Introduction

Space-based observations of carbon dioxide (CO${}_{\mathrm{2}}$) can contribute to the elimination of important knowledge gaps related to the regional sources and sinks of CO${}_{\mathrm{2}}$ . Near-surface sensitive measurements of column-averaged dry-air mole fractions of CO${}_{\mathrm{2}}$ (XCO${}_{\mathrm{2}}$) in the short-wave infrared spectral region (SWIR) are well suited for this application. These observations can complement measurements from existing surface-based greenhouse gas monitoring networks, especially in data-poor regions, by providing data with dense spatial coverage. However, satellite measurements need to be precise and accurate enough to reduce uncertainties in the characterisation of the sources and sinks. Studies showed that a precision of better than 1 $\mathrm{\%}$ for regional averages and monthly means and regional biases of less than a few tenth of a part per million (ppm) are required .

The SCanning Imaging Absorption spectroMeter for Atmospheric CHartographY (SCIAMACHY) on-board the European Space Agency's (ESA) Environmental Satellite (ENVISAT) , launched in 2002, was in the time period before mid-2009 the only satellite instrument measuring XCO${}_{\mathrm{2}}$ with high surface sensitivity. The long-term time series of surface-sensitive satellite-derived XCO${}_{\mathrm{2}}$ starts with SCIAMACHY. SCIAMACHY had observed the Earth's atmosphere until the loss of ENVISAT in April 2012.

The Thermal And Near infrared Sensor for carbon Observations Fourier Transform Spectrometer (TANSO-FTS) on-board the Greenhouse gases Observing SATellite (GOSAT) , launched in January 2009, and the Orbiting Carbon Observatory-2 (OCO-2) , launched in July 2014, are currently the only satellite instruments yielding XCO${}_{\mathrm{2}}$ with high near-surface sensitivity. Both satellite missions are specifically designed to observe XCO${}_{\mathrm{2}}$.

Several retrieval algorithms have been developed to evaluate the satellite observations for SCIAMACHY e.g. and for GOSAT e.g.. These algorithms differ e.g. in cloud and aerosol treatment, state vector elements and cloud filtering for more details see, e.g.. One of these algorithms is the Bremen Optimal Estimation DOAS (BESD) retrieval algorithm developed for the evaluation of SCIAMACHY measurements at the University of Bremen . As unaccounted scattering by aerosols and clouds is a major error source for satellite retrievals e.g., BESD aims to reduce this error source by explicitly considering atmospheric scattering . The BESD algorithm has been used to generate a SCIAMACHY XCO${}_{\mathrm{2}}$ data product ranging from 2002 to 2012. This data product has been used in several key European projects, e.g. ESA's Climate Change Initiative CCI, www.esa-ghg-cci.org and and the EU's Monitoring of Atmospheric Composition and Climate MACC, project.

Carbon cycle and climate-related research requires consistent and accurate long-term global CO${}_{\mathrm{2}}$ data sets. However, global data sets based on observations from different satellite instruments may suffer from inconsistencies originating from the use of different satellite algorithms. We address this potential issue by applying the same retrieval algorithm, the BESD algorithm, to different satellite instruments, SCIAMACHY and TANSO-FTS. Within the European MACC project, after the loss of ENVISAT, the BESD algorithm has been modified to also retrieve XCO${}_{\mathrm{2}}$ from TANSO-FTS measurements. The GOSAT/TANSO-FTS BESD XCO${}_{\mathrm{2}}$ product was delivered for the assimilation into the European Centre for Medium-range Weather Forecasts (ECMWF) Integrated Forecasting System . Here, we report first results of an assessment of the new GOSAT BESD XCO${}_{\mathrm{2}}$ data product. In addition, we discuss results of an investigation concerning the consistency of the SCIAMACHY BESD and GOSAT BESD XCO${}_{\mathrm{2}}$ data sets. This analysis includes a comparison of validation results obtained by using data from the Total Carbon Column Observing Network TCCON,, a direct comparison of daily satellite-based XCO${}_{\mathrm{2}}$ data and a global comparison with NOAA's CO${}_{\mathrm{2}}$ modelling and assimilation system CarbonTracker .

This paper is structured as follows: in Sects. 2 and 3, relevant aspects of the SCIAMACHY and TANSO-FTS instruments are discussed. Section 4 gives a short overview of the SCIAMACHY BESD retrieval algorithm whereas in Sect. 5 the recently developed GOSAT BESD XCO${}_{\mathrm{2}}$ retrieval algorithm is introduced. This includes the GOSAT Level 1C generation (fully calibrated total intensity, measurement error and a priori information), the GOSAT Level 2 XCO${}_{\mathrm{2}}$ generation as well as the cloud filtering and post-processing. In Sects. 6 and 7 the comparison of the satellite XCO${}_{\mathrm{2}}$ data with TCCON and CarbonTracker are described and discussed. Finally, conclusions are given in Sect. 8.

SCIAMACHY on ENVISAT

The satellite instrument SCIAMACHY was part of the atmospheric chemistry payload on-board ESA's ENVISAT. The ENVISAT satellite was launched in March 2002. On 8 April 2012, after 10 $\mathrm{years}$ of operation, ESA lost contact to ENVISAT and finally had declared the official end of the ENVISAT mission on 9 May 2012. ENVISAT flew on a sun-synchronous daytime (descending) orbit with an equator crossing time of 10:00 local time (LT).

The SCIAMACHY instrument was a passive remote sensing moderate-resolution imaging spectrometer and measured sunlight transmitted, reflected and scattered by the Earth's atmosphere or surface in the ultraviolet, visible and near-infrared wavelength regions in eight spectral channels (214–1750, 1940–2040, 2265–2380 $\mathrm{nm}$) with a spectral resolution between 0.2 and 1.4 $\mathrm{nm}$. The scientific objective of SCIAMACHY was to improve our knowledge of global atmospheric change and related issues of importance to the chemistry and physics of the atmosphere, i.e. the impact of pollution, exchange processes between atmospheric layers, atmospheric chemistry in polar and other regions and the influence of natural phenomena such as volcanic eruptions. Targets of SCIAMACHY were atmospheric gases (e.g. O${}_{\mathrm{3}}$, NO${}_{\mathrm{2}}$, CH${}_{\mathrm{4}}$ and CO${}_{\mathrm{2}}$) as well as clouds and aerosols, ocean colour and land parameters. SCIAMACHY measured in three different viewing geometries: nadir, limb and solar/lunar occultation.

For the work presented in this study the nadir mode observations in channel 4 (755–775 $\mathrm{nm}$) and channel 6 (1558–1594 $\mathrm{nm}$) has been used. The integration time of the instrument in the used spectral regions was typically 0.25 $\mathrm{s}$. This provided a typical spatial resolution of $\sim 60$ $\mathrm{km}$ across track and $\sim 30$ $\mathrm{km}$ along track. By scanning $\pm 32$${}^{\circ }$ across track, SCIAMACHY achieved a swath width of $\sim 1000$ $\mathrm{km}$.

TANSO-FTS on GOSAT

GOSAT was the first satellite mission dedicated to measuring atmospheric XCO${}_{\mathrm{2}}$ and XCH${}_{\mathrm{4}}$ . GOSAT is a joint project of the Japanese Aerospace Exploration Agency, the National Institute for Environmental Studies and the Ministry of the Environment. The objectives of GOSAT are to monitor the global distribution of greenhouse gases, to estimate CO${}_{\mathrm{2}}$ and CH${}_{\mathrm{4}}$ sources and sinks on subcontinental scale and to verify reductions of anthropogenic greenhouse gas emissions . On 23 January 2009, GOSAT was launched in a sun-synchronous daytime orbit with an equator crossing time of 13:00 (LT).

GOSAT carries two satellite instruments, the TANSO-FTS and the Cloud and Aerosol Imager (TANSO-CAI). The TANSO-FTS is a double pendulum interferometer. It measures two orthogonal polarisation directions of reflected or scattered sunlight in three bands (bands 1, 2, 3) in the SWIR between 4800 and 13 200 ${\mathrm{cm}}^{-\mathrm{1}}$ (758–2083 $\mathrm{nm}$). In addition to the SWIR bands, band 4 measures in the thermal infrared between 700 and 1800 ${\mathrm{cm}}^{-\mathrm{1}}$ (5.56–14.3 $\mathrm{\mu }$m). However, measurements obtained with band 4 are not considered in this paper. TANSO-FTS has a spectral resolution of $\mathrm{\Delta }{\mathit{\nu }}_{\mathrm{1}}\approx 0.36$ ${\mathrm{cm}}^{-\mathrm{1}}$ ($\mathrm{\Delta }{\mathit{\lambda }}_{\mathrm{1}}\approx 0.02$ $\mathrm{nm}$) in band 1 and $\mathrm{\Delta }{\mathit{\nu }}_{\mathrm{2},\mathrm{3}}\approx 0.26$ ${\mathrm{cm}}^{-\mathrm{1}}$ ($\mathrm{\Delta }{\mathit{\lambda }}_{\mathrm{2}}\approx 0.07$ and $\mathrm{\Delta }{\mathit{\lambda }}_{\mathrm{3}}\approx 0.1$ $\mathrm{nm}$) in bands 2 and 3. In order to improve the dynamic range of the instrument, the scientific measurements of TANSO-FTS are performed in two gain modes, medium (M) and high (H), used according to the measured level of intensity. For example, gain M is used over bright surfaces such as deserts. With an instantaneous field of view (IFOV) of 15.8 $\mathrm{mrad}$ ($\sim 10.5$ $\mathrm{km}$ diameter at nadir when projected to the ground), TANSO-FTS can measure $\pm$ 35${}^{\circ }$ across track and $\pm$ 20${}^{\circ }$ along track. The typically used scan time of one interferogram is 4 $\mathrm{s}$. Between 4 April 2009 and 31 July 2010, the five-point across track mode was used, which yields footprints separated by $\sim 158$ $\mathrm{km}$ across track and $\sim 152$ $\mathrm{km}$ along track at the equator e.g.. In order to improve the pointing stability during the scans, on 1 August 2010 the observation mode was changed to a three-point across track mode with footprints separated by $\sim 263$ $\mathrm{km}$ across track and $\sim 283$ $\mathrm{km}$ along track at the equator.

The TANSO-CAI instrument is a high spatial resolution imager detecting clouds and optically thick aerosol layers within the TANSO-FTS field of view. The TANSO-CAI data products are not used for the BESD algorithm.

SCIAMACHY BESD algorithm

The BESD retrieval algorithm has been developed at the University of Bremen to retrieve XCO${}_{\mathrm{2}}$ from SCIAMACHY nadir measurements. BESD aims to minimise scattering-related errors of the retrieved XCO${}_{\mathrm{2}}$. For this purpose, the algorithm explicitly accounts for scattering. The theoretical basis of BESD and a study of synthetic retrievals is presented in the publication of and validation results are presented in .

The algorithm is a core algorithm within ESA's CCI aiming at delivering high-quality satellite retrievals. Here we use the most recent product version (02.00.08) of SCIAMACHY BESD, which is part of the Climate Research Data Package (CRDP#2) of the CCI project. A detailed description of the current version of BESD can be found in the Algorithm Theoretical Basis Document (ATBD) available at http://www.esa-ghg-cci.org/. Here, only a short overview of the algorithm is given.

The BESD algorithm retrieves several independent parameters from the O${}_{\mathrm{2}}$-A band (755–775 $\mathrm{nm}$) in SCIAMACHY's channel 4 and from a CO${}_{\mathrm{2}}$ band (1558–1594 $\mathrm{nm}$) in channel 6. An optimal-estimation-based inversion technique is used to derive the most probable atmospheric state from a SCIAMACHY measurement using some a priori knowledge. The state vector consists of 26 elements. These elements include a wavelength shift and the full width half maximum (FWHM) of a Gaussian-shaped instrumental slit function, both fitted separately in the O${}_{\mathrm{2}}$ and CO${}_{\mathrm{2}}$ fit window. A Lambertian surface albedo with smooth spectral progression expressed as a second-order polynomial (with polynomial coefficients $P_{\mathrm{0}}$, $P_{\mathrm{1}}$ and $P_{\mathrm{2}}$) is fitted separately in both fit windows. A 10-layered CO${}_{\mathrm{2}}$ mixing ratio profile, which is separated in equally spaced pressure intervals, is fitted in the CO${}_{\mathrm{2}}$ fit window. The correlated a priori errors of the CO${}_{\mathrm{2}}$ profile layers provide a degree of freedom of the retrieved XCO${}_{\mathrm{2}}$ of $\sim 1.0$. Reanalysis profiles ERA-Interim, of pressure, temperature and humidity provided by the ECMWF are used for the forward model calculation needed to calculate simulated SCIAMACHY spectra. The surface pressure, a shift of the temperature profile and the H${}_{\mathrm{2}}$O column-averaged mole fraction are fitted in the O${}_{\mathrm{2}}$ and CO${}_{\mathrm{2}}$ window simultaneously.

Atmospheric scattering is considered by fitting three scattering-related parameters. A thin ice cloud layer consisting of fractal ice crystals with 50 µm effective radius and a thickness of 0.5 $\mathrm{km}$ is defined for the forward model calculations. Within the retrieval, the cloud water path (CWP) and the cloud top height (CTH) are retrieved. Aerosols are considered by using a standard LOWTRAN summer aerosol profile with moderate rural aerosol load. A Henyey–Greenstein phase function is used and the total optical thickness is about 0.136 at 750 $\mathrm{nm}$ and 0.038 at 1550 $\mathrm{nm}$. The aerosol retrieval is based on scaling the predefined aerosol profile (aerosol profile scaling (APS) factor). Not only the scattering parameters but also the parameters defining the meteorological situation are fitted simultaneously via a merged fit window approach. Simultaneous fitting in both fit windows transfers information, e.g. in case of scattering parameters, mostly obtained from the O${}_{\mathrm{2}}$-A band to the CO${}_{\mathrm{2}}$ band.

Coefficients for empirical noise for GOSAT high (H) and medium (M) gain observations over land.

The forward model is the radiative transfer model SCIATRAN . SCIATRAN calculates the needed radiance spectra and weighting functions, which are the derivatives of the measured radiation. The correlated-k approach of is used to accelerate the radiative transfer calculations. Line parameters from NASA's absorption cross section database ABSCO v4.0 is used for O${}_{\mathrm{2}}$. The HITRAN 2008 database are used for the other gases. The calculated spectra are convolved with a Gaussian slit function.

Although BESD has been designed to minimise scattering-related retrieval errors, clouds are still an important potential error source and strict cloud filtering is necessary. BESD filters clouds by using cloud information based on measurements of the Medium Resolution Imaging Spectrometer (MERIS).

The post-processing of the retrieved data includes strict quality filtering and an empirical bias correction. This is needed due to the demanding accuracy requirements on the satellite retrievals. The implemented bias correction for SCIAMACHY BESD is described in the BESD ATBD .

GOSAT BESD algorithm

The GOSAT BESD algorithm is based on the SCIAMACHY BESD algorithm which has been modified to also retrieve XCO${}_{\mathrm{2}}$ from GOSAT. Here, an overview of the modifications of BESD are given.

Level 1C data generation

GOSAT BESD uses GOSAT Level 1B data (L1B) version 161160. These data have been obtained from the GOSAT User Interface Gateway (http://data.gosat.nies.go.jp/GosatUserInterfaceGateway/guig/GuigPage/open.do) and from ESA's GOSAT Third Party Mission data archive. The (uncalibrated) L1B data have been converted into calibrated Level 1C (L1C) data, by using e.g. the radiance correction scheme described by . The L1C data consist of the fully calibrated total intensity, an estimation of the measurement error and a priori information. The total intensity is computed by using the polarisation synthesis method described by using the Mueller matrices described by . The measurement noise (${\mathit{\epsilon }}_{\text{meas}}$) is estimated by the standard deviation of the first 500 and the last 500 off-band spectral points of GOSAT bands 1, 2 and 3. These spectral points lie outside the band pass filter and can therefore provide a good estimate of ${\mathit{\epsilon }}_{\text{meas}}$. However, using only the estimate of the measurement noise for the retrieval neglects the contribution of the forward model error. Therefore, empirical noise (${\mathit{\epsilon }}_{\text{empirical}}$) has been implemented and used as described by and . In order to account for the forward model error, we make the same assumptions as done by . We assume that our forward model error increases as the signal-to-noise ratio (SNR) increases. Using the same formula as given by , $${\mathit{\epsilon }}_{\text{empirical}}={\mathit{\epsilon }}_{\text{meas}}\cdot \sqrt{a_{\mathrm{0}}+a_{\mathrm{1}}\text{SNR}+a_{\mathrm{2}}{\text{SNR}}^{\mathrm{2}}},$$ and evaluating the relationship between SNR and the mean squared values of the residual spectra delivers the coefficients $a_{\mathrm{0}}$, $a_{\mathrm{1}}$ and $a_{\mathrm{2}}$ in each spectral window. The coefficients are listed in Table .

The a priori information includes profiles of temperature, pressure and humidity obtained from ECMWF data and height information from a digital elevation model (DEM). The used DEM (obtained from http://www.viewfinderpanoramas.org) is mostly based on data collected in 2000 by the Shuttle Radar Topography Mission and has a spatial resolution of 15 arc s. A priori estimates for the zeroth-order polynomial coefficient of the albedo ($P_{\mathrm{0}}$) are obtained by computing the 95 $\mathrm{\%}$ percentile of the reflectance (sun-normalised GOSAT intensity divided by the cosine of the solar zenith angle).

GOSAT XCO${}_{\mathrm{2}}$ (Level 2) generation

The GOSAT XCO${}_{\mathrm{2}}$ (Level 2) data have been generated by using a modified version of the SCIAMACHY BESD retrieval algorithm. The main modifications are the following: we have used three bands instead of two bands (as used for SCIAMACHY) for the retrieval of GOSAT XCO${}_{\mathrm{2}}$. Band 1 includes the O${}_{\mathrm{2}}$-A band (12 920–13 195 ${\mathrm{cm}}^{-\mathrm{1}}$ or 758–774 $\mathrm{nm}$), band 2 contains a weak CO${}_{\mathrm{2}}$ absorption band (6170–6278 ${\mathrm{cm}}^{-\mathrm{1}}$ or 1593–1621 $\mathrm{nm}$) and band 3 includes a strong CO${}_{\mathrm{2}}$ absorption band (4804–4896 ${\mathrm{cm}}^{-\mathrm{1}}$ or 2042–2082 $\mathrm{nm}$).

The state vector of GOSAT BESD consists of 38 elements instead of 26 for SCIAMACHY BESD. The state vector elements, their a priori values and uncertainties are listed in Table . A second-order albedo polynomial is additionally fitted in the third fit window. Besides a spectral shift of the nadir radiance, a shift of the solar spectrum is fitted. Instead of the FWHM of a SCIAMACHY Gaussian slit function, parameters defining the instrumental line shape function (ILS) of TANSO-FTS are fitted. These parameters are the maximum optical path difference (MOPD) and the IFOV. The ILS is calculated similar as done by e.g. from $$\text{ILS}\left(\mathit{\nu }\right)\propto \mathrm{\Pi }\left(\frac{\mathrm{8}\mathit{\nu }}{{\mathit{\nu }}_{\mathrm{0}}\text{IFOV}}\right)\otimes \text{sinc}(\mathrm{2}\mathit{\nu }\cdot \text{MOPD}).$$

Here, $\mathit{\nu }$ is the wavenumber (centred around 0), $\mathrm{\Pi }$ is a boxcar function, the $\otimes$ is the convolution operator and ${\mathit{\nu }}_{\mathrm{0}}$ is the centre wavenumber.

A temperature shift, the column-averaged mole fraction of water vapour and the surface pressure are fitted as for SCIAMACHY BESD and also the CO${}_{\mathrm{2}}$ profile consists of 10 layers. The CO${}_{\mathrm{2}}$ a priori profile is obtained by using the Simple Empirical CO${}_{\mathrm{2}}$ Model (SECM) described by . The a priori uncertainty of the CO${}_{\mathrm{2}}$ profile has been scaled similar to so that the a priori XCO${}_{\mathrm{2}}$ uncertainty is about 42 $\mathrm{ppm}$. This large value enables that the XCO${}_{\mathrm{2}}$ retrieval is virtually unconstrained.

Contributions from plant fluorescence and the impact of a non-linearity response of the incident radiation to the intensity in the mostly affected band 1 can be reduced by fitting a wavenumber independent offset (also called zero-level offset) . This has also been implemented in GOSAT BESD for the O${}_{\mathrm{2}}$-A band.

The fit parameters defining atmospheric scattering are the same as for SCIAMACHY BESD, namely CWP, CTH and APS. The defined thin cloud layer consists of fractal ice particles with an effective radius of 100 $\mathrm{\mu }$m.

The much higher spectral resolution of GOSAT is the reason why the radiative transfer model SCIATRAN cannot run in the implemented computational efficient correlated-k mode used for SCIAMACHY BESD. However, in order to accelerate the radiative transfer calculations for GOSAT BESD retrievals, tabulated cross sections based on the absorption cross sections database ABSCO v4.0 described by have been used and the linear-k scheme of has been implemented. A high spectral resolution solar irradiance spectrum based on the “OCO TOON spectrum” is used to calculate the total intensity instead of the sun-normalised intensity as used by SCIAMACHY BESD. The simulated intensity is convolved with the GOSAT ILS (Eq. ).

In Fig.  a typical example of observed and fitted GOSAT spectra in all three fitting windows is presented. The observed and fitted spectra show reasonable agreement. The reduced ${\mathit{\chi }}^{\mathrm{2}}$ computed as described by is in all three fitting windows $\sim \mathrm{1}$, which means that the difference between observed and fitted spectra agrees with the estimated noise.

State vector elements of the GOSAT BESD retrieval algorithm.

Observed (black) and fitted (red) intensity (radiance) and its residuum (blue) over a typical scene in Germany, near Berlin (52.42${}^{\circ }$ N, 13.40${}^{\circ }$ E) on 3 June 2010. Top panel: observed and fitted radiance and the residuum for GOSAT band 1 (12 920–13 195 ${\mathrm{cm}}^{-\mathrm{1}}$). Middle panel: as top panel but for band 2 (6170–6278 ${\mathrm{cm}}^{-\mathrm{1}}$). Bottom panel: as top panel but for band 3 (4804–4896 ${\mathrm{cm}}^{-\mathrm{1}}$).

[Figure omitted. See PDF]

Parameters and thresholds as used for the quality filtering. A scene is considered to be of “good” quality if e.g. the albedo difference between the fitted and a priori albedo in band 2 (albedo difference, weak CO${}_{\mathrm{2}}$) is larger than the lower threshold of $-0.02$ and smaller than the upper threshold of 0.02.

Cloud filtering and post-processing

Even thin clouds are a main error source for satellite XCO${}_{\mathrm{2}}$ retrievals. Therefore, GOSAT BESD includes a cloud detection method similar to and . The intensity from a saturated water vapour absorption band at 1.9 $\mathrm{\mu }$m is used and clouds are detected by using a threshold technique. The basic idea behind this method is that in the clear-sky case, the amount of radiation measured by GOSAT is very small as essentially all photons are absorbed by tropospheric water vapour. When a cirrus cloud is located above most of the atmospheric water vapour, a significant amount of radiation can be backscattered and measured. A cloud is detected when the measured intensity is larger than a threshold. We use 4 times the measurement noise as threshold, which has been empirically determined. This filter is sensitive to high ice clouds but not that sensitive to low water clouds. Therefore, we also filter for bright scenes by using the a priori $P_{\mathrm{0}}$ (zeroth-order polynomial coefficient of the albedo) obtained from GOSAT reflectances (see Sect. ). If the a priori $P_{\mathrm{0}}$ is larger than a threshold, the measurement is considered to be cloud contaminated. The threshold for this filter is 0.7 and has also been empirically determined. In addition to these cloud filters, the quality filtering removes still remaining potentially cloud-contaminated scenes.

Used TCCON sites, their location, altitude (above sea level) and used observation period.

The high demands on the satellite retrievals require strict quality filtering not only for clouds. In order to minimise biases and to reduce the scatter of the data, GOSAT BESD uses filter thresholds for selected parameters. The used parameters and their filter thresholds have been selected by evaluating GOSAT XCO${}_{\mathrm{2}}$ biases and are shown in Table . These parameters include e.g. parameters defining the quality of the spectral fit (${\mathit{\chi }}^{\mathrm{2}}$, RMSE), scattering parameters (CWP, APS) and parameters defining the meteorological state (difference between fitted and a priori surface pressure).

Systematic errors have been additionally reduced by using a global bias correction scheme similar as done by. We use TCCON data from all stations listed in Table  for the evaluation of the coefficients of the bias correction. As TCCON is used here as reference, the differences to TCCON can be interpreted as the systematic retrieval errors. Figure  shows the dependence of the non-bias-corrected GOSAT BESD–TCCON XCO${}_{\mathrm{2}}$ differences on the four most relevant retrieval parameters. The four parameters are the viewing zenith angle (VZA), the air-mass factor (AMF), $P_{\mathrm{0}}$ of band 1 (ALB) and the difference to the a priori $P_{\mathrm{0}}$ of band 2 (ALBDIFF). These parameters show a linear or quadratic dependence on these differences.

To reduce the systematic errors in the GOSAT BESD XCO${}_{\mathrm{2}}$ data set, the following equation has been used: $$\begin{array}{cc}& {\text{XCO}}_{\mathrm{2}}^{\text{cor}}={\text{XCO}}_{\mathrm{2}}+b_{\mathrm{0}}+b_{\mathrm{1}}\cdot \text{ALBDIFF}+b_{\mathrm{2}}\cdot \text{VZA}\\ & & +b_{\mathrm{3}}\cdot {\text{VZA}}^{\mathrm{2}}+b_{\mathrm{4}}\cdot \text{AMF}+b_{\mathrm{5}}\cdot {\text{AMF}}^{\mathrm{2}}+b_{\mathrm{6}}\cdot \text{ALB}.\end{array}$$

Two-dimensional histograms of non-bias-corrected (left) and standard (bias-corrected, right) GOSAT BESD–TCCON XCO${}_{\mathrm{2}}$ differences versus the following four retrieval parameters: (a) viewing zenith angle (VZA), (b) difference of retrieved to a priori albedo $P_{\mathrm{0}}$ of band 2 (ALBDIFF), (c) retrieved $P_{\mathrm{0}}$ of band 1 (ALB) and (d) air-mass factor (AMF).

[Figure omitted. See PDF]

The coefficients found by multivariate linear regression are $b_{\mathrm{0}}=0.4490$ $\mathrm{ppm}$, $b_{\mathrm{1}}=236.8$ $\mathrm{ppm}$, $b_{\mathrm{2}}=-0.1096\mathrm{ppm}{(}^{\circ }{)}^{-\mathrm{1}}$, $b_{\mathrm{3}}=6.750\times {10}^{-\mathrm{3}}\mathrm{ppm}{(}^{\circ }{)}^{-\mathrm{2}}$, $b_{\mathrm{4}}=5.961$ $\mathrm{ppm}$, $b_{\mathrm{5}}=-1.912$ $\mathrm{ppm}$ and $b_{\mathrm{6}}=-8.212$ $\mathrm{ppm}$. After application of the bias correction the dependence on the four parameters is significantly reduced (see right panels of Fig. ). Our standard product is the bias corrected GOSAT BESD XCO${}_{\mathrm{2}}$ data set and the version used here is 01.00.02.

Intercomparisons between TCCON, SCIAMACHY and GOSAT XCO${}_{\mathrm{2}}$

The quality of the satellite XCO${}_{\mathrm{2}}$ data products and their consistency has been assessed using ground-based TCCON XCO${}_{\mathrm{2}}$ observations. In this section a short overview of TCCON is given, the assessment method is described and the comparison results are discussed.

TCCON stations used for validation.

[Figure omitted. See PDF]

TCCON observations

The Total Carbon Column Observing Network (TCCON) consists of several ground-based measurement stations of Fourier transform spectrometers (FTS). The FTS instruments measure the absorption of direct sunlight by gases. This has the advantage of being less influenced by atmospheric scattering compared to satellite measurements. From the measured spectra TCCON retrieves XCO${}_{\mathrm{2}}$, i.e. the same quantity as retrieved from satellite instruments. TCCON achieves a precision and accuracy of 0.4 $\mathrm{ppm}$ (1$\mathit{\sigma }$) . In this study, we use TCCON version GGG2012 considering all recommended corrections from http://tccon-wiki.caltech.edu. For a comprehensive validation, data from as many TCCON stations as possible need to be used. Therefore, we have used 16 TCCON stations for the validation that have an overlapping observation period with SCIAMACHY and GOSAT. The used stations are shown in Fig.  and listed in Table .

Method

The first part of this study is the validation of the GOSAT BESD (available for January 2010–December 2013) and SCIAMACHY BESD XCO${}_{\mathrm{2}}$ (available for August 2003–March 2012) data sets using TCCON XCO${}_{\mathrm{2}}$. In order to evaluate the consistency of the satellite data products, we compare the data products with TCCON data for the same time period and perform a direct comparison of the satellite data, i.e. validation results from the overlapping observation years 2010–2011 of SCIAMACHY and GOSAT are presented and compared, and a direct comparison of daily means of the data sets and an additional comparison to daily TCCON data are performed.

The comparison between different CO${}_{\mathrm{2}}$ data sets from measurements of different instruments is not trivial because of the different averaging kernels and a priori information as used by the different retrieval algorithms. To ensure that the differences between the measurements are not dominated by differences of the averaging kernels and a priori information, recommends adjusting the measurements by using a common a priori profile and accounting for the averaging kernels. As SCIAMACHY BESD and GOSAT BESD already use the same a priori profiles obtained from the SECM model , only the TCCON measurements need to be adjusted. However, for TCCON, the CO${}_{\mathrm{2}}$ averaging kernels are typically very close to unity and the used a priori profiles only marginally differ from the SECM profiles as SECM is based on CarbonTracker CO${}_{\mathrm{2}}$ , which is similar to the TCCON a priori. found that adjusting the FTS measurements results in only small modifications of about 0.1 $\mathrm{ppm}$. This is small compared to the precision of SCIAMACHY and GOSAT retrievals. Therefore, the FTS measurements are not adjusted.

All TCCON measurements 2 hours before or after the satellite measurement and all satellite data within a ${10}^{\circ }\times {10}^{\circ }$ box surrounding the TCCON stations are used. We have also tested other collocation criteria such as a ${\mathrm{5}}^{\circ }$ and a 350 km radius around the TCCON sites. The results of the intercomparison of the data sets using these collocation criteria have been similar to the ${10}^{\circ }\times {10}^{\circ }$ box (see Table S1, S2 and S3 in the Supplement). For the results presented here we have decided to use the ${10}^{\circ }\times {10}^{\circ }$ box collocation criterion as it provided the largest amount of collocated data points.

Four values have been obtained from the comparisons of the data sets at the TCCON sites: (i) the number of collocated data points, (ii) the mean difference between the data sets (can be interpreted as a regional bias), (iii) the standard deviation of the difference (is an estimate of the precision when compared with TCCON) and (iv) the linear correlation coefficient between the data sets.

SCIAMACHY BESD (black), GOSAT BESD (green) and TCCON (red) XCO${}_{\mathrm{2}}$ at the Lamont (top) and Darwin (bottom) TCCON sites ($\pm$ 2 h, ${10}^{\circ }\times {10}^{\circ }$).

[Figure omitted. See PDF]

Scatter plots of individual satellite vs. TCCON XCO${}_{\mathrm{2}}$ measurements at the chosen TCCON sites. (a) GOSAT BESD XCO${}_{\mathrm{2}}$ (January 2012–December 2013) vs. TCCON XCO${}_{\mathrm{2}}$. (b) SCIAMACHY BESD XCO${}_{\mathrm{2}}$ (August 2002–March 2012) vs. TCCON XCO${}_{\mathrm{2}}$. $n$ is the number of collocations, $\mathrm{\Delta }$ is the mean difference between the satellite-based data and TCCON, $\mathit{\sigma }$ is the standard deviation of the difference and $r$ is the correlation coefficient.

[Figure omitted. See PDF]

Results

Entire time series

Figure  shows time series of BESD and TCCON XCO${}_{\mathrm{2}}$ at the Lamont and Darwin TCCON sites. The qualitative comparison between SCIAMACHY BESD and GOSAT BESD XCO${}_{\mathrm{2}}$ indicates good consistency between the data sets as the satellite data are in reasonable to good agreement among themselves and with TCCON. This has been further investigated by more quantitative comparisons.

In Fig. a all collocated GOSAT and TCCON XCO${}_{\mathrm{2}}$ data between 2010 and 2013 and Fig. b all collocated SCIAMACHY and TCCON XCO${}_{\mathrm{2}}$ data between 2002 and 2012 are presented. The number of collocations are higher for SCIAMACHY/TCCON compared to GOSAT/TCCON as the time series of BESD SCIAMACHY is longer and more measurements per day were performed by SCIAMACHY. The mean difference to TCCON is $-0.38$ $\mathrm{ppm}$ for GOSAT and $-0.11$ $\mathrm{ppm}$ for SCIAMACHY. The standard deviation of the difference to TCCON is similar ($\sim \mathrm{2}$ $\mathrm{ppm}$) for GOSAT and SCIAMACHY. The correlation coefficient between GOSAT/TCCON is $0.84$ and between SCIAMACHY/TCCON $0.90$.

Results of the comparison between GOSAT BESD and TCCON XCO${}_{\mathrm{2}}$ for individual (single measurement) satellite data. Shown are the results for non-bias corrected and standard (bias-corrected) GOSAT BESD of the full time series (January 2010–December 2013, see Fig. S1 for the time series of the standard GOSAT BESD) of the data set and for a 2010–2011 sub-set of the standard GOSAT BESD data product. $\mathrm{\Delta }$ is the mean difference between GOSAT BESD and TCCON XCO${}_{\mathrm{2}}$, $\mathit{\sigma }$ is the standard deviation of the difference, $r$ is the correlation coefficient between the time series and $n$ the number of collocations. Stations marked with ${}^{*}$ have less than 30 collocations in one of the comparisons of GOSAT BESD or SCIAMACHY BESD XCO${}_{\mathrm{2}}$ with TCCON XCO${}_{\mathrm{2}}$. Therefore, these comparisons should be interpreted with care. The mean offset (mean of the mean differences), the estimated single measurement precision (mean of the standard deviation of the difference), the mean correlation coefficient and the station-to-station bias (standard deviation of the mean differences) are calculated without these stations.

As Table  but for SCIAMACHY BESD XCO${}_{\mathrm{2}}$ full data set (August 2003–March 2012, see Fig. S2 for the time series) and for a 2010–2011 sub-set.

In more detail, the comparison results between GOSAT BESD XCO${}_{\mathrm{2}}$ and TCCON are shown in Table  (full time series, standard). The standard deviation of the difference is between $1.36$ $\mathrm{ppm}$ (Darwin) and $2.65$ $\mathrm{ppm}$ (Karlsruhe); the station bias to TCCON is in the range $-0.92$ $\mathrm{ppm}$ (JPL) to $2.07$ $\mathrm{ppm}$ (Tsukuba) and the correlation coefficient between GOSAT BESD and TCCON is between $0.57$ (JPL) and $0.89$ (Park Falls). The comparison results at the Izaña TCCON site should be interpreted with care as some of the collocated GOSAT data could be measured over scenes with a large altitude difference to the Izaña site (altitude of 2.37 km). Also shown are the results for the non-bias-corrected GOSAT BESD XCO${}_{\mathrm{2}}$. Due to the found systematic retrieval errors, the station biases are between $-3.56$ $\mathrm{ppm}$ (Sodankylä) and $1.37$ $\mathrm{ppm}$ (Tsukuba), the standard deviation of the difference is between $3.35$ $\mathrm{ppm}$ (Karlsruhe) and $1.94$ $\mathrm{ppm}$ (Darwin) and the correlation coefficient is between 0.44 (JPL) and 0.82 (Park Falls, Tsukuba).

Table  shows the detailed results of the comparison between the SCIAMACHY BESD XCO${}_{\mathrm{2}}$ data and the TCCON measurements for the full SCIAMACHY BESD data set (ranging from mid-2002 to mid-2012). The standard deviation of the difference is between $1.72$ $\mathrm{ppm}$ (Darwin) and $3.03$ $\mathrm{ppm}$ (Lauder). The station biases are between $-1.95$ $\mathrm{ppm}$ (Four Corners) and $2.36$ $\mathrm{ppm}$ (Tsukuba). The correlation coefficient is typically high and is between $0.38$ (Four Corners) and $0.93$ (Park Falls). The low correlation coefficient at Four Corners can be explained by the dependence of the correlation coefficient on the length of the time series. At Four Corners SCIAMACHY and TCCON have collocations only in 1 year compared to 8 years at Park Falls. An additional explanation for the low correlation at Four Corners can be the collocation criterion. There are two large power plants in the vicinity of the Four Corners TCCON station introducing large variability which can be smeared out in the satellite data by using the ${10}^{\circ }\times {10}^{\circ }$ collocation criterion. This may also be a reason for the large $-1.95$ $\mathrm{ppm}$ mean difference to TCCON at Four Corners.

In order to summarise the results, we calculate the mean standard deviation of the difference (can be interpreted as an upper limit for the single measurement precision) and the standard deviation of the station biases, which we interpret as the station-to-station bias deviation (short: station-to-station bias). For the sake of completeness, we also calculate the mean of the station biases (mean offset) and the mean correlation coefficient. However, the mean offset is less relevant as it can be easily adjusted. In order to determine robust values, we have excluded TCCON stations with less than 30 measurements in one of the comparisons, i.e. Tsukuba, JPL, Saga, Izaña and Lauder are not considered.

The full data set analysis (GOSAT: January 2010–December 2013; SCIAMACHY: August 2002–March 2012) shows for the standard GOSAT BESD data set a mean offset of $-0.30$ $\mathrm{ppm}$, a single measurement precision of $2.09$ $\mathrm{ppm}$, a mean correlation coefficient of $0.79$ and a station-to-station bias of $0.43$ $\mathrm{ppm}$. Compared to the non-bias-corrected GOSAT BESD data set (mean offset of $-1.85$ $\mathrm{ppm}$, single measurement precision of $2.78$ $\mathrm{ppm}$, mean correlation coefficient of $0.69$ and station-to-station bias of $0.93$ $\mathrm{ppm}$) the quality of the standard (bias-corrected) GOSAT BESD data set is enhanced as the implemented bias correction scheme reduces systematic retrieval errors. The results for the standard GOSAT BESD data set are similar to results of other XCO${}_{\mathrm{2}}$ products from retrieval algorithms applied to GOSAT observations; e.g. found for the full-physics algorithm of the University of Leicester a mean offset of $-0.76$ $\mathrm{ppm}$, a single measurement precision of $2.37$ $\mathrm{ppm}$, a mean correlation coefficient of $0.79$ and a station-to-station bias of $0.53$ $\mathrm{ppm}$ and for SRON's RemoTeC algorithm a mean offset of $-0.57$ $\mathrm{ppm}$, a mean single measurement precision of $2.50$ $\mathrm{ppm}$, a mean correlation coefficient of $0.81$ and a station-to-station bias of $0.75$ $\mathrm{ppm}$. Note that both data sets are bias corrected as well. They used GOSAT data between April 2009 and April 2011, a collocation time of $\pm$ 2 h and all measurements within a $500$ $\mathrm{km}$ radius around a TCCON site.

The SCIAMACHY BESD data have a mean offset of $-0.05$ $\mathrm{ppm}$, a single measurement precision of $2.20$ $\mathrm{ppm}$, a mean correlation coefficient of $0.78$ and a station-to-station bias of $0.89$ $\mathrm{ppm}$. The mean offset, the mean single measurement precision and the mean correlation coefficient are similar to the findings of . They found a mean offset of $0.02$ $\mathrm{ppm}$, a slightly larger single measurement precision of $2.53$ $\mathrm{ppm}$ and a mean correlation of $0.81$. The station-to-station bias found by is slightly better with $0.63$ $\mathrm{ppm}$. A reason for this difference is the large mean difference from TCCON at Four Corners ($-1.95$ $\mathrm{ppm}$). Without Four Corners the mean offset ($0.14$ $\mathrm{ppm}$), the mean correlation coefficient ($0.82$) and the mean single measurement precision ($2.18$ $\mathrm{ppm}$) remain nearly the same, but the station-to-station bias ($0.67$ $\mathrm{ppm}$) becomes better and similar to the findings of .

As Fig.  but for daily averages of GOSAT, SCIAMACHY and TCCON XCO${}_{\mathrm{2}}$ (2010–2011). (a) GOSAT BESD XCO${}_{\mathrm{2}}$ vs. TCCON XCO${}_{\mathrm{2}}$. (b) SCIAMACHY BESD XCO${}_{\mathrm{2}}$ vs. TCCON XCO${}_{\mathrm{2}}$. (c) GOSAT BESD XCO${}_{\mathrm{2}}$ vs. SCIAMACHY BESD XCO${}_{\mathrm{2}}$.

[Figure omitted. See PDF]

Results of the comparison of daily averages of (standard) GOSAT, SCIAMACHY and TCCON XCO${}_{\mathrm{2}}$ for 2010–2011 (see Fig. S3 for time series). The values are computed as for Table . Here, the comparisons at the TCCON sites marked with a ${}^{*}$, with less than 10 $\mathrm{days}$ of data for all three comparisons, should be interpreted with care. The mean offset (mean of the mean differences), the estimated single measurement precision (mean of the standard deviation of the difference), the mean correlation coefficient and the station-to-station bias (standard deviation of the mean differences) are calculated without these stations.

Overlapping time series (2010–2011)

For the comparison of the validation results of GOSAT BESD and SCIAMACHY BESD, we have used the time period 2010 to 2011 where both data sets overlap. Both data sets have a negative station bias e.g. at Bremen ($-1.01$ $\mathrm{ppm}$ for GOSAT and $-1.07$ $\mathrm{ppm}$ for SCIAMACHY), Darwin ($-1.00$ $\mathrm{ppm}$ for GOSAT and $-0.87$ $\mathrm{ppm}$ for SCIAMACHY) and Four Corners ($-0.77$ and $-1.61$ $\mathrm{ppm}$) and a positive station bias e.g. at Garmisch ($0.52$ and $0.98$ $\mathrm{ppm}$). These similarities result in a high correlation coefficient of $0.83$ between the station biases of SCIAMACHY BESD and GOSAT BESD (considering all stations with a sufficient number of collocations). The standard deviation of the difference at Karlsruhe is in both data sets similarly high ($2.67$ and $2.55$ $\mathrm{ppm}$) and similarly low at Darwin ($1.24$ $\mathrm{ppm}$ for GOSAT and $1.67$ $\mathrm{ppm}$ for SCIAMACHY).

Overall, the analysis results for the time period 2010–2011 are similar to the results obtained for the full data set analysis. In both comparisons, the mean offset is negative ($-0.42$ $\mathrm{ppm}$ for GOSAT and $-0.08$ $\mathrm{ppm}$ for SCIAMACHY), the single measurement precision is similar ($2.04$ $\mathrm{ppm}$ for GOSAT and $2.12$ $\mathrm{ppm}$ for SCIAMACHY) and the mean correlation coefficient is high ($0.71$ for GOSAT and $0.63$ for SCIAMACHY). The station-to-station bias is slightly better for GOSAT with $0.48$ $\mathrm{ppm}$ compared to $0.88$ $\mathrm{ppm}$ for SCIAMACHY.

Results of the comparison of daily means of GOSAT BESD, SCIAMACHY BESD and TCCON XCO${}_{\mathrm{2}}$ are shown in Fig. . The daily means are computed using only days with more than three measurements within the ${10}^{\circ }\times {10}^{\circ }$ around the TCCON sites. Figure  shows (similar to Fig. ) (a) all collocated daily means of GOSAT and TCCON XCO${}_{\mathrm{2}}$ data between 2010 and 2011, (b) all collocated daily means of SCIAMACHY and TCCON XCO${}_{\mathrm{2}}$ data between 2010 and 2011 and additionally (c) all collocated daily means of GOSAT and SCIAMACHY XCO${}_{\mathrm{2}}$. The mean daily difference (offset) from TCCON is $-0.34$ $\mathrm{ppm}$ for GOSAT and $0.10$ $\mathrm{ppm}$ for SCIAMACHY. The offset between the GOSAT and SCIAMACHY data is small with $-0.60$ $\mathrm{ppm}$. The standard deviation of the daily difference to TCCON is for GOSAT smaller with $1.37$ $\mathrm{ppm}$ compared to SCIAMACHY with $1.79$ $\mathrm{ppm}$. The standard deviation of the daily difference between GOSAT and SCIAMACHY is $1.56$ $\mathrm{ppm}$, which is similar to the comparison to TCCON. The correlation coefficient between GOSAT/TCCON is higher ($0.86$) compared to SCIAMACHY/TCCON ($0.75$) and similar to GOSAT/SCIAMACHY ($0.82$).

Global maps of XCO${}_{\mathrm{2}}$ (left), XCO${}_{\mathrm{2}}$ differences ($\mathrm{\Delta }$XCO${}_{\mathrm{2}}$, middle) and latitudinal averages of the differences (right) of GOSAT BESD, SCIAMACHY BESD and CarbonTracker gridded on ${\mathrm{5}}^{\circ }\times {\mathrm{5}}^{\circ }$ for April–May 2011. The values shown near the bottom of the difference maps are $\mathrm{\Delta }$, the mean difference between the data products, $\mathit{\sigma }$, the standard deviation of the difference and $r$, the correlation coefficient. The black diamonds in the right panels are the XCO${}_{\mathrm{2}}$ differences in the individual grid boxes. The red triangles represent the latitudinal averages and the error bars the latitudinal standard deviation. ${\mathit{\sigma }}_{\mathrm{l}}$ is the standard deviation over all latitudinal averages.

[Figure omitted. See PDF]

As Fig.  but for August–September 2011.

[Figure omitted. See PDF]

A more detailed comparison is shown in Table . Only stations with more than 10 days of data are used to compute the mean values shown in Table . The comparison with TCCON shows for GOSAT and SCIAMACHY BESD a small negative offset of $-0.17$ $\mathrm{ppm}$ (GOSAT) and $-0.05$ $\mathrm{ppm}$ (SCIAMACHY), a daily precision of $1.28$ $\mathrm{ppm}$ (GOSAT) and $1.60$ $\mathrm{ppm}$ (SCIAMACHY), a mean correlation coefficient of $0.85$ (GOSAT) and $0.73$ (SCIAMACHY) and a station-to-station bias of $0.54$ $\mathrm{ppm}$ (GOSAT) and $0.85$ $\mathrm{ppm}$ (SCIAMACHY). The correlation of the daily station biases at the TCCON sites for SCIAMACHY and GOSAT BESD is high ($r=0.88$). The direct comparison between the GOSAT BESD and SCIAMACHY BESD XCO${}_{\mathrm{2}}$ data set shows that the satellite data have a $-0.77$ $\mathrm{ppm}$ offset against one another. However, this can be simply adjusted by accounting for this offset. The mean scatter of the differences of $1.51$ $\mathrm{ppm}$ and the mean correlation coefficient of $0.80$ are similar to the precision and mean correlation coefficient obtained by the comparison with TCCON. The standard deviation of the mean differences between GOSAT and SCIAMACHY of $0.59$ $\mathrm{ppm}$ is smaller/similar than the station-to-station bias of daily GOSAT BESD and SCIAMACHY BESD data.

The differences between the satellite data are likely due to non-perfect collocations (observed air masses are not identical) and potentially due to a non-perfect BESD retrieval algorithm. However, the similar scatter of the difference between the data sets compared to the difference to TCCON, the high correlation coefficient of the station biases and the smaller/similar standard deviation of the mean differences of the data sets compared to the station-to-station bias indicate a high degree of consistency between the SCIAMACHY and GOSAT XCO${}_{\mathrm{2}}$ data sets.

Comparisons with CarbonTracker XCO${}_{\mathrm{2}}$

In addition to the comparisons with TCCON, we have also compared the BESD data sets with the model results of CarbonTracker. For this purpose, we have used data of 4 months in 2011: we selected April–May when the atmospheric CO${}_{\mathrm{2}}$ concentration in the Northern Hemisphere peaks and August–September where it reaches its minimum.

CarbonTracker is NOAA's modelling and assimilation system and has been developed to estimate global CO${}_{\mathrm{2}}$ concentrations and CO${}_{\mathrm{2}}$ surface fluxes . We use CarbonTracker version CT2013B downloaded from http://carbontracker.noaa.gov. Global monthly maps of GOSAT BESD, SCIAMACHY BESD and CarbonTracker XCO${}_{\mathrm{2}}$ have been generated in a grid of ${\mathrm{5}}^{\circ }\times {\mathrm{5}}^{\circ }$. All grid boxes with less than 15 measurements have been excluded to achieve robust results. A global mean offset has been added to GOSAT BESD ($\mathrm{1}$ $\mathrm{ppm}$) and SCIAMACHY BESD ($0.4$ $\mathrm{ppm}$) to better compare the differences to CarbonTracker. From the intercomparison of the global maps the mean difference, the standard deviation of the difference and the correlation coefficient between the data sets have been computed.

Figure  shows the comparison results for April–May 2011. The GOSAT BESD, SCIAMACHY BESD and CarbonTracker maps show a similar strong latitudinal dependence of XCO${}_{\mathrm{2}}$ with high XCO${}_{\mathrm{2}}$ in the Northern Hemisphere and low XCO${}_{\mathrm{2}}$ in the Southern Hemisphere. The number of grid boxes filled with sufficient observations is larger for SCIAMACHY than for GOSAT BESD. In comparison to CarbonTracker, GOSAT BESD as well as SCIAMACHY BESD has a small mean difference (GOSAT: $0.10$ $\mathrm{ppm}$; SCIAMACHY: $0.03$ $\mathrm{ppm}$) and a similar standard deviation of the difference (GOSAT: $1.29$ $\mathrm{ppm}$; SCIAMACHY: $1.30$ $\mathrm{ppm}$). The correlation coefficient between the BESD data sets and CarbonTracker is similarly high ($\sim 0.9$). The direct comparison between GOSAT BESD and SCIAMACHY BESD shows a mean difference of $0.09$ $\mathrm{ppm}$, a smaller standard deviation of the difference of $1.17$ $\mathrm{ppm}$ and a similar correlation coefficient ($r=0.92$) as compared to the difference to CarbonTracker. In addition to the global maps, latitudinal averages of the differences are shown (Fig. , right panel). Generally the latitudinal differences between the data sets are small. We have also computed the standard deviation of the latitudinal differences (${\mathit{\sigma }}_{\mathrm{l}}$). The differences between GOSAT BESD or SCIAMACHY BESD to CarbonTracker show a similar ${\mathit{\sigma }}_{\mathrm{l}}$ (GOSAT: $0.42$ $\mathrm{ppm}$; SCIAMACHY: $0.44$ $\mathrm{ppm}$), but the differences between GOSAT and SCIAMACHY BESD are smaller with ${\mathit{\sigma }}_{\mathrm{l}}=0.29$ $\mathrm{ppm}$. These results show that the north to south dependence of XCO${}_{\mathrm{2}}$ is more consistent between the BESD data sets as compared to CarbonTracker.

The results for August–September 2011 are shown in Fig. . The northern hemispheric carbon uptake in this time period explains the low XCO${}_{\mathrm{2}}$ values in the Northern Hemisphere shown in all three data sets. The number of grid boxes is again larger for SCIAMACHY compared to GOSAT BESD. The comparison with CarbonTracker shows for GOSAT and SCIAMACHY a similar small offset ($-0.04$ $\mathrm{ppm}$). The standard deviation of the difference is somewhat smaller for GOSAT ($1.14$ $\mathrm{ppm}$) as compared to SCIAMACHY BESD ($1.28$ $\mathrm{ppm}$) and the correlation coefficient is similar (GOSAT: $0.71$; SCIAMACHY: $0.74$). The direct comparison of the BESD data sets shows a smaller/similar standard deviation of the difference ($1.02$ $\mathrm{ppm}$) and has a similarly high correlation coefficient ($0.80$) as obtained from the comparison with CarbonTracker. The latitudinal averages of GOSAT BESD–CarbonTracker as well as SCIAMACHY BESD–CarbonTracker decrease in a similar way near the equator. As a result the latitudinal averages of the difference between the two BESD data sets are smaller (${\mathit{\sigma }}_{\mathrm{l}}=0.35$ $\mathrm{ppm}$) than the difference of either data set to CarbonTracker (GOSAT: $0.68$ $\mathrm{ppm}$; SCIAMACHY: $0.62$ $\mathrm{ppm}$). These results again show that the north to south dependence of XCO${}_{\mathrm{2}}$ is more consistent between the BESD data sets as compared to CarbonTracker.

The remaining differences between GOSAT and SCIAMACHY BESD are likely due to the non-perfect spatial and temporal collocations and a non-perfect BESD algorithm. However, the smaller/similar differences of the BESD data sets as compared to CarbonTracker are another indication for the high degree of consistency between GOSAT and SCIAMACHY BESD.

Conclusions

As consistent long-term data sets of XCO${}_{\mathrm{2}}$ are required for carbon cycle and climate-related research, we have investigated whether retrievals of XCO${}_{\mathrm{2}}$ from different satellites but evaluated using the same retrieval algorithm are consistent. For this purpose, the BESD algorithm originally developed for SCIAMACHY measurements has been modified and used to also evaluate GOSAT measurements.

The quality of the BESD data products was estimated by a validation study using TCCON observations. This comparison showed that the GOSAT BESD XCO${}_{\mathrm{2}}$ data product has a mean offset of $-0.30$ $\mathrm{ppm}$, a single measurement precision of $2.09$ $\mathrm{ppm}$, a mean correlation coefficient of $0.79$ and a station-to-station bias of $0.43$ $\mathrm{ppm}$. The SCIAMACHY BESD XCO${}_{\mathrm{2}}$ data product has a mean offset of $-0.05$ $\mathrm{ppm}$, a single measurement precision of $2.20$ $\mathrm{ppm}$, a mean correlation coefficient of $0.78$ and a station-to-station bias of $0.89$ $\mathrm{ppm}$ ($0.67$ $\mathrm{ppm}$ without Four Corners).

In order to evaluate the consistency of the satellite data products, we compared the data products with the TCCON data for the same time period and performed a direct comparison of the satellite data.

The comparison of the validation results for the years 2010–2011, when the observation periods of SCIAMACHY and GOSAT overlap, showed for both data sets a small mean offset ($-0.42$ $\mathrm{ppm}$ for GOSAT, $-0.08$ $\mathrm{ppm}$ for SCIAMACHY), a similar single measurement precision of $2.04$ $\mathrm{ppm}$ for GOSAT and $2.12$ $\mathrm{ppm}$ for SCIAMACHY and a similar mean correlation coefficient for GOSAT ($0.71$) and SCIAMACHY ($0.63$). The station-to-station bias for GOSAT is slightly better with $0.48$ $\mathrm{ppm}$ compared to $0.88$ $\mathrm{ppm}$ for SCIAMACHY.

The GOSAT BESD and SCIAMACHY BESD XCO${}_{\mathrm{2}}$ data show similarities in the comparisons at the TCCON sites. The mean difference from TCCON is at e.g. Bremen ($-1.01$ $\mathrm{ppm}$ for GOSAT and $-1.07$ $\mathrm{ppm}$ for SCIAMACHY) and Darwin ($-1.00$ $\mathrm{ppm}$ for GOSAT and $-0.87$ $\mathrm{ppm}$ for SCIAMACHY) similarly low. Overall, the correlation coefficient between the station biases of both data sets is large (0.83). The single measurement precision has similar small values e.g. at Darwin ($1.24$ $\mathrm{ppm}$ for GOSAT and $1.67$ $\mathrm{ppm}$ for SCIAMACHY) and a similar high value e.g. at Karlsruhe ($2.67$ $\mathrm{ppm}$ for GOSAT and $2.55$ $\mathrm{ppm}$ for SCIAMACHY). These similarities, the large correlation coefficient of the station biases and the similarity of the validation results give evidence that the GOSAT BESD XCO${}_{\mathrm{2}}$ and the SCIAMACHY BESD XCO${}_{\mathrm{2}}$ are generally consistent.

In a direct comparison of the satellite data, we analysed daily averages of GOSAT and SCIAMACHY BESD XCO${}_{\mathrm{2}}$. This analysis showed an offset between the data sets of $-0.77$ $\mathrm{ppm}$, a similar standard difference between the data sets ($1.51$ $\mathrm{ppm}$) compared to the TCCON comparison ($1.28$ $\mathrm{ppm}$ for GOSAT and $1.60$ $\mathrm{ppm}$ for SCIAMACHY), a high correlation coefficient ($0.80$) and smaller/similar station-to-station variations of the mean difference ($0.59$ $\mathrm{ppm}$) compared to the difference to TCCON ($0.54$ $\mathrm{ppm}$ for GOSAT and $0.85$ $\mathrm{ppm}$ for SCIAMACHY).

We have also compared global monthly maps and latitudinal averages of the satellite data sets with CarbonTracker XCO${}_{\mathrm{2}}$. Results of two time periods, April–May and August–September 2011, were presented. These results showed that the differences between the BESD data sets are smaller/similar as the difference to CarbonTracker.

The remaining differences found between GOSAT and SCIAMACHY are likely not only due to non-perfect collocation (i.e. the observed air masses can be not identical) but likely also to a non-perfect BESD retrieval algorithm. However, the similar scatter of the difference between the data sets compared to the difference to TCCON and CarbonTracker and the smaller/similar station-to-station variation of the differences of the data sets compared to the difference to TCCON indicate a high degree of consistency between the SCIAMACHY and GOSAT XCO${}_{\mathrm{2}}$ data sets. These results demonstrates that consistent retrievals can be obtained from different satellite instruments using the same retrieval algorithm.

Our overarching goal is to generate a satellite-derived XCO${}_{\mathrm{2}}$ data set appropriate for climate and carbon cycle research covering the longest time period. We therefore also plan to extend the existing SCIAMACHY and GOSAT data set discussed here by also using data from other current or future missions, e.g. OCO-2 , GOSAT-2 and CarbonSat .

The Supplement related to this article is available online at doi:10.5194/amt-8-2961-2015-supplement.

Acknowledgements

We thank JAXA, NIES and ESA for providing us with the GOSAT L1B and L2 IDS data. We are also grateful to Jonathan de Ferranti for the development of the digital elevation model, which we used for our evaluations. We thank TCCON for providing FTS XCO${}_{\mathrm{2}}$ data obtained from the TCCON Data Archive, operated by the California Institute of Technology, from the website at http://tccon.ipac.caltech.edu/. The CarbonTracker CT2013B results has been provided by NOAA ESRL, Boulder, Colorado, USA, from the website at http://carbontracker.noaa.gov. We thank NASA for providing us with the ABSCOv4 tables and ECMWF for the meteorological data. This work has been funded by the EU FP7 (MACC-II), EU Horizon 2020 (MACC-III), ESA (GHG-CCI project and Living Planet Fellowship project CARBOFIRES) and the state and the University of Bremen. The article processing charges for this open-access publication were covered by the University of Bremen. Edited by: D. Brunner