School of Earth Sciences - Research Publications

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Type: Journal Article × Start date: 2013 × End date: 2019 × Author: Walsh, Kevin ×

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    Review of tropical cyclones in the Australian region: Climatology, variability, predictability, and trends
    Chand, SS ; Dowdy, AJ ; Ramsay, HA ; Walsh, KJE ; Tory, KJ ; Power, SB ; Bell, SS ; Lavender, SL ; Ye, H ; Kuleshov, Y (WILEY, 2019-01-01)
    Abstract Tropical cyclones (TCs) can have severe impacts on Australia. These include extreme rainfall and winds, and coastal hazards such as destructive waves, storm surges, estuarine flooding, and coastal erosion. Various aspects of TCs in the Australian region have been documented over the past several decades. In recent years, increasing emphasis has been placed on human‐induced climate change effects on TCs in the Australian region and elsewhere around the globe. However, large natural variability and the lack of consistent long‐term TC observations have often complicated the detection and attribution of TC trends. Efforts have been made to improve TC records for Australia over the past decades, but it is still unclear whether such records are sufficient to provide better understanding of the impacts of natural climate variability and climate change. It is important to note that the damage costs associated with tropical cyclones in Australia have increased in recent decades and will continue to increase due to growing coastal settlement and infrastructure development. Therefore, it is critical that any coastal infrastructure planning and engineering decisions, as well as disaster management decisions, strongly consider future risks from tropical cyclones. A better understanding of tropical cyclones in a changing climate will provide key insights that can help mitigate impacts of tropical cyclones on vulnerable communities. An objective assessment of the Australian TCs at regional scale and its link with climate variability and change using improved and up‐to‐date data records is more imperative now than before. This article is categorized under: Paleoclimates and Current Trends > Modern Climate Change
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    Application of a synthetic cyclone method for assessment of tropical cyclone storm tides in Samoa
    McInnes, KL ; Hoeke, RK ; Walsh, KJE ; O'Grady, JG ; Hubbert, GD (SPRINGER, 2016-01)
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    Mediterranean warm-core cyclones in a warmer world
    Walsh, K ; Giorgi, F ; Coppola, E (SPRINGER, 2014-02)
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    Natural hazards in Australia: sea level and coastal extremes
    McInnes, KL ; White, CJ ; Haigh, ID ; Hemer, MA ; Hoeke, RK ; Holbrook, NJ ; Kiem, AS ; Oliver, ECJ ; Ranasinghe, R ; Walsh, KJE ; Westra, S ; Cox, R (SPRINGER, 2016-11)
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    Sensitivity of the distribution of thunderstorms to sea surface temperatures in four Australian east coast lows
    Chambers, CRS ; Brassington, GB ; Walsh, K ; Simmonds, I (SPRINGER WIEN, 2015-10)
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    Tropical cyclones in a regional climate change projection with RegCM4 over the CORDEX Central America domain
    Diro, GT ; Giorgi, F ; Fuentes-Franco, R ; Walsh, KJE ; Giuliani, G ; Coppola, E (SPRINGER, 2014-07)
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    Estimation of the maximum annual number of North Atlantic tropical cyclones using climate models
    Lavender, SL ; Walsh, KJE ; Caron, L-P ; King, M ; Monkiewicz, S ; Guishard, M ; Zhang, Q ; Hunt, B (AMER ASSOC ADVANCEMENT SCIENCE, 2018-08)
    Using millennia-long climate model simulations, favorable environments for tropical cyclone formation are examined to determine whether the record number of tropical cyclones in the 2005 Atlantic season is close to the maximum possible number for the present climate of that basin. By estimating both the mean number of tropical cyclones and their possible year-to-year random variability, we find that the likelihood that the maximum number of storms in the Atlantic could be greater than the number of events observed during the 2005 season is less than 3.5%. Using a less restrictive comparison between simulated and observed climate with the internal variability accounted for, this probability increases to 9%; however, the estimated maximum possible number of tropical cyclones does not greatly exceed the 2005 total. Hence, the 2005 season can be used as a risk management benchmark for the maximum possible number of tropical cyclones in the Atlantic.
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    The role of the SST-thermocline relationship in Indian Ocean Dipole skewness and its response to global warming
    Ng, B ; Cai, W ; Walsh, K (NATURE PORTFOLIO, 2014-08-12)
    A positive Indian Ocean Dipole (IOD) tends to have stronger cold sea surface temperature anomalies (SSTAs) over the eastern Indian Ocean with greater impacts than warm SSTAs that occur during its negative phase. Two feedbacks have been suggested as the cause of positive IOD skewness, a positive Bjerknes feedback and a negative SST-cloud-radiation (SCR) feedback, but their relative importance is debated. Using inter-model statistics, we show that the most important process for IOD skewness is an asymmetry in the thermocline feedback, whereby SSTAs respond to thermocline depth anomalies more strongly during the positive phase than negative phase. This asymmetric thermocline feedback drives IOD skewness despite positive IODs receiving greater damping from the SCR feedback. In response to global warming, although the thermocline feedback strengthens, its asymmetry between positive and negative IODs weakens. This behaviour change explains the reduction in IOD skewness that many models display under global warming.