathrm{2}}{\mathrm{F}}_{\mathrm{2}}$). Except for the latter, the emissions of all these species are controlled under the Kyoto Protocol and covered by most “nationally determined contributions” (NDCs) under the Paris Agreement. However, currently the aggregated greenhouse effect of this group of synthetic GHGs is still almost a factor of 10 smaller compared to the ODSs (cf. Fig. 8g and m). In contrast to the ODSs, nearly all of these other fluorinated gas concentrations are still rising; the exception is HFC-152a, which has stopped growing since 2012 and may now be in decline, (Fig. S33f). Thus, a primary concern with these gases is the potential for substantial climate forcing in the future if uncontrolled growth continues.

The most abundant of these gases is the refrigerant HFC-134a, with 2014 concentrations estimated to be 80.5 $\mathrm{ppt}$, followed by HFC-23 (26.9 $\mathrm{ppt}$), HFC-125 (15.4 $\mathrm{ppt}$) and HFC-143a (15.2 $\mathrm{ppt}$). At the other end of the concentration spectrum, we include results from Ivy et al. (2012) for some PFCs that exhibit low concentrations of 0.13 $\mathrm{ppt}$ (${\mathrm{C}}_{\mathrm{5}}{\mathrm{F}}_{\mathrm{12}}$ and ${\mathrm{C}}_{\mathrm{7}}{\mathrm{F}}_{\mathrm{16}}$) or 0.09 $\mathrm{ppt}$ (${\mathrm{C}}_{\mathrm{8}}{\mathrm{F}}_{\mathrm{18}}$) (Table 7). The only fluorinated gas considered to have substantial natural sources, and hence a pre-industrial background concentration, is ${\mathrm{CF}}_{\mathrm{4}}$ with an assumed pre-industrial concentration of 34.05 $\mathrm{ppt}$ (see Fig. S26), in line with findings by Trudinger et al. (2016) and Mühle et al. (2010).

For a number of substances, especially the PFCs with lower abundances, there were not sufficient data available to estimate the seasonality of atmospheric concentrations. We consider seasonality only for 3 of the 23 species. HFC-134a has a somewhat atypical pattern of lowest mole fractions in the spring Northern Hemisphere ($-$2.6 % compared to annual mean) as other gases normally show a summer or autumn low point of concentrations. This spring minimum results from a seasonality of sources of this refrigerant (Fig. S31a), although seasonality in loss also likely plays a role (Xiang et al., 2014). Secondly, the short-lived HFC-152a (lifetime 1.5 years) shows seasonal variations of up to $\pm$13 % while the very long-lived ${\mathrm{SF}}_{\mathrm{6}}$ (lifetime of 3200 years) exhibits a much smaller seasonality of up to $\pm$0.5 %.

For most of the considered substances, the latitudinal gradient is rather small. Exceptions are the shorter-lived species like HFC-32, whose concentration has risen relatively quickly since 2000 due to rapidly increasing northern hemispheric sources (Fig. S28b), HFC-152a and some other shorter-lived HFCs. For the three heavier PFCs with very low abundances of well below 1 $\mathrm{ppt}$ in 2014, namely ${\mathrm{C}}_{\mathrm{6}}{\mathrm{F}}_{\mathrm{14}}$, ${\mathrm{C}}_{\mathrm{7}}{\mathrm{F}}_{\mathrm{16}}$ and ${\mathrm{C}}_{\mathrm{8}}{\mathrm{F}}_{\mathrm{18}}$, we incorporated hemispheric data from Ivy et al. (2012). Before about 1990, those three gases are suggested to have reversed latitudinal gradients with higher southern hemispheric concentrations. Due to the very low mole fractions near the limit of measurement, future studies may need to confirm whether those reverse gradients existed (and if so, why). Given the negligible radiative forcing from these gases to date, this uncertainty does not affect the overall results.

Global- and annual-mean GHG surface concentrations for year 2011 and 2014, including a comparison to 2011 NOAA, AGAGE and UCI estimates – as provided in IPCC AR5 WG1. Unit is parts per trillion (ppt), unless otherwise stated.

The CMIP6 recommendation and data format

We present the community CMIP6 datasets of historical GHG mole fractions. In conjunction with other data, these GHG surface mole fraction datasets are to be used in the historical concentration-driven runs for the Climate Model Intercomparison Project Phase 6 (CMIP6) (Eyring et al., 2016). Depending on the specific CMIP6 experiment, different protocols and recommendations can apply. Modellers should hence also check the experiment specific descriptions (see the special issue available at https://www.geosci-model-dev.net/special_issue590.html), including protocols regarding the other important forcing input datasets like aerosols, their emissions and optical properties, and land-use patterns, but also short-lived GHGs like tropospheric and stratospheric ozone for models without interactive ozone chemistry.

The historical GHG concentrations of this study are specifically designed to be useful for the historical run, as well as the idealized runs of abrupt4x, 1pctCO2 and picontrol. Also, the PMIP4-related last-millennium experiment will be based on the GHG concentrations of this study (Jungclaus et al., 2017; Kageyama et al., 2016).

Regarding the historical runs of the DECK simulations, the CMIP6 recommendation as decided by the CMIP Panel is as follows: “In the ${\mathrm{CO}}_{\mathrm{2}}$-concentration-driven historical simulations, time-varying global annual mean mole fractions for ${\mathrm{CO}}_{\mathrm{2}}$ and other long-lived GHGs are prescribed. If a modelling center decides to represent additional spatial and seasonal variations in prescribed GHG forcings, this needs to be adequately documented” (Eyring et al., 2016).

This study provides the data for both the global annual mean mole fractions as well as the mole fraction histories that take latitudinal and seasonal variations into account (see data description further below). CMIP6 modelling groups should indicate which time and space resolution of the data version they applied. All data are freely available via the PCMDI servers (https://esgf-node.llnl.gov/search/input4mips/) as netcdf files. The data is also available via ftp servers, and in multiple data formats (netcdf, csv, xls and MATLAB mat) as described at climatecollege.unimelb.edu.au/cmip6.

picontrol: global- and annual-mean surface concentrations for the picontrol CMIP6 experiment. The hemispheric and latitudinally resolved concentrations for 43 GHGs and three aggregate equivalent concentrations are provided in the accompanying historical run dataset for the year 1850. The complexity reduction options for capturing all GHGs with fewer species than 43 are indicated in the table as Option 1, Option 2 and Option 3, with “x” denoting relevant columns under each option.

In terms of the spatio-temporal resolution, four files for each of the 43 GHGs and the three equivalence species CFC-12 eq., HFC-134a eq. and CFC-11 eq. (Sect. 2.1.10) are provided as follows:

• I.

  latitudinal 15${}^{\circ }$ bins with monthly resolution (filename-code: “_15degreelatXmonth”), with monthly means for each latitudinal band provided at the centre of the box, i.e. $-$82.5, $-$67.5, $\mathrm{\dots }$ 67.5, 82.6;

• II.

  interpolated latitudinal half-degree bins with monthly resolution (filename-code: “_0p5degreelatXmonth”), with means for each latitudinal band provided at the centre of the box, i.e. $-$89.75, $-$89.25, $\mathrm{\dots }$ 89.25, 89.75. The area-weighted mean over 15${}^{\circ }$ latitudinal bands is the same as the files under variant I above;

• III.

  global and hemispheric means with monthly resolution (filename-code “_GMNHSHmeanXmonth”);

• IV.

  global and hemispheric means with annual resolution (filename-code “_GMNHSHmeanXyear”).

The CMIP6 recommendation for the picontrol experiment are to use the 1850 GHG mole fractions with annual means as provided in Table 8 (${\mathrm{CO}}_{\mathrm{2}}$ annual-mean mole fractions of 284.32 $\mathrm{ppm}$, ${\mathrm{CH}}_{\mathrm{4}}$ mole fractions of 808.25 $\mathrm{ppb}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ mole fractions of 273.02 $\mathrm{ppb}$). Other gases are covered, depending on the choice of the modelling group by either following Option 1, Option 2, or Option 3 described in Table 5, or an equivalently suited method that aggregates the radiative effect of the remaining 40 GHGs or a large fraction thereof.

The abrupt4x experiment should keep all GHG mole fractions unchanged from the picontrol run except for the ${\mathrm{CO}}_{\mathrm{2}}$ mole fractions, which should be increased instantaneously in year 1 ($=$ 1850) of the experiment to 4 times the 1850 value, namely to 1137.27 $\mathrm{ppm}$ (Table 10).

The 1pctCO2 experiment should also keep all GHG mole fractions unchanged from the picontrol run except for ${\mathrm{CO}}_{\mathrm{2}}$ mole fractions. Starting in year 1 of the experiment, ${\mathrm{CO}}_{\mathrm{2}}$ mole fractions should increase by 1 % per annum, reaching slightly over double the ${\mathrm{CO}}_{\mathrm{2}}$ mole fractions in year 70 (or 1920, if the start year is set to 1850) with 570.56 and 1264.76 $\mathrm{ppm}$ in year 150 (or year 2000) (Table 9).

As with the abrupt4x and 1pctCO2 scenarios, the historical experiment should diverge from the picontrol run. GHGs should then follow the historical observations as derived in this study, reaching, for example, ${\mathrm{CO}}_{\mathrm{2}}$ mole fractions of 397.55 $\mathrm{ppm}$ in 2014, and ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ mole fractions of 1831.47 and 326.99 $\mathrm{ppb}$, respectively. Modelling groups should document which spatial and temporal resolution (see above) of the provided data they use, as the climate effect will likely be different with different resolutions.

The future concentration pathways, the so-called “SSP-RCP” scenarios, considered under ScenarioMIP (O'Neill et al., 2016) are planned to provide the same data formats and spatio-temporal resolutions. The methodological approach to derive and adapt both seasonality and latitudinal gradients in this study was designed such that a future extrapolation will be possible.

1pctCO2: global-mean annual-mean surface ${\mathrm{CO}}_{\mathrm{2}}$ concentrations for idealized CMIP6 experiments 1pctCO2. All other gases, as in picontrol run (see Table 8). The value 284.317 $\mathrm{ppm}$ with three-digit precision in year 1850 is increased by 1 % per year.

The vertical dimension

The purpose of our reconstructions is to provide radiative forcing for climate models. This radiative forcing depends on the vertical as well as horizontal distribution of a gases' mole fraction. Our reconstructions describe only surface concentrations and modellers need some method for calculating the 3-D distribution. If the model is capable of calculating tracer transport, includes any sinks and sources in the free atmosphere, and has an appropriate treatment of the boundary layer, we recommend using this study's surface reconstruction as a mole fraction lower boundary condition for a mass balance inversion. If this is not possible, we propose a simple equation to reflect the relaxation of horizontal gradients with height and the upward propagation of mole fraction changes from the surface.

CMIP5 ESMs vertical mole fraction averages at the provided pressure levels – averaged over the 30-year period 1976–2005. The black line indicates surface mole fractions at the 1000 hPa pressure level. The red bold line indicates mole fractions at the 100 hPa level (cf. Fig. 14a and b).

[Figure omitted. See PDF]

Idealized vertical gradients recommended for implementation of surface concentration fields. For parametric formulas, see text. Note that tropospheric columns of non-${\mathrm{CO}}_{\mathrm{2}}$ gases are – for simplicity – assumed to be well-mixed. The assumed age of air at the 1 hPa level for ${\mathrm{CO}}_{\mathrm{2}}$ is 5 years.

[Figure omitted. See PDF]

Comparison between the recommended annual global mean surface concentrations of ${\mathrm{CO}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{4}}$ and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ for CMIP5 and CMIP6 historical experiments.

[Figure omitted. See PDF]

Comparison of global-mean and hemispheric monthly-average concentrations of ${\mathrm{CO}}_{\mathrm{2}}$ (a), ${\mathrm{CH}}_{\mathrm{4}}$ (b) and ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ (c) between the CMIP6 surface mole fractions (this study), the NOAA Marine Layer Boundary products, the World Data Centre of Greenhouse gases (WDCGG) products and the NASA AQUA satellite data of tropospheric ${\mathrm{CO}}_{\mathrm{2}}$ concentrations. For comparison, individual (monthly average) NOAA and AGAGE station data across all latitudes is shown in the background (grey dots).

[Figure omitted. See PDF]

Comparison of the CMIP6 historical ${\mathrm{CO}}_{\mathrm{2}}$ emissions (a) with the NOAA Marine Boundary Layer (MBL) product from 1979 to 2014 (b). Differences indicate that a seasonal higher ${\mathrm{CO}}_{\mathrm{2}}$ concentration is implied by the CMIP6 data of up to 5 $\mathrm{ppm}$ in mid-latitude northern bands, whereas some monthly tropical ${\mathrm{CO}}_{\mathrm{2}}$ mole fractions tend to be slightly lower in the CMIP6 product compared to NOAA MBL (c).

[Figure omitted. See PDF]

Comparison of the surface ${\mathrm{CH}}_{\mathrm{4}}$ monthly mean concentrations between CMIP6 (a) and the NOAA Marine Boundary Layer product (b), and the difference between them (c). Since around 1992, there are seasonal differences in the mid-northern latitudes with the CMIP6 data being up to 50 ppb higher than the NOAA MBL product. Similarly, higher concentrations are apparent in the areas of tropical southern and lower latitude southern areas, presumably due to differences of data over land areas.

[Figure omitted. See PDF]

The comparison between latitudinal and monthly ${\mathrm{N}}_{\mathrm{2}}\mathrm{O}$ concentrations to the NOAA Marine Boundary Layer product (b). The differences (c) show that the CMIP6 historical GHG concentrations are slightly higher in the Southern Hemisphere (0.5 $\mathrm{ppb}$) and slightly lower in the tropics (0.5 $\mathrm{ppb}$), as the stronger latitudinal gradient from tropics to southern latitudes is not reproduced in CMIP6 data. Note: data submitted by P. Tans, personal communication, 2016.

[Figure omitted. See PDF]

In the case of ${\mathrm{CO}}_{\mathrm{2}}$, there are no sinks in the middle and upper troposphere or stratosphere and only slight sources due to the oxidization of ${\mathrm{CH}}_{\mathrm{4}}$ and carbon monoxide (CO). Evidence from ESMs (Fig. 13) indicates an almost well-mixed tropospheric column in the tropics and little or partly reversed vertical gradient in the southern troposphere, while the annual-mean gradient in the Northern Hemisphere is – depending on the season – variable. The annual average vertical gradient in the Northern Hemisphere is decreasing in all CMIP5 ESMs analysed here (Fig. 13).

abrupt4x: Global- and annual-mean surface concentrations for the idealized abrupt4x CMIP6 experiment. The hemispheric and latitudinally resolved concentrations for 43 GHGs and three aggregate equivalent concentrations are provided in the accompanying historical-run dataset, with the 1850 ${\mathrm{CO}}_{\mathrm{2}}$ concentration of 284.317 being multiplied by 4. The complexity reduction options for capturing all GHGs with fewer species than 43 are indicated in the table as Option 1, Option 2 and Option 3, with “x” denoting relevant columns under each option.

In order to enable the implementation of surface mole fractions in models that do not have an inherent transport model to capture vertical gradients, we offer here simplified parameterizations as default options. While an assumption about a well-mixed atmospheric vertical column seems to be a justifiable simplification, these simple vertical extensions could increase the realism, vertical heating structure and overall climatic effect. Specifically, modelling teams could use the following approximation to extend surface concentration fields (at the 1000 hPa level) towards higher tropospheric and stratospheric levels. First, a bell-shaped concentration distribution is assumed at the 100 hPa level for the higher latitude tropopause and tropical upper troposphere: $$\begin{array}{cc}{\displaystyle }& {\displaystyle }C\left(l,,,,\mathrm{100},,\mathrm{hPa},,,,t\right)=\stackrel{\mathrm{‾}}{C}\left(\text{global},,,,\mathrm{1000},,\mathrm{hPa},,,,t\right)\mathrm{\dots }\\ {\displaystyle }& {\displaystyle }+(\stackrel{\mathrm{‾}}{C}\left(\text{global},,,,\mathrm{1000},,\mathrm{hPa},,,t,-,\mathrm{5},,\text{yrs}\right)-\stackrel{\mathrm{‾}}{C}\left(\text{global},,,,\mathrm{1000},,\mathrm{hPa},,,,t\right))\\ & {\displaystyle }& {\displaystyle }\cdot {\displaystyle \frac{\sin (l{)}^{\mathrm{2}}}{\mathrm{2}}},\end{array}$$ with $\stackrel{\mathrm{‾}}{C}\left(\text{global},,,\mathrm{1000},,\mathrm{hPa},,,t\right)$ indicating global-average, annual-average concentrations at the surface 1000 hPa level at time $t$. Ideally, a smoothed mean-preserving monthly time series of these annual-average global averages is used to prevent step changes from calendar month 12 to 1. Equivalently, $\stackrel{\mathrm{‾}}{C}\left(\text{global},,,\mathrm{1000},,\mathrm{hPa},,,t,-,\mathrm{5},,\text{yrs}\right)$ indicates the global-average, annual-average surface mole fraction 5 years earlier. The $\frac{\sin (l{)}^{\mathrm{2}}}{\mathrm{2}}$ factor depends on the latitude $l$ and results in the bell-shaped concentration curve with concentrations at the tropical 100 hPa level to be identical to the global average surface concentrations, while the polar mole fractions are effectively of a medium age (2.5 years in the case of linearly increasing concentration history). Having defined this 100 hPa concentration level, the tropospheric mole fractions at latitude $l$ and pressure level $p$ (with $p>$ 100 $\mathrm{hPa}$) can then be assumed to be a simple linear interpolation between the surface mole fraction level at latitude $l$ and the 100 hPa level, so that $$\begin{array}{cc}{\displaystyle }& {\displaystyle }C\left(l,,,p,,,t\right)=C\left(l,,,\mathrm{100},,\mathrm{hPa},,,t\right)+\left(C,\left(l,,,\mathrm{1000},,\mathrm{hPa},,,t\right)\right.\\ & {\displaystyle }& {\displaystyle }\left..-,C,\left(l,,,\mathrm{100},,\mathrm{hPa},,,t\right)\right)\cdot {\displaystyle \frac{(p-\mathrm{100}\mathrm{hPa})}{(\mathrm{1000}\mathrm{hPa}-\mathrm{100}\mathrm{hPa})}}.\end{array}$$ Above 100 $\mathrm{hPa}$, i.e. in the tropical upper troposphere and stratosphere, the mole fraction is a simple linear interpolation between the 100 hPa level and the top-of-the atmosphere 1 hPa level that is assumed to have a median age of air of 5 years, so that for $p<$ 100 $\mathrm{hPa}$ $$\begin{array}{cc}{\displaystyle }& {\displaystyle }C\left(l,,,p,,,t\right)=\stackrel{\mathrm{‾}}{C}\left(\text{global},,,\mathrm{1000},,\mathrm{hPa},,,t,-,\mathrm{5},,\text{yrs}\right)\mathrm{\dots }\\ {\displaystyle }& {\displaystyle }+\left(C,\left(l,,,\mathrm{100},,\mathrm{hPa},,,t\right)\right.\\ {\displaystyle }& {\displaystyle }\left..-,\stackrel{\mathrm{‾}}{C},\left(\text{global},,,\mathrm{1000},,\mathrm{hPa},,,t,-,\mathrm{5},,\text{yrs}\right)\right)\mathrm{\dots }\\ & {\displaystyle }& {\displaystyle }\cdot {\displaystyle \frac{(p-\mathrm{1}\mathrm{hPa})}{(\mathrm{100}\mathrm{hPa}-\mathrm{1}\mathrm{hPa})}},\end{array}$$ with $\stackrel{\mathrm{‾}}{C}\left(\text{global},,,\mathrm{1000},,\mathrm{hPa},,,t,-,\mathrm{5},,\text{yrs}\right)$ being again the global-mean surface concentration (1000 $\mathrm{hPa}$) 5 years ago and $C\left(l,,,\mathrm{100},,\mathrm{hPa},,,t\right)$ the latitudinally dependent concentration at the 100 hPa level.