Modelling CO&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt; weather – why horizontal resolution matters

Agustı́-Panareda, Anna; Diamantakis, Michail; Massart, S.; Chevallier, F.; Muñoz‐Sabater, Joaquín; Barré, Jérôme; Curcoll, Roger; Engelen, Richard; Langerock, Bavo; Law, R. M.; Loh, Zoë; Morguí, Josep Anton; Parrington, Mark; Peuch, Vincent-Henri; Ramonet, Michel; Roehl, Coleen M.; Vermeulen, Alex; Warneke, Thorsten; Wunch, Debra

doi:10.5194/acp-19-7347-2019

Cited by 68 publications

(77 citation statements)

References 109 publications

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“…It is possible that, although the model transport errors influence the flux estimates, the resolution-dependent transport processes are not sensitive to NEE IAV for the time period considered here. However, both model resolutions examined in this study are quite coarse, and horizontal resolu-tion becomes increasingly important at smaller spatial scales (Agustí-Panareda et al, 2019).…”

Section: Model Horizontal Resolutionmentioning

confidence: 89%

On what scales can GOSAT flux inversions constrain anomalies in terrestrial ecosystems?

et al. 2019

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Abstract. Interannual variations in temperature and precipitation impact the carbon balance of terrestrial ecosystems, leaving an imprint in atmospheric CO2. Quantifying the impact of climate anomalies on the net ecosystem exchange (NEE) of terrestrial ecosystems can provide a constraint to evaluate terrestrial biosphere models against and may provide an emergent constraint on the response of terrestrial ecosystems to climate change. We investigate the spatial scales over which interannual variability in NEE can be constrained using atmospheric CO2 observations from the Greenhouse Gases Observing Satellite (GOSAT). NEE anomalies are calculated by performing a series of inversion analyses using the GEOS-Chem adjoint model to assimilate GOSAT observations. Monthly NEE anomalies are compared to “proxies”, variables that are associated with anomalies in the terrestrial carbon cycle, and to upscaled NEE estimates from FLUXCOM. Statistically significant correlations (P<0.05) are obtained between posterior NEE anomalies and anomalies in soil temperature and FLUXCOM NEE on continental and larger scales in the tropics, as well as in the northern extratropics on subcontinental scales during the summer (R2≥0.49), suggesting that GOSAT measurements provide a constraint on NEE interannual variability (IAV) on these spatial scales. Furthermore, we show that GOSAT flux inversions are generally better correlated with the environmental proxies and FLUXCOM NEE than NEE anomalies produced by a set of terrestrial biosphere models (TBMs), suggesting that GOSAT flux inversions could be used to evaluate TBM NEE fluxes.

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Section: Model Horizontal Resolutionmentioning

confidence: 89%

On what scales can GOSAT flux inversions constrain anomalies in terrestrial ecosystems?

et al. 2019

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“…3.4). Two sets of MPAS simulations are conducted: the first set simulations covers four ACT campaign seasons (2016-2018) for evaluation using high-resolution airborne measurements; the second set covers January and July of 2014 for evaluation using near-surface CO 2 measurements and comparison with the IFS simulation results reported in Agusti-Panareda et al (2019). In the following model evaluation, https://doi.org/10.5194/gmd-2020-265 Preprint.…”

Section: Model Evaluationmentioning

confidence: 99%

“…4), the MPAS simulated horizontal wind fields have larger errors in both January and July of 2014. For instance, the IFS 80 km resolution simulation has a vector wind RMSE about 4.5 m/s at the 200 hPa level in January while MPAS results in 5.16 m/s at the same pressure level.We then compare MPAS simulated CO 2 with hourly measurements from 50 stations that were used for the IFS model evaluation inAgusti-Panareda et al (2019). The information of the 50 stations, including location, elevation, intake height, and reference is listedTable 7.…”

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confidence: 99%

“…For a given station this result in 744 (24 × 31) hourly measurements per month at the maximum. FollowingPatra et al (2008) andAgusti-Panareda et al (2019), MPAS hourly outputs are horizontally sampled by taking the nearest land cell to a given station. The resulting statistics (RMSE, bias, and STDE) for the MPAS simulation covering the month of January 2014, along with their counterparts from the IFS 9 km and 80 km resolution simulations(Agusti-Panareda et al, 2019), are listed in…”

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confidence: 99%

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Development and evaluation of CO<sub>2</sub> transport in MPAS-A v6.3

Zheng¹,

Feng²,

Davis³

et al. 2020

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Abstract. Chemistry transport models (CTM) play an important role in understanding fluxes and atmospheric distribution of carbon dioxide (CO2). They have been widely used for modeling CO2 transport through forward simulations and inferring fluxes through inversion systems. With the increasing availability of high resolution observations, it has been become possible to estimate CO2 fluxes at higher spatial resolution. However the computational cost of high resolution global model simulation is so high that only major research and operation centers can afford it. In this paper, we implemented CO2 transport in Model Prediction Across Scales-Atmosphere (MPAS-A). The objective is to use the variable-resolution capability of MPAS-A to enable high resolution CO2 simulation at limited region with a global model. Treating CO2 as an inert tracer, we implemented in MPAS-A (v6.3) the CO2 transport processes, including advection, vertical mixing by boundary layer scheme, and convective transport. We evaluated the newly implemented model by running two sets of simulations over a 60–15 km variable-resolution global domain. The first set of simulations covers four Atmospheric Carbon and Transport-America (ACT-America) aircraft campaign seasons (2016–2018), and the simulated CO2 is evaluated using the extensive airborne measurements from ACT. The simulation accuracy is also compared with a 27-km resolution WRF-Chem simulation and CarbonTracker (v2019) covering the same time periods. The second set of simulations covers the month of January and July of 2014, and the results are evaluated using near-surface hourly CO2 measurements from 50 surface and tower sites across the globe. This simulation accuracy is compared with European Center for Medium-Range Weather Forecasts (ECMWF) Integrated Forecasting System (IFS) global simulation conducted during the same period. Overall, the evaluation using aircraft measurements indicates that MPAS CO2 transport model is capable of representing the observed atmospheric CO2 structures related with the mid-latitude synoptic weather system, including the warm/cold sector distinction, boundary layer to free troposphere difference, and CO2 enhancements along frontal boundaries. The evaluation using hourly measurements shows that the MPAS CO2 transport model is capable of achieving a same level of accuracy as the IFS 80-km resolution simulation.

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“…Comparison of ECWMF IFS CO2 simulated hourly CO2 statistics with MPAS results for the month of January 2014. RMSE, STDE, and Bias of IFS 9km and 80km are reproduced from supplementTable S1ofAgusti-Panareda et al (2019) with permission.…”

mentioning

confidence: 99%

Supplementary material to "Development and evaluation of CO<sub>2</sub> transport in MPAS-A v6.3"

Zheng¹,

Feng²,

Davis³

et al. 2020

Preprint

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Modelling CO<sub>2</sub> weather – why horizontal resolution matters

Cited by 68 publications

References 109 publications

On what scales can GOSAT flux inversions constrain anomalies in terrestrial ecosystems?

On what scales can GOSAT flux inversions constrain anomalies in terrestrial ecosystems?

Development and evaluation of CO<sub>2</sub> transport in MPAS-A v6.3

Supplementary material to "Development and evaluation of CO<sub>2</sub> transport in MPAS-A v6.3"

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Modelling CO&lt;sub&gt;2&lt;/sub&gt; weather – why horizontal resolution matters

Cited by 68 publications

References 109 publications

On what scales can GOSAT flux inversions constrain anomalies in terrestrial ecosystems?

On what scales can GOSAT flux inversions constrain anomalies in terrestrial ecosystems?

Development and evaluation of CO&lt;sub&gt;2&lt;/sub&gt; transport in MPAS-A v6.3

Supplementary material to &quot;Development and evaluation of CO&lt;sub&gt;2&lt;/sub&gt; transport in MPAS-A v6.3&quot;

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Modelling CO<sub>2</sub> weather – why horizontal resolution matters

Development and evaluation of CO<sub>2</sub> transport in MPAS-A v6.3

Supplementary material to "Development and evaluation of CO<sub>2</sub> transport in MPAS-A v6.3"