Your search keyword '"Ruedy, Reto"' showing total 6 results

1. Global Climate Data and Models: A Reconciliation

Author

Hansen, James E., Sato, Makiko, Ruedy, Reto, Lacis, Andrew, and Glascoe, Jay

Published

1998

2. Present-Day Atmospheric Simulations Using GISS ModelE : Comparison to In Situ, Satellite, and Reanalysis Data

Author

Schmidt, Gavin A., Ruedy, Reto, Hansen, James E., Aleinov, Igor, Bell, Nadine, Bauer, Mike, Bauer, Susanne, Cairns, Brian, Canuto, Vittorio, Cheng, Ye, Del Genio, Anthony, Faluvegi, Greg, Friend, Andrew D., Hall, Tim M., Hu, Yongyun, Kelley, Max, Kiang, Nancy Y., Koch, Dorothy, Lacis, Andy A., Lerner, Jean, Lo, Ken K., Miller, Ron L., Nazarenko, Larissa, Oinas, Valdar, Perlwitz, Jan, Perlwitz, Judith, Rind, David, Romanou, Anastasia, Russell, Gary L., Sato, Makiko, Shindell, Drew T., Stone, Peter H., Sun, Shan, Tausnev, Nick, Thresher, Duane, and Yao, Mao-Sung

Published

2006

3. Future Climate Change Under SSP Emission Scenarios With GISS‐E2.1.

Author

Nazarenko, Larissa S., Tausnev, Nick, Russell, Gary L., Rind, David, Miller, Ron L., Schmidt, Gavin A., Bauer, Susanne E., Kelley, Maxwell, Ruedy, Reto, Ackerman, Andrew S., Aleinov, Igor, Bauer, Michael, Bleck, Rainer, Canuto, Vittorio, Cesana, Grégory, Cheng, Ye, Clune, Thomas L., Cook, Ben I., Cruz, Carlos A., and Del Genio, Anthony D.

Subjects

CLIMATE change, CLIMATE sensitivity, GENERAL circulation model, ATMOSPHERIC models, STREAM function

Abstract

This paper presents the response to anthropogenic forcing in the GISS‐E2.1 climate models for the 21st century Shared Socioeconomic Pathways emission scenarios within the Coupled Model Intercomparison Project Phase 6 (CMIP6). The experiments were performed using an updated and improved version of the NASA Goddard Institute for Space Studies (GISS) coupled general circulation model that includes two different versions for atmospheric composition: A non‐interactive version (NINT) with prescribed composition and a tuned aerosol indirect effect and the One‐Moment Aerosol model (OMA) version with fully interactive aerosols which includes a parameterized first indirect aerosol effect on clouds. The effective climate sensitivities are 3.0°C and 2.9°C for the NINT and OMA models, respectively. Each atmospheric version is coupled to two different ocean general circulation models: The GISS ocean model (E2.1‐G) and HYCOM (E2.1‐H). We describe the global mean responses for all future scenarios and spatial patterns of change for surface air temperature and precipitation for four of the marker scenarios: SSP1‐2.6, SSP2‐4.5, SSP4‐6.0, and SSP5‐8.5. By 2100, global mean warming ranges from 1.5°C to 5.2°C relative to 1,850–1,880 mean temperature. Two high‐mitigation scenarios SSP1‐1.9 and SSP1‐2.6 limit the surface warming to below 2°C by the end of the 21st century, except for the NINT E2.1‐H model that simulates 2.2°C of surface warming. For the high emission scenario SSP5‐8.5, the range is 4.6–5.2°C at 2100. Due to about 15% larger effective climate sensitivity and stronger transient climate response in both NINT and OMA CMIP6 models compared to CMIP5 versions, there is a stronger warming by 2100 in the SSP emission scenarios than in the comparable Representative Concentration Pathway (RCP) scenarios in CMIP5. Changes in sea ice area are highly correlated to global mean surface air temperature anomalies and show steep declines in both hemispheres, with the largest sea ice area decreases occurring during September in the Northern Hemisphere in both E2.1‐G (−1.21 × 106 km2/°C) and E2.1‐H models (−0.94 × 106 km2/°C). Both coupled models project decreases in the Atlantic overturning stream function by 2100. The largest decrease of 56%–65% in the 21st century overturning stream function is produced in the warmest scenario SSP5‐8.5 in the E2.1‐G model, comparable to the reduction in the corresponding CMIP5 GISS‐E2 RCP8.5 simulation. Both low‐end scenarios SSP1‐1.9 and SSP1‐2.6 also simulate substantial reductions of the overturning (9%–37%) with slow recovery of about 10% by the end of the 21st century (relative to the maximum decrease at the middle of the 21st century). Plain Language Summary: The projections of future climate change are uncertain because they are dependent on different possible scenarios of human‐caused emissions and their interaction with natural forcings, internal climate variability, and inter‐model differences. This paper presents the results of the climate model of the NASA Goddard Institute for Space Studies, GISS‐E2.1, for the anthropogenically forced climate response for the twenty first century Shared Socioeconomic Pathways emission scenarios within the Coupled Model Intercomparison Project Phase 6 (CMIP6). The sensitivity of the model response to different magnitudes of anthropogenic forcings in the twenty‐first‐century scenarios were performed using two different versions for the atmospheric composition and two different ocean general circulation models. Compared to CMIP5 GISS‐E2 versions, the CMIP6 GISS‐E2.1 climate model shows a stronger warming by 2100 in comparable scenarios due to larger effective climate sensitivity and transient climate response. Both climate models with two different ocean components project decreases in the Atlantic overturning stream function by 2100. Key Points: GISS E2.1 model with different configurations is used to carry out 134 Shared Socioeconomic Pathway (SSP) experimentsGISS‐E2.1 climate model shows a stronger warming by 2,100 in comparable Representative Concentration Pathway scenarios in CMIP5 due to larger effective climate sensitivity and stronger transient climate responseBoth coupled models, E2.1‐G and E2.1‐H, project decreases in the Atlantic overturning stream function by 2100 with the largest decrease in the warmest scenario SSP5‐8.5 in the E2.1‐G model [ABSTRACT FROM AUTHOR]

Published

2022

4. CMIP6 Historical Simulations (1850–2014) With GISS‐E2.1.

Author

Miller, Ron L., Schmidt, Gavin A., Nazarenko, Larissa S., Bauer, Susanne E., Kelley, Maxwell, Ruedy, Reto, Russell, Gary L., Ackerman, Andrew S., Aleinov, Igor, Bauer, Michael, Bleck, Rainer, Canuto, Vittorio, Cesana, Grégory, Cheng, Ye, Clune, Thomas L., Cook, Ben I., Cruz, Carlos A., Del Genio, Anthony D., Elsaesser, Gregory S., and Faluvegi, Greg

Subjects

NEWTON'S laws of motion, HEAT storage, GREENHOUSE gases, CLIMATE sensitivity, ATMOSPHERIC models

Abstract

Simulations of the CMIP6 historical period 1850–2014, characterized by the emergence of anthropogenic climate drivers like greenhouse gases, are presented for different configurations of the NASA Goddard Institute for Space Studies (GISS) Earth System ModelE2.1. The GISS‐E2.1 ensembles are more sensitive to greenhouse gas forcing than their CMIP5 predecessors (GISS‐E2) but warm less during recent decades due to a forcing reduction that is attributed to greater longwave opacity in the GISS‐E2.1 pre‐industrial simulations. This results in an atmosphere less sensitive to increases in opacity from rising greenhouse gas concentrations, demonstrating the importance of the base climatology to forcing and forced climate trends. Most model versions match observed temperature trends since 1979 from the ocean to the stratosphere. The choice of ocean model is important to the transient climate response, as found previously in CMIP5 GISS‐E2: the model that more efficiently exports heat to the deep ocean shows a smaller rise in tropospheric temperature. Model sea level rise over the historical period is traced to excessive drawdown of aquifers to meet irrigation demand with a smaller contribution from thermal expansion. This shows how fully coupled models can provide indirect observational constraints upon forcing, in this case, constraining irrigation rates with observed sea level changes. The overall agreement of GISS‐E2.1 with observed trends is familiar from evaluation of its predecessors, as is the conclusion that these trends are almost entirely anthropogenic in origin. Plain Language Summary: Measurements show clear evidence of warming over the twentieth century and up to the present day. Our anticipation of future change comes from computer models of climate. These are based upon well‐established physical principles like Newton's laws of motion and radiative transfer theory; the models are closely related to those used for weather forecasting. We can never predict the weather on a particular day, 50 years in the future, but we can calculate whether that future decade will be warmer than our present climate. Part of our confidence in such a forecast comes from testing a climate model's ability to reproduce warming and other changes measured over the past century. We use observations of atmospheric composition and the sunlight received by our planet to calculate how the model responds to their changes. The climate model of the NASA Goddard Institute for Space Studies, GISS‐E2.1, closely follows changes measured in the ocean and atmosphere as the concentrations of greenhouse gases and other pollutants rise. This agreement suggests that future warming by greenhouse gases will be reliably predicted by GISS‐E2.1. This suggests that the warming we already experience is due to our consumption of fossil fuels that has led to the increase of carbon dioxide and other greenhouse gases in the atmosphere over the past two centuries. Key Points: Tropospheric warming and ocean heat uptake by 2014 are smaller in GISS‐E2.1 and closer to observed trends than in its CMIP5 predecessorGISS‐E2.1 climate sensitivity is higher than in CMIP5 GISS‐E2, but forcing by greenhouse gases is smallerAtmospheric trends vary among model configurations with the storage of heat beneath the thermocline [ABSTRACT FROM AUTHOR]

Published

2021

5. Configuration and assessment of the GISS ModelE2 contributions to the CMIP5 archive.

Author

Schmidt, Gavin A., Kelley, Max, Nazarenko, Larissa, Ruedy, Reto, Russell, Gary L., Aleinov, Igor, Bauer, Mike, Bauer, Susanne E., Bhat, Maharaj K., Bleck, Rainer, Canuto, Vittorio, Chen, Yong‐Hua, Cheng, Ye, Clune, Thomas L., Del Genio, Anthony, de Fainchtein, Rosalinda, Faluvegi, Greg, Hansen, James E., Healy, Richard J., and Kiang, Nancy Y.

Subjects

GENERAL circulation model, ATMOSPHERIC composition, ATMOSPHERIC models, ATMOSPHERIC chemistry, HYDROLOGIC cycle

Abstract

We present a description of the ModelE2 version of the Goddard Institute for Space Studies (GISS) General Circulation Model (GCM) and the configurations used in the simulations performed for the Coupled Model Intercomparison Project Phase 5 (CMIP5). We use six variations related to the treatment of the atmospheric composition, the calculation of aerosol indirect effects, and ocean model component. Specifically, we test the difference between atmospheric models that have noninteractive composition, where radiatively important aerosols and ozone are prescribed from precomputed decadal averages, and interactive versions where atmospheric chemistry and aerosols are calculated given decadally varying emissions. The impact of the first aerosol indirect effect on clouds is either specified using a simple tuning, or parameterized using a cloud microphysics scheme. We also use two dynamic ocean components: the Russell and HYbrid Coordinate Ocean Model (HYCOM) which differ significantly in their basic formulations and grid. Results are presented for the climatological means over the satellite era (1980-2004) taken from transient simulations starting from the preindustrial (1850) driven by estimates of appropriate forcings over the 20th Century. Differences in base climate and variability related to the choice of ocean model are large, indicating an important structural uncertainty. The impact of interactive atmospheric composition on the climatology is relatively small except in regions such as the lower stratosphere, where ozone plays an important role, and the tropics, where aerosol changes affect the hydrological cycle and cloud cover. While key improvements over previous versions of the model are evident, these are not uniform across all metrics. [ABSTRACT FROM AUTHOR]

Published

2014

6. The sensitivity of the equatorial pacific ODZ to particulate organic matter remineralization in a climate model under pre-industrial conditions.

Author

Lerner, Paul, Romanou, Anastasia, Nicholson, David, Kelley, Maxwell, Ruedy, Reto, and Russell, Gary

Subjects

*ATMOSPHERIC models, *ORGANIC compounds, *DISSOLVED organic matter, *OXYGEN content of seawater, *HETEROTROPHIC respiration, *ATMOSPHERE

Abstract

Marine oxygen plays a fundamental role in regulating the transfer of organic carbon and nutrients to their dissolved inorganic forms, serving as the terminal electron acceptor for heterotrophic respiration. Oxygen can become limiting to these processes in coastal and open-ocean oxygen deficient zones (ODZs). The maintenance of ODZs depends on the balance between physical processes such as ventilation and biogeochemical processes such as remineralization. These two processes act in opposing directions on ODZs, with ventilation responsible for transporting oxygen from the surface, where it is near saturation with the partial pressure of O 2 in the atmosphere, to deeper oxygen-depleted layers, and remineralization acting to consume oxygen through biogeochemical processes such as microbial degradation throughout the water column. Remineralization is represented in all CMIP6 models, but the actual parameterizations, as well as their magnitude, are widely varying. In this study, we examine the sensitivity to remineralization of the equatorial Pacific ODZ (O 2 < 60 μ m ol/kg) in a model; the NASA GISS Ocean Biogeochemical Model (NOBM-G) embedded in the NASA-GISS coupled atmosphere-ocean model. We find that increasing the remineralization rate shoals the ODZ onset depth (i.e. the regionally averaged upper bound of the ODZ), and decreases ODZ volume and regional-averaged thickness. Changes in biological consumption and vertical convergence of oxygen are identified as the primary contributors to changes in ODZ onset depth. ODZ thickness is mainly influenced by the shoaling of the bottom boundary of the ODZ, which decreases with maximum remineralization rate due to decreasing oxygen consumption and increasing horizontal oxygen convergence in deep waters. On the other hand, vertically-averaged ODZ area has a more complex, non-monotonic relationship with maximum remineralization rate. While these findings suggest an important role for remineralization in determining the shape of the ODZ in our model, the relative importance of remineralization vs. other physical parameterizations remains to be established. While our results reflect the structure of our ocean biogeochemical model, the relationship of remineralization to ODZ characteristics in other models should be examined to better inform model inter-comparisons. • ODZ volume, depth, and thickness decrease as the remineralization rate increases. • ODZ area displays a non-monotonic relationship with remineralization rate. • Subpycnocline ODZ depth is controlled by O 2 consumption and vertical convergence. • Increasing remineralization lowers deep ocean O 2 consumption, reducing ODZ thickness. [ABSTRACT FROM AUTHOR]

Published

2024