Geoscientific Model Development
www.geosci-model-dev.net
1991-959X
1991-9603
3
2
2010
10.5194/gmd-3-365-2010
http://www.geosci-model-dev.net/3/365/2010/
http://www.geosci-model-dev.net/3/365/2010/gmd-3-365-2010.html
http://www.geosci-model-dev.net/3/365/2010/gmd-3-365-2010.pdf
365
376
2010-08-13
Development of a system emulating the global carbon cycle in Earth system models
K. Tachiiri
tachiiri@jamstec.go.jp
J. C. Hargreaves
J. D. Annan
A. Oka
A. Abe-Ouchi
M. Kawamiya
Japan Agency for Marine-Earth Science and Technology 3173-25 Showamachi, Kanazawa-ku, Yokohama, 236-0001, Japan
Atmosphere and Ocean Research Institute, University of Tokyo, 5-1-5, Kashiwanoha, Kashiwa, Chiba, 277-8568, Japan
Recent studies have indicated that the uncertainty in the global carbon cycle
may have a significant impact on the climate. Since state of the art models
are too computationally expensive for it to be possible to explore their
parametric uncertainty in anything approaching a comprehensive fashion, we
have developed a simplified system for investigating this problem. By
combining the strong points of general circulation models (GCMs), which
contain detailed and complex processes, and Earth system models of
intermediate complexity (EMICs), which are quick and capable of large
ensembles, we have developed a loosely coupled model (LCM) which can
represent the outputs of a GCM-based Earth system model, using much smaller
computational resources. We address the problem of relatively poor
representation of precipitation within our EMIC, which prevents us from
directly coupling it to a vegetation model, by coupling it to a precomputed
transient simulation using a full GCM. The LCM consists of three components:
an EMIC (MIROC-lite) which consists of a 2-D energy balance atmosphere
coupled to a low resolution 3-D GCM ocean (COCO) including an ocean carbon
cycle (an NPZD-type marine ecosystem model); a state of the art vegetation
model (Sim-CYCLE); and a database of daily temperature, precipitation, and
other necessary climatic fields to drive Sim-CYCLE from a precomputed
transient simulation from a state of the art AOGCM. The transient warming of
the climate system is calculated from MIROC-lite, with the global temperature
anomaly used to select the most appropriate annual climatic field from the
pre-computed AOGCM simulation which, in this case, is a 1% pa increasing
CO<sub>2</sub> concentration scenario.
<br><br>
By adjusting the effective climate sensitivity (equivalent to the equilibrium
climate sensitivity for an energy balance model) of MIROC-lite, the transient
warming of the LCM could be adjusted to closely follow the low sensitivity
(with an equilibrium climate sensitivity of 4.0 K) version of MIROC3.2. By
tuning of the physical and biogeochemical parameters it was possible to
reasonably reproduce the bulk physical and biogeochemical properties of
previously published CO<sub>2</sub> stabilisation scenarios for that model. As an
example of an application of the LCM, the behavior of the high sensitivity
version of MIROC3.2 (with a 6.3 K equilibrium climate sensitivity) is also
demonstrated. Given the highly adjustable nature of the model, we believe
that the LCM should be a very useful tool for studying uncertainty in global
climate change, and we have named the model, JUMP-LCM, after the name of our
research group (Japan Uncertainty Modelling Project).
Bryan, K.: Accelerating the convergence to equilibrium of ocean-climate models, J. Phys. Oceanogr., 14, 666–673, 1984.
Claussen, M., Mysak, L. A., Weaver, A. J., Crucifix, M., Fichefet, T., Loutre, M.-F., Weber, S. L., Alcamo, J., Alexeev, V. A., Berger, A., Calov, R., Ganopolski, A., Goosse, H., Lohmann, G., Lunkeit, F., Mokhov, I. I., Petoukhov, V., Stone, P., and Wang, Z.: Earth system models of intermediate complexity: closing the gap in the spectrum of climate system models, Clim. Dynam., 18, 579–586, 2002.
Edwards, N. R. and Marsh, R. J.: Uncertainties due to transport parameter sensitivity in an efficient 3-D ocean-climate model., Clim. Dynam., 24, 415–433, doi:10.1007/s00382-004-0508-8, 2005.
Gent, P. R. and McWilliams, J C.: Isopycnal mixing in ocean circulation models, J. Phys. Oceanogr., 20, 150–155, 1990.
Gregory, J M. and Forster, P M.: Transient climate response estimated from radiative forcing and observed temperature change, J. Geophys. Res., 113, D23105, doi:10.1029/2008JD010405, 2008.
Hasumi, H. and Suginohara, N.: Sensitivity of a global ocean general circulation model to tracer advection schemes, J. Phys. Oceanogr., 29, 2730–2740, 1999.
Hoerling, M., Kumar, A., Eischeid, J., and Jha, B.: What is causing the variability in global mean land temperature?, Geophys. Res. Lett., 35, L23712, doi:10.1029/2008GL035984, 2008.
Hooss, G., Voss, R., Hasselmann, K., Maier-Reimer, E., and Joos, F.: A nonlinear impulse response model of the coupled carbon cycle-climate system (NICCS), Clim. Dynam., 18, 189–202, 2001.
Huntingford, C., Lowe, J. A., Booth, B. B. B., Jones, C. D., Harris, G. R., Gohar, L. K., and Meir, P.: Contributions of carbon cycle uncertainty to future climate projection spread, Tellus B, 61, 355–360, doi:10.1111/j.1600–0889.2009.00414.x, 2009.
IPCC: Climate Change 2007: The Physical Science Basis, in: Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change, edited by: Solomon, S., Qin, D., Manning, M., Chen, Z., Marquis, M., Averyt, K. B., Tignor, M., and Miller, H. L., Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 996~pp., 2007.
Ito, A. and Oikawa, T.: A simulation model of the carbon cycle in land ecosystems (Sim-CYCLE): a description based on dry-matter production theory and plot-scale validation, Ecol. Model., 151, 143–176, 2002.
K-1 model developers: K-1 Coupled GCM (MIROC) Description, K-1 Technical Report No.1, available at: http://www.ccsr.u-tokyo.ac.jp/kyosei/hasumi/MIROC/tech-repo.pdf (last access: 5~August 2010), 2004.
Kawamiya, M., Yoshikawa, C., Kato, T., Sato, H., Sudo, K., Watanabe, S., and Matsuno, T.: Development of an integrated Earth system model on the Earth Simulator, J. Earth Simulator, 4, 18–30, 2005.
Lloyd, J. and Taylor, J. A.: On the temperature dependence of soil respiration, Funct. Ecol., 8, 315–323, 1994.
Matthews, E.: Vegetation, land-use and seasonal albedo data sets: Documentation of archived data sets, NASA Technical Memorandum, No 86107, p 12, 1984.
Meehl, G A., Covey, C., Delworth, T., et al.: The WCRP CMIP3 multi-model dataset: A new era in climate change research, B. Am. Meteorol. Soc., 88, 1383–1394, 2007.
Mitchell, J. F. B., Johns, T. C., Eagles, M., Ingram, W. J., and Davis, R. A.: Towards the construction of climate change scenarios, Climatic Change, 41, 547–581, 1999.
Miyama, T. and Kawamiya, M.: Estimating allowable carbon emission for CO<sub>2</sub> concentration stabilization using a GCM-Based Earth system model, Geophys. Res. Lett., 36, L19709, doi:10.1029/2009GL039678, 2009.
Monsi, M. and Saeki, T.: Uber den Lichtfaktor in den Pflanzengesellschaften und seine Bedeutung fur die Stoffproduktion, Jpn. J. Bot., 14, 22–52, 1953 (in German, English version available as: On the Factor Light in Plant Communities and its Importance for Matter Production, Ann. Bot., 95, 549–567, 2005).
Mueller, S.: Stabilisation Pathways SP450, SP550, SP650, SP750, SP1000, DSP450, DSP550, OSP350, OSP450, available at: http://www.climate.unibe.ch/emicAR4/ (last access: 5~August 2010), 2004.
Ogura, T., Emori, S., Webb, M J., Tsushima, Y., Yokohata, T., Abe-Ouchi, A., and Kimoto, M.: Towards understanding cloud response in atmospheric GCMs: the use of tendency diagnostics, J. Meterol. Soc. Jpn., 86, 69–79, 2008.
Oikawa, T.: Simulation of forest carbon dynamics based on a dry-matter production model i. fundamental model structure of a tropical rainforest ecosystem, Bot. Mag.-Tokyo, 98, 225–238, 1985.
Oka, A., Hasumi, H., and Suginohara, N.: Stabilization of thermohaline circulation by wind-driven and vertical diffusive salt transport, Clim. Dynam., 18, 71–83, 2001.
Oka, A., Tajika, E., Abe-Ouchi, A., and Kubota, K.: Role of ocean in controlling atmospheric CO<sub>2</sub> concentration in the course of global glaciations, Clim. Dynam., submitted, 2010.
Oort, A H.: Global atmospheric circulation statistics, 1958–1973, NOAA Prof Pap 14, 180~pp., 1983.
Orr, J., Najjar, R., Sabine, C. and Joos, F.: Abiotic-HOWTO Revision: 1.16, available at: http://www.cgd.ucar.edu/oce/klindsay/ocmip/HOWTO-Abiotic.pdf (last access: 5~August 2010), 2000.
Oschlies, A.: Model-derived estimates of new production: New results point towards lower values, Deep-Sea Res Pt II, 48, 2173–2197, 2001.
Oschlies, A. and Garcon, V.: An eddy-permitting coupled physical-biological model of the North Atlantic 1. Sensitivity to advection numerics and mixed layer physics, Global Biogeochem. Cy., 13, 135–160, 1999.
Palmer, J. R. and Totterdell, I. J.: Production and export in a global ocean ecosystem model, Deep-Sea Res Pt I, 48, 1169–1198, doi:10.1016/S0967-0637(00)00080-7, 2001.
Pelletier, J D.: Analysis and modeling of the natural variability of climate, J. Climate, 10, 1331–1342, 1997.
Plattner, G.-K., Joos, F., Stocker, T. F., and Marchal, O.: Feedback mechanisms and sensitivities of ocean carbon uptake under global warming, Tellus B, 53, 564–592, 2001.
Raper, S. C. B., Gregory, J. M., and Osborn, T. J.: Use of an upwelling-diffusion energy balance climate model to simulate and diagnose A/OGCM results, Clim. Dynam., 17, 601–613, 2001.
Santer, B. D., Wigley, T. M. L., Schlesinger, M. E., and Mitchell, J. F. B.: Developing climate scenarios from equilibrium GCM results, Max Planck institut für Meteorologie, Hamburg, Rep 47, 1990.
Takata, K., Emori, S., and Watanabe, T.: Development of the minimal advanced treatments of surface interaction and runoff, Global Planet. Change, 38, 209–222, 2003.
Takemura, T., Okamoto, H., Maruyama, Y., Numaguti, A., Higurashi, A., and Nakajima, T.: Global three-dimensional simulation of aerosol optical thickness distribution of various origins, J. Geophys. Res., 105(D14), 17853–17873, 2000.
Takemura, T., Nakajima, T., Dubovik, O., Holben, B N., and Kinne, S.: Single-scattering albedo and radiative forcing of various aerosol species with a global three-dimensional model, J. Climate, 15, 333–352, 2002.
Weaver, A. J., Eby, M., Wiebe, E. C., Bitz, C. M., Duffy, P. B., Ewen, T. L., Fanning, A. F., Holland, M. M., MacFadyen, A., Matthews, H. D., Meissner, K. J., Saenko, O., Schmittner, A., Wang, H., and Yoshimori, M.: The UVic Earth System Climate Model: Model description, climatology and application to past, present and future climates, Atmos Ocean, 39, 361–428, 2001.
Weber, S. L.: The utility of Earth system Models of Intermediate Complexity (EMICs), Wiley Interdisciplinary Reviews (WIREs) Climate Change, 1(2), 324–327, 2010.
Wigley, T. M L. and Raper, S. C B.: Natural variability of the climate system and detection of the greenhouse effect, Nature, 344, 243–252, 1990.
Yamanaka, Y. and Tajika, E.: The role of the vertical fluxes of particulate organic matter and calcite in the oceanic carbon cycle: Studies using an ocean biogeochemical general circulation model, Global Biogeochem. Cy., 10, 361–382, 1996.
Yokohata, T., Emori, S., Nozawa, T., Tsushima, Y., Ogura, T., and Kimoto, M.: Climate response to volcanic forcing: Validation of climate sensitivity of a coupled atmosphere-ocean general circulation model, Geophys. Res. Lett., 32, L21710, doi:10.1029/2005GL023542, 2005.
Yokohata, T., Emori, S., Nozawa, T., Ogura, T., Okada, N., Suzuki, T., Tsushima, Y., Kawamiya, M., Abe-Ouchi, A., Hasumi, H., Sumi, A., and Kimoto, M.: Different transient climate responses of two versions of an atmosphere-ocean coupled general circulation model, Geophys. Res. Lett., 34, L02707, doi:10.1029/2006GL027966, 2007.
Yokohata, T., Emori, S., Nozawa, T., Ogura, T., Kawamiya, M., Tsushima, Y., Suzuki, T., Yukimoto, S., Abe-Ouchi, A., Hasumi, H., Sumi, A., and Kimoto, M.: Comparison of equilibrium and transient responses to CO2 increase in eight state-of-the-art climate models, Tellus A, 60, 946–961, 2008.