Showing total 20 results

1. Projected wave climate of Bass Strait and south-east Australia by the end of the twenty-first century.

Author

Liu, Jin, Meucci, Alberto, and Young, Ian R.

Subjects

TWENTY-first century, OCEAN waves, CLIMATE change, ROGUE waves, ATMOSPHERIC models

Abstract

A high-resolution third-generation wave model based on unstructured grids, WAVEWATCH III (WW3), was used to study the projected future wave climate of Bass Strait and south-east Australia under two different greenhouse gas emission scenarios (SSP1-2.6 and SSP5-8.5). The wave model, forced with winds from the Australian ACCESS-CM2 Global Climate Model, shows good agreement with coastal long-term buoy observations and an independent WW3 hindcast dataset over the historical period 1985–2014. The projected mean significant wave height ( H s ) for SSP5-8.5 by the end of the twenty-first century (2071–2100) shows a robust increase for the majority of the domain, but a decrease in nearshore regions, mainly due to projected decreases in local wind speed. The increase in H s for SSP1-2.6 is relatively small. Seasonal variations show that H s (SSP5-8.5) is primarily influenced by Southern Ocean swell in spring and winter and local winds prevail in summer and autumn. Hs percentiles show a stronger increase in extreme wave climate for SSP5-8.5 than for SSP1-2.6. Extreme value H s for SSP1-2.6 shows a projected decrease in western regions of the domain and an increase in the east. Extreme value H s for SSP5-8.5 shows a decrease in the nearshore areas of Victoria. This study shows that projected wave climate changes in south-east Australia may have potential implications for Tasmanian and Victorian coastline stability. [ABSTRACT FROM AUTHOR]

Published

2023

2. Future changes in winter explosive cyclones over the Southern Hemisphere domains from the CORDEX-CORE ensemble.

Author

Reboita, Michelle Simões, Crespo, Natália Machado, Torres, Jose Abraham, Reale, Marco, Porfírio da Rocha, Rosmeri, Giorgi, Filippo, and Coppola, Erika

Subjects

ATMOSPHERIC models, CYCLONES, WINTER, BAROCLINICITY, TWENTY-first century

Abstract

Future projections in austral winter characteristics of explosive extratropical cyclones (EECs) in three CORDEX Southern Hemisphere domains (Africa-AFR, Australia-AUS and South America-SAM) are investigated. The projections are obtained with a fine resolution (25 km) Regional Climate Model (RegCM4) within the CORDEX-CORE framework driven by three Global Climate Models (GCMs: HadGEM2-ES, MPI-ESM-MR and NorESM-1 M) under the RCP8.5 scenario. The cyclone database was obtained using a tracking scheme applied to 6-hourly mean sea level pressure fields and EECs are selected using the Sanders and Gyakum criterion. EECs represent ~ 13–17% of the total number of extratropical cyclones during austral winter in the ERA-Interim reanalysis (1995–2014), while both GCMs and RegCM4 ensembles underestimate this percentage. The frequency of EECs is projected to increase in AFR and in SAM domains at the end of the twenty-first century. However, the magnitude of the projected changes needs to be considered with caution because it is smaller than the underestimations in the frequency of EECs of both ensembles in the present climate. EECs in the future will be deeper and faster but with a shorter lifetime. Eady Growth Rate composites, when EECs reach the explosive phase, indicate a less baroclinic large-scale environment in the future. On the other hand, the intensification of precipitation associated with EECs in the future indicates an increase in the contribution of the diabatic processes acting to strengthen the local baroclinicity of the EECs. [ABSTRACT FROM AUTHOR]

Published

2021

3. Estimating present day extreme water level exceedance probabilities around the coastline of Australia: tropical cyclone-induced storm surges.

Author

Haigh, Ivan, MacPherson, Leigh, Mason, Matthew, Wijeratne, E., Pattiaratchi, Charitha, Crompton, Ryan, and George, Steve

Subjects

TROPICAL cyclones, STORM surges, COASTS, WATER levels, PROBABILITY theory, PARAMETER estimation, EROSION, MATHEMATICAL models of oceanography, CLIMATE change

Abstract

The incidence of major storm surges in the last decade have dramatically emphasized the immense destructive capabilities of extreme water level events, particularly when driven by severe tropical cyclones. Given this risk, it is vitally important that the exceedance probabilities of extreme water levels are accurately evaluated to inform risk-based flood and erosion management, engineering and for future land-use planning and to ensure the risk of catastrophic structural failures due to under-design or expensive wastes due to over-design are minimised. Australia has a long history of coastal flooding from tropical cyclones. Using a novel integration of two modeling techniques, this paper provides the first estimates of present day extreme water level exceedance probabilities around the whole coastline of Australia, and the first estimates that combine the influence of astronomical tides, storm surges generated by both extra-tropical and tropical cyclones, and seasonal and inter-annual variations in mean sea level. Initially, an analysis of tide gauge records has been used to assess the characteristics of tropical cyclone-induced surges around Australia. However, given the dearth (temporal and spatial) of information around much of the coastline, and therefore the inability of these gauge records to adequately describe the regional climatology, an observationally based stochastic tropical cyclone model has been developed to synthetically extend the tropical cyclone record to 10,000 years. Wind and pressure fields derived for these synthetically generated events have then been used to drive a hydrodynamic model of the Australian continental shelf region with annual maximum water levels extracted to estimate exceedance probabilities around the coastline. To validate this methodology, selected historic storm surge events have been simulated and resultant storm surges compared with gauge records. Tropical cyclone induced exceedance probabilities have been combined with estimates derived from a 61-year water level hindcast described in a companion paper to give a single estimate of present day extreme water level probabilities around the whole coastline of Australia. Results of this work are freely available to coastal engineers, managers and researchers via a web-based tool (). The described methodology could be applied to other regions of the world, like the US east coast, that are subject to both extra-tropical and tropical cyclones. [ABSTRACT FROM AUTHOR]

Published

2014

4. The CORDEX-Australasia ensemble: evaluation and future projections.

Author

Evans, Jason P., Di Virgilio, Giovanni, Hirsch, Annette L., Hoffmann, Peter, Remedio, Armelle Reca, Ji, Fei, Rockel, Burkhardt, and Coppola, Erika

Subjects

ATMOSPHERIC models, CLIMATE research, CLIMATE change, SEASONS, DOWNSCALING (Climatology)

Abstract

A new regional climate projection ensemble has been created for the Australasia region as part of the World Climate Research Programs Coordinated Regional Downscaling Experiment (CORDEX). The CORDEX-Australasia ensemble is the largest regional climate projection ensemble ever created for the region. It is a 20-member ensemble made by 6 regional climate models downscaling 11 global climate models. Overall the ensemble produces a good representation of recent climate. Consistent biases within the ensemble include an underestimation of the diurnal temperature range and an underestimation of precipitation across much of southern Australia. Under a high emissions scenario projected temperature changes by the end of the twenty-first century reach ~ 5 K in the interior of Australia with smaller increases found toward the coast. Projected precipitation changes are towards drying, particularly in the most populated areas of the southwest and southeast of the continent. The projected precipitation change is very seasonal with summer projected to see little change leaning toward an increase. These results provide a foundation enabling future studies of regional climate changes, climate change impacts, and adaptation options for Australia. [ABSTRACT FROM AUTHOR]

Published

2021

5. Interdecadal changes in Southern Hemisphere winter explosive storms and Southern Australian rainfall.

Author

Osbrough, Stacey L. and Frederiksen, Jorgen S.

Subjects

ATMOSPHERIC circulation, RAINFALL anomalies, TWENTY-first century, DROUGHTS, WEATHER, WINTER storms

Abstract

Interdecadal changes, over the last seventy years, in winter synoptic weather systems that grow and decay in the extratropical storm tracks of the Southern Hemisphere are investigated. The statistics of the intensity of growing and decaying eddies, and their preferred structures and growth rates, are determined from 6-hourly lower-tropospheric reanalysis data for high-pass filtered (period less than 4 days) and band-pass filtered (period between 4 and 8 days) disturbances. A new data-driven methodology is used in which the perturbations are spectrally analysed in both space and time, their growth rates are calculated and statistics are accumulated for growing and decaying instabilities. Rainfall variability in Southern Australia is found to be closely related to the changing statistics of weather system intensity and to interannual and decadal variability in indices or predictors that characterize local, hemispheric or global aspects of the atmospheric circulation. In investigations into the mid-1970s drying of southwestern Western Australia, the Australian Millennium Drought and Southern Australian rainfall anomalies of the early twenty-first century it is found that decadal changes in rainfall are most related to the intensity of the fast growing weather systems. Two new indices, the Subtropical Atmospheric Jet (SAJ) index and the Southern Ocean Regional Dipole (SORD) index, are introduced and shown to have some skill in characterizing aspects of Southern Australian winter rainfall variability particularly on decadal timescales. [ABSTRACT FROM AUTHOR]

Published

2021

6. Realised added value in dynamical downscaling of Australian climate change.

Author

Di Virgilio, Giovanni, Evans, Jason P., Di Luca, Alejandro, Grose, Michael R., Round, Vanessa, and Thatcher, Marcus

Subjects

DOWNSCALING (Climatology), CLIMATE change, ATMOSPHERIC models, CLIMATOLOGY

Abstract

Coarse resolution global climate models (GCMs) cannot resolve fine-scale drivers of regional climate, which is the scale where climate adaptation decisions are made. Regional climate models (RCMs) generate high-resolution projections by dynamically downscaling GCM outputs. However, evidence of where and when downscaling provides new information about both the current climate (added value, AV) and projected climate change signals, relative to driving data, is lacking. Seasons and locations where CORDEX-Australasia ERA-Interim and GCM-driven RCMs show AV for mean and extreme precipitation and temperature are identified. A new concept is introduced, 'realised added value', that identifies where and when RCMs simultaneously add value in the present climate and project a different climate change signal, thus suggesting plausible improvements in future climate projections by RCMs. ERA-Interim-driven RCMs add value to the simulation of summer-time mean precipitation, especially over northern and eastern Australia. GCM-driven RCMs show AV for precipitation over complex orography in south-eastern Australia during winter and widespread AV for mean and extreme minimum temperature during both seasons, especially over coastal and high-altitude areas. RCM projections of decreased winter rainfall over the Australian Alps and decreased summer rainfall over northern Australia are collocated with notable realised added value. Realised added value averaged across models, variables, seasons and statistics is evident across the majority of Australia and shows where plausible improvements in future climate projections are conferred by RCMs. This assessment of varying RCM capabilities to provide realised added value to GCM projections can be applied globally to inform climate adaptation and model development. [ABSTRACT FROM AUTHOR]

Published

2020

7. Trends and projections of Southern Hemisphere baroclinicity: the role of external forcing and impact on Australian rainfall.

Author

Frederiksen, Carsten, Frederiksen, Jorgen, Sisson, Janice, and Osbrough, Stacey

Subjects

STORMS, RAINFALL, CLIMATE change, ANALYSIS of variance, BAROCLINICITY, ATMOSPHERIC models, TRENDS

Abstract

Changes in the characteristics of Southern Hemisphere (SH) storms, in all seasons, during the second half of the twentieth century, have been related to changes in the annual cycle of SH baroclinic instability. In particular, significant negative trends in baroclinic instability, as measured by the Phillips Criterion, have been found in the region of the climatological storm tracks; a zonal band of significant positive trends occur further poleward. Corresponding to this decrease/increase in baroclinic instability there is a decrease/increase in the growth rate of storm formation at these latitudes over this period, and in some cases a preference for storm formation further poleward than normal. Based on model output from a multi-model ensemble (MME) of coupled atmosphere-ocean general circulation models, it is shown that these trends are the result of external radiative forcing, including anthropogenic greenhouse gases, ozone, aerosols and land-use change. The MME is used in an analysis of variance method to separate the internal (natural) variability in the Phillips Criterion from influences associated with anomalous external radiative forcing. In all seasons, the leading externally forced mode has a significant trend and a loading pattern highly correlated with the pattern of trends in the Phillips Criterion. The covariance between the externally forced component of SH rainfall and the leading external mode strongly resembles the MME pattern of SH rainfall trends. A comparison between similar analyses of MME simulations using the second half of the twenty-first century of the Representative Concentration Pathways (RCP) RCP8.5 and RCP4.5 scenarios show that trends in the Phillips Criterion and rainfall are projected to continue and intensify under increasing anthropogenic greenhouse gas concentrations. [ABSTRACT FROM AUTHOR]

Published

2017

8. Using large-scale diagnostic quantities to investigate change in East Coast Lows.

Author

Ji, Fei, Evans, Jason, Argueso, Daniel, Fita, Lluis, and Luca, Alejandro

Subjects

LOWS (Meteorology), ISENTROPIC processes, VORTEX motion, CLIMATE change, WATER security

Abstract

East Coast Lows (ECLs) are intense low-pressure systems that affect the eastern seaboard of Australia. They have attracted research interest for both their destructive nature and water supplying capability. Estimating the changes in ECLs in the future has a major impact on emergency response as well as water management strategies for the coastal communities on the east coast of Australia. In this study, ECLs were identified using two large-scale diagnostic quantities: isentropic potential vorticity (IPV) and geostrophic vorticity (GV), which were calculated from outputs of historical and future regional climate simulations from the NSW/ACT regional climate modelling (NARCliM) project. The diagnostic results for the historical period were evaluated against a subjective ECL event database. Future simulations using a high emission scenario were examined to estimate changes in frequency, duration, and intensity of ECLs. The use of a relatively high resolution regional climate model makes this the first study to examine future changes in ECLs while resolving the full range of ECL sizes which can be as small as 100-200 km in diameter. The results indicate that it is likely that there will be fewer ECLs, with weaker intensity in the future. There could also be a seasonal shift in ECLs from cool months to warm months. These changes have the potential to significantly impact the water security on the east coast of Australia. [ABSTRACT FROM AUTHOR]

Published

2015

9. The role of external forcing in prolonged trends in Australian rainfall.

Author

Frederiksen, Carsten and Grainger, Simon

Subjects

RAINFALL, OCEAN-atmosphere interaction, MATHEMATICAL models of atmospheric circulation, ANTHROPOGENIC effects on nature, ANALYSIS of covariance, CLIMATE change

Abstract

Based on model output from a multi-model ensemble (MME) of coupled atmosphere-ocean general circulation models, it is shown that prolonged trends in Australian rainfall over the southwest during winter and the monsoonal northwest during summer are associated with trends in the large scale Southern Hemisphere circulation. These trends, in turn, are the result of external radiative forcing, including anthropogenic greenhouse gases, ozone, aerosols and land use change. The MME is used in an analysis of covariance method to separate the internal (natural) variability in the coupled rainfall-atmospheric circulation relationship from influences associated with anomalous external radiative forcing. In both seasons, the leading coupled external mode (singular vector) in the twentieth century runs has rainfall and circulation loading patterns with associated time-series that have statistically significant trends. The associated rainfall loading patterns qualitatively resemble the patterns of observed rainfall trends. The circulation loading patterns reflect the thermal expansion of the tropics and the Hadley Cell. A comparison between similar analyses using the second half of the twenty-first century of the representative concentration pathways (RCP) RCP8.5 and RCP4.5 scenarios show that trends in rainfall and the circulation are projected to continue and intensify under increasing anthropogenic greenhouse gas concentrations. The technique developed here is generally applicable to separate the climate change signal from natural variability in any relevant pair of coupled climate fields. [ABSTRACT FROM AUTHOR]

Published

2015

10. The ENSO-Australian rainfall teleconnection in reanalysis and CMIP5.

Author

King, Andrew, Donat, Markus, Alexander, Lisa, and Karoly, David

Subjects

RAINFALL, TELECONNECTIONS (Climatology), THERMODYNAMICS, CLIMATE change, OCEAN-atmosphere interaction, OCEAN temperature

Abstract

Australian rainfall is strongly influenced by El Niño-southern oscillation (ENSO). The relationship between ENSO and rainfall in eastern Australia is non-linear; the magnitude of La Niña events has a greater effect on rainfall than does the magnitude of El Niño events, and the cause of the non-linearity is unclear from previous work. The twentieth century reanalysis succeeds in capturing the asymmetric ENSO-rainfall relationship. In the reanalysis the asymmetry is strongly related to moisture availability in the south-west Pacific whereas wind flow is of less importance. Some global climate models (GCMs) in the coupled model intercomparison project (CMIP5) archive capture the asymmetric nature of the ENSO-rainfall relationship whilst others do not. Differences in thermodynamic processes and their relationships with ENSO are the primary cause of variability in model performance. Analysis of an atmosphere-only run of a GCM which fails to capture the non-linear ENSO-rainfall relationship is also conducted. The atmospheric run forced by observed sea surface temperatures shows no significant improvement in the ENSO-rainfall relationship over the corresponding coupled model run in the CMIP5 archive. This result suggests that some models are failing to capture the atmospheric teleconnection between the tropical Pacific and Australia, and both this and a realistic representation of oceanic ENSO characteristics are required for coupled models to accurately capture the ENSO-rainfall teleconnection. These findings have implications for the study of rainfall projections in the region. [ABSTRACT FROM AUTHOR]

Published

2015

11. Large scale and sub-regional connections in the lead up to summer heat wave and extreme rainfall events in eastern Australia.

Author

Boschat, Ghyslaine, Pezza, Alexandre, Simmonds, Ian, Perkins, Sarah, Cowan, Tim, and Purich, Ariaan

Subjects

HEAT waves (Meteorology), RAINFALL, CLIMATE change, WILDFIRES, OCEAN temperature

Abstract

Australia has been exposed to a vast array of extreme weather regimes over the past few years, and the frequency and intensity of these events are expected to increase as a result of anthropogenic climate change. However, the predictability of extreme droughts, heat waves (HWs), bushfires and floods, is still hampered by our inability to fully understand how these weather systems interact with each other and with the climate system. This study brings new insight into the regional and large scale dynamics of some extreme events in Australia, by describing and comparing the climate signature of summer HWs and extreme rainfall events which have occurred in the states of Victoria and Queensland respectively, during 1979-2013. Our analyses highlight the importance of mid-latitude dynamics operating during HWs, in contrast with more tropical interactions at play during extreme rainfall events. A 'common' blocking high pressure system is observed over the Tasman Sea during the two types of extreme events, and may explain why some southeastern HWs (only about 25 %) occur in close succession with floods in Queensland. However, our results suggest that there is no dynamical link between these two types of events, since the HW-related anticyclone evolves as part of a baroclinic wave train, whereas in the case of rainfall events, this structure emerges as an equivalent barotropic response to tropical convection. Sub-regional surface temperatures and air-sea fluxes also suggest that distinct processes may be operating in the lead up to these two events. Indeed, HWs tend to occur when the wave train propagates from the south Indian to the Pacific Ocean, inducing a quasi-stationary blocking high system over the Tasman Sea. This anticyclonic anomaly can then advect hot dry air towards the southern Victorian coast, where it produces HW conditions. On the other hand, extreme rainfall events mostly occur when the background conditions correspond to a La Niña state. The convection induced in the western Pacific can trigger a tropical-extratropical teleconnection over Queensland. This may generate an anticyclonic anomaly over the Tasman Sea, able to divert air parcels over a warm and humid area where conditions are, this time, favorable for more extreme rainfall along the Queensland coast. [ABSTRACT FROM AUTHOR]

Published

2015

12. Intra-seasonal drivers of extreme heat over Australia in observations and POAMA-2.

Author

Marshall, A., Hudson, D., Wheeler, M., Alves, O., Hendon, H., Pook, M., and Risbey, J.

Subjects

METEOROLOGICAL observations, MADDEN-Julian oscillation, ANTARCTIC oscillation, ANTICYCLONES, CLIMATE change, WEATHER forecasting, HEATING

Abstract

We assess the occurrence and probability of extreme heat over Australia in association with the Southern Annular Mode (SAM), persistent anticyclones over the Tasman Sea, and the Madden-Julian Oscillation (MJO), which have previously been shown to be key drivers of intra-seasonal variations of Australian climate. In this study, extreme heat events are defined as occurring when weekly-mean maximum temperature anomalies exceed the 90th percentile. The observed probability of exceedance is reduced during the positive phase of the SAM and enhanced during the negative phase of the SAM over most of Australia. Persistent anticyclones over the Tasman Sea are described in terms of (1) split-flow blocking at 160°E and (2) high pressure systems located in the vicinity of the subtropical ridge (STRHs), about 10° north of the split-flow blocking region, for which we devise a simple index. Split-flow blocks and STRHs have contrasting impacts on the occurrence of extreme heat over Australia, with STRHs showing enhanced probability of upper decile heat events over southern Australia in all seasons. The observed probability of an upper decile heat event varies according to MJO phase and time of year, with the greatest impact of the MJO on extreme heat occurring over southern Australia (including the Mallee agricultural region) in spring during phases 2-3. We show that this modulation of the probability of extreme heat by the SAM, persistent anticyclones over the Tasman Sea, and the MJO is well simulated in the Bureau of Meteorology dynamical intra-seasonal/seasonal forecast model POAMA-2 at lead times of 2-3 weeks. We further show that predictability of heat extremes increases in association with the negative SAM phase, STRH and MJO, thus providing a basis for skilful intra-seasonal prediction of heat extremes. [ABSTRACT FROM AUTHOR]

Published

2014

13. Simulation and prediction of blocking in the Australian region and its influence on intra-seasonal rainfall in POAMA-2.

Author

Marshall, A., Hudson, D., Hendon, H., Pook, M., Alves, O., and Wheeler, M.

Subjects

RAINFALL, TELECONNECTIONS (Climatology), CLIMATE change, MATHEMATICAL models of oceanography, OCEAN-atmosphere interaction, PREDICTION models, COMPUTER simulation

Abstract

We assess the depiction and prediction of blocking at 140°E and its impact on Australian intra-seasonal climate variability in the Bureau of Meteorology's dynamical intra-seasonal/seasonal forecast model Predictive Ocean Atmosphere Model for Australia version 2 (POAMA-2). The model simulates well the strong seasonality of blocking but underestimates its strength and frequency increasingly with lead time, particularly after the first fortnight of the hindcast, in connection with the model's drifting basic state. POAMA-2 reproduces well the large-scale structure of weekly-mean blocking anomalies and associated rainfall anomalies over Australia; the depiction of total blocking in POAMA-2 may be improved with the reduction of biases in the distribution of Indian Ocean rainfall via a tropical-extratropical wave teleconnection linking blocking activity at 140°E with tropical variability near Indonesia. POAMA-2 demonstrates the ability to skilfully predict the daily blocking index out to 16 days lead time for the ensemble mean hindcast, surpassing the average predictive skill of the individual hindcast members (5 days), the skill obtained from persistence of observed (2 days), and the decorrelation timescale of blocking (3 days). This skilful prediction of the blocking index, together with effective simulation of blocking rainfall anomalies, translates into higher skill in forecasting rainfall in weeks 2 and 3 over much of Australia when blocking is high at the initial time of the hindcast, compared to when the blocking index is small. POAMA-2 is thus capable of providing forecast skill for blocking rainfall on the intra-seasonal timescale to meet the needs of Australian farming communities, whose management practises often rely upon decisions being made a few weeks ahead. [ABSTRACT FROM AUTHOR]

Published

2014

14. Future change of Asian-Australian monsoon under RCP 4.5 anthropogenic warming scenario.

Author

Wang, Bin, Yim, So-Young, Lee, June-Yi, Liu, Jian, and Ha, Kyung-Ja

Subjects

CLIMATE change, MONSOONS, GLOBAL warming, ATMOSPHERIC models, METEOROLOGICAL precipitation

Abstract

We investigate the future changes of Asian-Australian monsoon (AAM) system projected by 20 climate models that participated in the phase five of the Coupled Model Intercomparison Project (CMIP5). A metrics for evaluation of the model's performance on AAM precipitation climatology and variability is used to select a subset of seven best models. The CMIP5 models are more skillful than the CMIP3 models in terms of the AAM metrics. The future projections made by the selected multi-model mean suggest the following changes by the end of the 21st century. (1) The total AAM precipitation (as well as the land and oceanic components) will increase significantly (by 4.5 %/°C) mainly due to the increases in Indian summer monsoon (5.0 %/°C) and East Asian summer monsoon (6.4 %/°C) rainfall; the Australian summer monsoon rainfall will increase moderately by 2.6 %/°C. The 'warm land-cool ocean' favors the entire AAM precipitation increase by generation of an east-west asymmetry in the sea level pressure field. On the other hand, the warm Northern Hemisphere-cool Southern Hemisphere induced hemispheric SLP difference favors the ASM but reduces the Australian summer monsoon rainfall. The combined effects explain the differences between the Asian and Australian monsoon changes. (2) The low-level tropical AAM circulation will weaken significantly (by 2.3 %/°C) due to atmospheric stabilization that overrides the effect of increasing moisture convergence. Different from the CMIP3 analysis, the EA subtropical summer monsoon circulation will increase by 4.4 %/°C. (3) The Asian monsoon domain over the land area will expand by about 10 %. (4) The spatial structures of the leading mode of interannual variation of AAM precipitation will not change appreciably but the ENSO-AAM relationship will be significantly enhanced. [ABSTRACT FROM AUTHOR]

Published

2014

15. Trends in Australian rainfall: contribution of tropical cyclones and closed lows.

Author

Lavender, Sally and Abbs, Deborah

Subjects

RAINFALL, TROPICAL cyclones, SYNOPTIC climatology, LOWS (Meteorology), CLIMATE change

Abstract

Over the past 40 years there have been significant changes in Australian rainfall with increases in the north-west and decreases in the east. Tropical cyclones (TCs) and other closed low pressure systems are important synoptic systems that provide a large proportion of Australia's annual rainfall. This study examines the proportion of rainfall that can be attributed to TCs over the 1970-2009 period, and to TCs combined with other closed lows over the 1989-2009 period. The contribution of these systems to Australian rainfall trends is also analysed. Tropical cyclones are found to have little influence on rainfall trends over the full time period. However, when the more recent 21-year period is considered, TCs and other closed low pressure systems can partially explain the positive rainfall trend in the north-west. Similarly, other closed low pressure systems, such as cut-off lows and east coast lows, can explain some of the negative rainfall trend in the south-east. The contribution of TCs and other closed low pressure systems to rainfall trends in the north and south-east is found to be predominantly due to respective increases and decreases in the rainfall producing efficiency of the systems. An understanding of the influence of these synoptic systems on Australian rainfall in the current climate is vital for evaluating how Australia's water budget may change in future climates. [ABSTRACT FROM AUTHOR]

Published

2013

16. The simulation of cutoff lows in a regional climate model: reliability and future trends.

Author

Grose, Michael, Pook, Michael, McIntosh, Peter, Risbey, James, and Bindoff, Nathaniel

Subjects

SIMULATION methods & models, CLIMATOLOGY, LATITUDE, RAINFALL, GENERAL circulation model, ATMOSPHERIC models

Abstract

Cutoff lows are an important source of rainfall in the mid-latitudes that climate models need to simulate accurately to give confidence in climate projections for rainfall. Coarse-scale general circulation models used for climate studies show some notable biases and deficiencies in the simulation of cutoff lows in the Australian region and important aspects of the broader circulation such as atmospheric blocking and the split jet structure observed over Australia. The regional climate model conformal cubic atmospheric model or CCAM gives an improvement in some aspects of the simulation of cutoffs in the Australian region, including a reduction in the underestimate of the frequency of cutoff days by more than 15 % compared to a typical GCM. This improvement is due at least in part to substantially higher resolution. However, biases in the simulation of the broader circulation, blocking and the split jet structure are still present. In particular, a northward bias in the central latitude of cutoff lows creates a substantial underestimate of the associated rainfall over Tasmania in April to October. Also, the regional climate model produces a significant north-south distortion of the vertical profile of cutoff lows, with the largest distortion occurring in the cooler months that was not apparent in GCM simulations. The remaining biases and presence of new biases demonstrates that increased horizontal resolution is not the only requirement in the reliable simulation of cutoff lows in climate models. Notwithstanding the biases in their simulation, the regional climate model projections show some responses to climate warming that are noteworthy. The projections indicate a marked closing of the split jet in winter. This change is associated with changes to atmospheric blocking in the Tasman Sea, which decreases in June to November (by up to 7.9 m s), and increases in December to May. The projections also show a reduction in the number of annual cutoff days by 67 % over the century, together with an increase in their intensity, and these changes are strongest in spring and summer. [ABSTRACT FROM AUTHOR]

Published

2012

17. An assessment and interpretation of the observed warming of West Antarctica in the austral spring.

Author

Schneider, David, Deser, Clara, and Okumura, Yuko

Subjects

GLOBAL warming, SPRING, EARTH temperature, CLIMATE change, ATMOSPHERIC circulation

Abstract

We synthesize variability and trends in multiple analyses of Antarctic near-surface temperature representing several independent source datasets and spatially complete reconstructions, and place these into the broader context of the behavior of other components of the climate system during the past 30-50 years. Along with an annual-mean trend during the past 50 years of about 0.1°C/decade averaged over Antarctica, there is a distinct seasonality to the trends, with insignificant change (and even some cooling) in austral summer and autumn in East Antarctica, contrasting with warming in austral winter and spring. Apart from the Peninsula, the seasonal warming is largest and most significant in West Antarctica in the austral spring since the late 1970s. Concurrent trends in sea ice are independent evidence of the observed warming over West Antarctic, with the decrease in sea ice area in the Amundsen and Bellingshausen Seas congruent with at least 50% of the inland warming of West Antarctica. Trends in near surface winds and geopotential heights over the high-latitude South Pacific are consistent with a role for atmospheric forcing of the sea ice and air temperature anomalies. Most of the circulation trend projects onto the two Pacific South American (PSA) modes of atmospheric circulation variability, while the Southern Annular Mode lacks a positive trend in spring that would otherwise cause a cooling tendency. The largest circulation trend is associated with the PSA-1 mode, a wave-train extending from the tropics to the high Southern latitudes. The PSA-1 mode is significantly correlated with SSTs in the southwestern tropical and subtropical Pacific. The increased SSTs in this region, together with the observed increase in rainfall, suggest that anomalous deep convection has strengthened or increased the occurrence of the Rossby wave-train associated with PSA-1. This hypothesis is supported by results from two ensembles of SST-forced atmospheric general circulation model simulations. Finally, the implications of the seasonality, timing, and spatial patterns of Antarctic temperature trends with respect to interpreting the relative roles of stratospheric ozone depletion, SSTs and increased atmospheric concentrations of greenhouse gasses are discussed. [ABSTRACT FROM AUTHOR]

Published

2012

18. Erratum to: Australian east coast rainfall decline related to large scale climate drivers.

Author

Speer, Milton, Leslie, Lance, and Fierro, Alexandre

Subjects

RAINFALL, COASTS, CLIMATE change, MAP scales, RELIEF models

Published

2011

19. Diagnosing Australia-Asian monsoon onset/retreat using large-scale wind and moisture indices.

Author

Huqiang Zhang

Subjects

MONSOONS, RAINFALL, ATMOSPHERIC models

Abstract

Using large-scale variables, in this study we have developed a method for defining monsoon onset/retreat in the Australia-Asian region and used this method to study monsoon activities simulated by global climate models. For this purpose, the method needs to capture fundamental characteristics of monsoon rainfall and circulation seasonal variations and at the same time it can be reasonably simulated by current climate models. We develop the method by using both atmospheric precipitable water and wind conditions in our definition and compared our results using 44-year ERA-40 reanalysis data with some published results in the region. Our results offer similar features to several observational studies, including features in Australia-Asian summer monsoon temporal and spatial evolutions and their interannual variations. Results further show that the observed significant increase in summer rainfall in northwest Australia corresponds to earlier onset and much longer duration of its summer monsoon, with its duration significantly increased. Prolonged summer monsoon duration is also seen in central-east China where upward rainfall trend is observed. Furthermore, the Australian summer monsoon appears to be more affected by ENSO than the Asian monsoon, with delayed onsets and shortened durations during El Nino years. Finally, by analyzing results from an IPCC AR4 model, we have shown that using the two large-scale variables simulated by climate models, it is possible to conduct some detailed studies on monsoon activities in current and future climate. Results from this particular model suggest that global warming could potentially modify some of the monsoon characteristics, including earlier onset in most of the region but different features for changes in duration. In the Australian region, it also displays further southward penetration of its summer monsoon. [ABSTRACT FROM AUTHOR]

Published

2010

20. South Australian rainfall variability and climate extremes.

Author

Evans, Alexander D., Bennett, John M., and Ewenz, Caecilia M.

Subjects

RAINFALL, CLIMATE change, PRECIPITABLE water

Abstract

Rainfall extremes over South Australia are connected with broad-scale atmospheric rearrangements associated with strong meridional sea surface temperature (SST) gradients in the eastern Indian Ocean. Thirty-seven years of winter radiosonde data is used to calculate a time series of precipitable water (PW) and convective available potential energy (CAPE) in the atmosphere. Principle component analysis on the parameters of CAPE and PW identify key modes of variability that are spatially and seasonally consistent with tropospheric processes over Australia. The correlation of the leading principle component of winter PW to winter rainfall anomalies reveal the spatial structure of the northwest cloudband and fronts that cross the southern half of the continent during winter. Similarly the second and third principle components, respectively, reveal the structures of the less frequent northern and continental cloudbands with remarkable consistency. 850 hPa-level wind analysis shows that during dry seasons, anomalous offshore flow over the northwest of Australia inhibits advection of moisture into the northwest, while enhanced subsidence from stronger anticyclonic circulation over the southern half of the continent reduces CAPE. This coincides with a southward shift of the subtropical ridge resulting in frontal systems passing well to the south of the continent, thus producing less frequent interaction with moist air advected from the tropics. Wet winters are the reverse, where a weaker meridional pressure gradient to the south of the continent allows rain-bearing fronts to reach lower latitudes. The analysis of SSTs in the Indian Ocean indicate that anomalous warm (cool) waters in the southeast Indian Ocean coincide with a southward (northward) shift in the subtropical ridge during dry (wet) seasons. [ABSTRACT FROM AUTHOR]

Published

2009