Your search keyword '"Belikov, Dmitry A."' showing total 5 results

1. Technical note: A high-resolution inverse modelling technique for estimating surface CO2 fluxes based on the NIES-TM–FLEXPART coupled transport model and its adjoint.

Author

Maksyutov, Shamil, Oda, Tomohiro, Saito, Makoto, Janardanan, Rajesh, Belikov, Dmitry, Kaiser, Johannes W., Zhuravlev, Ruslan, Ganshin, Alexander, Valsala, Vinu K., Andrews, Arlyn, Chmura, Lukasz, Dlugokencky, Edward, Haszpra, László, Langenfelds, Ray L., Machida, Toshinobu, Nakazawa, Takakiyo, Ramonet, Michel, Sweeney, Colm, and Worthy, Douglas

Subjects

ESTIMATION theory, CARBON cycle, BIOSPHERE, ATMOSPHERIC carbon dioxide, CARBON dioxide, ATMOSPHERIC transport, TRACE gases, BIOMASS burning

Abstract

We developed a high-resolution surface flux inversion system based on the global Eulerian–Lagrangian coupled tracer transport model composed of the National Institute for Environmental Studies (NIES) transport model (TM; collectively NIES-TM) and the FLEXible PARTicle dispersion model (FLEXPART). The inversion system is named NTFVAR (NIES-TM–FLEXPART-variational) as it applies a variational optimization to estimate surface fluxes. We tested the system by estimating optimized corrections to natural surface CO2 fluxes to achieve the best fit to atmospheric CO2 data collected by the global in situ network as a necessary step towards the capability of estimating anthropogenic CO2 emissions. We employed the Lagrangian particle dispersion model (LPDM) FLEXPART to calculate surface flux footprints of CO2 observations at a spatial resolution of 0.1∘×0.1∘. The LPDM is coupled with a global atmospheric tracer transport model (NIES-TM). Our inversion technique uses an adjoint of the coupled transport model in an iterative optimization procedure. The flux error covariance operator was implemented via implicit diffusion. Biweekly flux corrections to prior flux fields were estimated for the years 2010–2012 from in situ CO2 data included in the Observation Package (ObsPack) data set. High-resolution prior flux fields were prepared using the Open-Data Inventory for Anthropogenic Carbon dioxide (ODIAC) for fossil fuel combustion, the Global Fire Assimilation System (GFAS) for biomass burning, the Vegetation Integrative SImulator for Trace gases (VISIT) model for terrestrial biosphere exchange, and the Ocean Tracer Transport Model (OTTM) for oceanic exchange. The terrestrial biospheric flux field was constructed using a vegetation mosaic map and a separate simulation of CO2 fluxes at a daily time step by the VISIT model for each vegetation type. The prior flux uncertainty for the terrestrial biosphere was scaled proportionally to the monthly mean gross primary production (GPP) by the Moderate Resolution Imaging Spectroradiometer (MODIS) MOD17 product. The inverse system calculates flux corrections to the prior fluxes in the form of a relatively smooth field multiplied by high-resolution patterns of the prior flux uncertainties for land and ocean, following the coastlines and fine-scale vegetation productivity gradients. The resulting flux estimates improved the fit to the observations taken at continuous observation sites, reproducing both the seasonal and short-term concentration variabilities including high CO2 concentration events associated with anthropogenic emissions. The use of a high-resolution atmospheric transport in global CO2 flux inversions has the advantage of better resolving the transported mixed signals from the anthropogenic and biospheric sources in densely populated continental regions. Thus, it has the potential to achieve better separation between fluxes from terrestrial ecosystems and strong localized sources, such as anthropogenic emissions and forest fires. Further improvements in the modelling system are needed as our posterior fit was better than that of the National Oceanic and Atmospheric Administration (NOAA)'s CarbonTracker for only a fraction of the monitoring sites, i.e. mostly at coastal and island locations where background and local flux signals are mixed. [ABSTRACT FROM AUTHOR]

Published

2021

2. A decadal inversion of CO2 using the Global Eulerian–Lagrangian Coupled Atmospheric model (GELCA): sensitivity to the ground-based observation network

Author

Shirai, T., Ishizawa, M., Zhuravlev, Ruslan, Ganshin, Alexander, Belikov, Dmitry A., Saito, M., Oda, Tomohiro, Valsala, V., Gómez Peláez, Ángel Jesús, Langenfelds, Ray L., and Maksyutov, Shamil

Subjects

Flux estimation, inversion, Carbon dioxide, tropical Asia, lcsh:Meteorology. Climatology, Top-down approach, Carbon cycle, lcsh:QC851-999, Physics::Atmospheric and Oceanic Physics, Coupled model

Abstract

We present an assimilation system for atmospheric carbon dioxide (CO2) using a Global Eulerian–Lagrangian Coupled Atmospheric model (GELCA), and demonstrate its capability to capture the observed atmospheric CO2 mixing ratios and to estimate CO2 fluxes. With the efficient data handling scheme in GELCA, our system assimilates non-smoothed CO2 data from observational data products such as the Observation Package (ObsPack) data products as constraints on surface fluxes. We conducted sensitivity tests to examine the impact of the site selections and the prior uncertainty settings of observation on the inversion results. For these sensitivity tests, we made five different site/ data selections from the ObsPack product. In all cases, the time series of the global net CO2 flux to the atmosphere stayed close to values calculated from the growth rate of the observed global mean atmospheric CO2 mixing ratio. At regional scales, estimated seasonal CO2 fluxes were altered, depending on the CO2 data selected for assimilation. Uncertainty reductions were determined at the regional scale and compared among cases. As measures of the model– data mismatch, we used the model–data bias, root-mean-square error, and the linear correlation. For most observation sites, the model–data mismatch was reasonably small. Regarding regional flux estimates, tropical Asia was one of the regions that showed a significant impact from the observation network settings. We found that the surface fluxes in tropical Asia were the most sensitive to the use of aircraft measurements over the Pacific, and the seasonal cycle agreed better with the results of bottom-up studies when the aircraft measurements were assimilated. These results confirm the importance of these aircraft observations, especially for constraining surface fluxes in the tropics. R. Zhuravlev is supported by Russian Science Foundation (grant No. 15-17-10024). T. Oda is supported by NASA Carbon Cycle Science program [grant number NNX14AM76G].

Published

2017

3. Study of the footprints of short-term variation in XCO2 observed by TCCON sites using NIES and FLEXPART atmospheric transport models

Author

Belikov, Dmitry A., Maksyutov, Shamil, Ganshin, Alexander, Zhuravlev, Ruslan, Deutscher, Nicholas M., Wunch, Debra, Feist, Dietrich G., Morino, Isamu, Parker, Robert J., Strong, Kimberly, Yoshida, Yukio, Bril, Andrey, Oshchepkov, Sergey, Boesch, Hartmut, Dubey, Manvendra K., Griffith, David, Hewson, Will, Kivi, Rigel, Mendonca, Joseph, Notholt, Justus, Schneider, Matthias, Sussmann, Ralf, Velazco, Voltaire A., and Aoki, Shuji

Subjects

lcsh:Chemistry, Atmospheric transport models, lcsh:QD1-999, Carbon dioxide, lcsh:Physics, lcsh:QC1-999, Astrophysics::Galaxy Astrophysics, Satellite observations

Abstract

The Total Carbon Column Observing Network (TCCON) is a network of ground-based Fourier transform spectrometers (FTSs) that record near-infrared (NIR) spectra of the sun. From these spectra, accurate and precise observations of CO2 column-averaged dry-air mole fractions (denoted XCO2) are retrieved. TCCON FTS observations have previously been used to validate satellite estimations of XCO2; however, our knowledge of the short-term spatial and temporal variations in XCO2 surrounding the TCCON sites is limited. In this work, we use the National Institute for Environmental Studies (NIES) Eulerian three-dimensional transport model and the FLEXPART (FLEXible PARTicle dispersion model) Lagrangian particle dispersion model (LPDM) to determine the footprints of short-term variations in XCO2 observed by operational, past, future and possible TCCON sites. We propose a footprint-based method for the collocation of satellite and TCCON XCO2 observations and estimate the performance of the method using the NIES model and five GOSAT (Greenhouse Gases Observing Satellite) XCO2 product data sets. Comparison of the proposed approach with a standard geographic method shows a higher number of collocation points and an average bias reduction up to 0.15 ppm for a subset of 16 stations for the period from January 2010 to January 2014. Case studies of the Darwin and Reunion Island sites reveal that when the footprint area is rather curved, non-uniform and significantly different from a geographical rectangular area, the differences between these approaches are more noticeable. This emphasises that the collocation is sensitive to local meteorological conditions and flux distributions.

Published

2017

4. Analysis of the Diurnal, Weekly, and Seasonal Cycles and Annual Trends in Atmospheric CO2 and CH4 at Tower Network in Siberia from 2005 to 2016.

Author

Belikov, Dmitry, Arshinov, Mikhail, Belan, Boris, Davydov, Denis, Fofonov, Aleksandr, Sasakawa, Motoki, and Machida, Toshinobu

Subjects

*TEMPERATURE inversions, *WIND speed, *LOW temperatures, *TOWERS, *GREENHOUSE gases

Abstract

We analyzed 12 years (2005–2016) of continuous measurements of atmospheric CO 2 and CH 4 concentrations made at nine tower observation sites in the Japan–Russia Siberian Tall Tower Inland Observation Network (JR-STATION), located in Siberia. Since the data are very noisy and have a low temporal resolution due to gaps in instrument operation, we used the recently developed Prophet model, which was designed to handle the common features of time series (multiple strong seasonalities, trend changes, outliers) and has a robust performance in the presence of missing data and trend shifts. By decomposing each sampled time-series into its major components (i.e., annual trend and seasonal, weekly, and hourly variation), we observed periodically changing patterns of tracer concentrations. Specifically, we detected multi-year variability of tracers and identified high-concentration events. The frequency of such events was found to vary throughout the year, reaching up to 20% of days for some months, while the number of such events was found to be different for CO 2 and CH 4 . An analysis of weather conditions showed that, in most cases, high-concentration events were caused by a temperature inversion and low wind speed. Additionally, wind directions were found to be different for high- and low-concentration events. For some sites, the wind direction indicated the location of strong local sources of CO 2 and CH 4 . As well as elucidating the seasonality of greenhouse gas concentrations, this study confirmed the potential of the Prophet model for detecting periodicity in environmental phenomena. [ABSTRACT FROM AUTHOR]

Published

2019

5. EOF-based regression algorithm for the fast retrieval of atmospheric CO2 total column amount from the GOSAT observations.

Author

Bril, Аndrey, Maksyutov, Shamil, Belikov, Dmitry, Oshchepkov, Sergey, Yoshida, Yukio, Deutscher, Nicholas M., Griffith, David, Hase, Frank, Kivi, Rigel, Morino, Isamu, Notholt, Justus, Pollard, David F., Sussmann, Ralf, Velazco, Voltaire A., and Warneke, Thorsten

Subjects

*ATMOSPHERIC carbon dioxide, *CARBON dioxide spectra, *SHORT wavelength spectrometers, *DECOMPOSITION method, *COLLOCATION methods, *REGRESSION analysis

Abstract

This paper presents a novel retrieval algorithm for the rapid retrieval of the carbon dioxide total column amounts from high resolution spectra in the short wave infrared (SWIR) range observations by the Greenhouse gases Observing Satellite (GOSAT). The algorithm performs EOF (Empirical Orthogonal Function)-based decomposition of the measured spectral radiance and derives the relationship of limited number of the decomposition coefficients in terms of the principal components with target gas amount and a priori data such as airmass, surface pressure, etc. The regression formulae for retrieving target gas amounts are derived using training sets of collocated GOSAT and ground-based observations. The precision/accuracy characteristics of the algorithm are analyzed by the comparison of the retrievals with those from the Total Carbon Column Observing Network (TCCON) measurements and with the modeled data, and appear similar to those achieved by full-physics retrieval algorithms. [ABSTRACT FROM AUTHOR]

Published

2017