Vulnerability of Freshwater Resources to Climate Change in the Tropical Pacific Region

Abstract The coupled model of the Institute of Atmospheric Physics (IAP) is used to investigate the effects of extratropical cooling and warming on the tropical Pacific climate. The IAP coupled model is a fully coupled GCM without any flux correction. The model has been used in many aspects of climate modeling, including the Intergovernmental Panel on Climate Change (IPCC) Fourth Assessment Report (AR4) climate change and paleoclimate simulations. In this study, the IAP coupled model is subjected to cooling or heating over the extratropical Pacific. As in an earlier study, the cooling and heating is imposed over the extratropical region poleward of 10°N–10°S. Consistent with earlier findings, an elevated (reduced) level of ENSO activity in response to an increase (decrease) in the cooling over the extratropical region is found. The changes in the time-mean structure of the equatorial upper ocean are also found to be very different between the case in which ocean–atmosphere is coupled over the equatorial region and the case in which the ocean–atmosphere over the equatorial region is decoupled. For example, in the uncoupled run, the thermocline water across the entire equatorial Pacific is cooled in response to an increase in the extratropical cooling. In the corresponding coupled run, the changes in the equatorial upper-ocean temperature in the extratropical cooling resemble a La Niña situation—a deeper thermocline in the western and central Pacific accompanied by a shallower thermocline in the eastern Pacific. Conversely, with coupling, the response of the equatorial upper ocean to extratropical cooling resembles an El Niño situation. These results ascertain the role of extratropical ocean in determining the amplitude of ENSO. The results also underscore the importance of ocean–atmosphere coupling in the interaction between the tropical Pacific and the extratropical Pacific.

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Checklist & botanical bibliography of the Aroids of Malesia, Australia, and the Tropical Pacific region

Nordic Journal of Botany ◽

10.1111/j.1756-1051.1996.tb00228.x ◽

1996 ◽

Vol 16 (3) ◽

pp. 276-276

Author(s):

Kai Larsen

Keyword(s):

Tropical Pacific ◽

Pacific Region ◽

The Tropical Pacific

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CAPE Variations in the Current Climate and in a Climate Change

Journal of Climate ◽

10.1175/1520-0442-11.8.1997 ◽

1998 ◽

Vol 11 (8) ◽

pp. 1997-2015 ◽

Cited By ~ 39

Author(s):

Bing Ye ◽

Anthony D. Del Genio ◽

Kenneth K-W. Lo

Keyword(s):

Climate Change ◽

Relative Humidity ◽

General Circulation ◽

Large Scale ◽

Tropical Pacific ◽

Lapse Rate ◽

Moist Convection ◽

Upper Troposphere ◽

Current Climate ◽

The Tropical Pacific

Abstract Observed variations of convective available potential energy (CAPE) in the current climate provide one useful test of the performance of cumulus parameterizations used in general circulation models (GCMs). It is found that frequency distributions of tropical Pacific CAPE, as well as the dependence of CAPE on surface wet-bulb potential temperature (Θw) simulated by the Goddard Institute for Space Studies’s GCM, agree well with that observed during the Australian Monsoon Experiment period. CAPE variability in the current climate greatly overestimates climatic changes in basinwide CAPE in the tropical Pacific in response to a 2°C increase in sea surface temperature (SST) in the GCM because of the different physics involved. In the current climate, CAPE variations in space and time are dominated by regional changes in boundary layer temperature and moisture, which in turn are controlled by SST patterns and large-scale motions. Geographical thermodynamic structure variations in the middle and upper troposphere are smaller because of the canceling effects of adiabatic cooling and subsidence warming in the rising and sinking branches of the Walker and Hadley circulations. In a forced equilibrium global climate change, temperature change is fairly well constrained by the change in the moist adiabatic lapse rate and thus the upper troposphere warms to a greater extent than the surface. For this reason, climate change in CAPE is better predicted by assuming that relative humidity remains constant and that the temperature changes according to the moist adiabatic lapse rate change of a parcel with 80% relative humidity lifted from the surface. The moist adiabatic assumption is not symmetrically applicable to a warmer and colder climate: In a warmer regime moist convection determines the tropical temperature structure, but when the climate becomes colder the effect of moist convection diminishes and the large-scale dynamics and radiative processes become relatively important. Although a prediction based on the change in moist adiabat matches the GCM simulation of climate change averaged over the tropical Pacific basin, it does not match the simulation regionally because small changes in the general circulation change the local boundary layer relative humidity by 1%–2%. Thus, the prediction of regional climate change in CAPE is also dependent on subtle changes in the dynamics.

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Empirical Orthogonal Function Analysis of Wind Vectors over the Tropical Pacific Region

Bulletin of the American Meteorological Society ◽

10.1175/1520-0477(1983)064<0234:eofaow>2.0.co;2 ◽

1983 ◽

Vol 64 (3) ◽

pp. 234-241 ◽

Cited By ~ 63

Author(s):

David M. Legler

Keyword(s):

Empirical Orthogonal Function ◽

Function Analysis ◽

Tropical Pacific ◽

Empirical Orthogonal Function Analysis ◽

Pacific Region ◽

Orthogonal Function ◽

The Tropical Pacific

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Oxygen minimum zones in the tropical Pacific across CMIP5 models: mean state differences and climate change trends

Biogeosciences Discussions ◽

10.5194/bgd-12-6525-2015 ◽

2015 ◽

Vol 12 (8) ◽

pp. 6525-6587 ◽

Cited By ~ 2

Author(s):

A. Cabré ◽

I. Marinov ◽

R. Bernardello ◽

D. Bianchi

Keyword(s):

Climate Change ◽

Tropical Pacific ◽

Cmip5 Models ◽

Upper Ocean ◽

Intermediate Water ◽

Climate Change Projections ◽

Oxygen Minimum Zones ◽

Mean State ◽

Oxygen Minimum ◽

The Tropical Pacific

Abstract. We analyze simulations of the Pacific Ocean oxygen minimum zones (OMZs) from 11 Earth System model contributions to the Coupled Model Intercomparison Project Phase 5, focusing on the mean state and climate change projections. The simulations tend to overestimate the volume of the OMZs, especially in the tropics and Southern Hemisphere. Compared to observations, five models introduce incorrect meridional asymmetries in the distribution of oxygen including larger southern OMZ and weaker northern OMZ, due to interhemispheric biases in intermediate water mass ventilation. Seven models show too deep an extent of the tropical hypoxia compared to observations, stemming from a deficient equatorial ventilation in the upper ocean combined with a too large biologically-driven downward flux of particulate organic carbon at depth, caused by too high particle export from the euphotic layer and too weak remineralization in the upper ocean. At interannual timescales, the dynamics of oxygen in the eastern tropical Pacific OMZ is dominated by biological consumption and linked to natural variability in the Walker circulation. However, under the climate change scenario RCP8.5, all simulations yield small and discrepant changes in oxygen concentration at mid depths in the tropical Pacific by the end of the 21st century due to an almost perfect compensation between warming-related decrease in oxygen saturation and decrease in biological oxygen utilization. Climate change projections are at odds with recent observations that show decreasing oxygen levels at mid depths in the tropical Pacific. Out of the OMZs, all the CMIP5 models predict a decrease of oxygen over most of the surface, deep and high latitudes ocean due to an overall slow-down of ventilation and increased temperature.

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