@article {bnh-8288, title = {Interactive influence of ENSO and IOD on contiguous heatwaves in Australia}, journal = {Environmental Research Letters}, year = {2021}, month = {11/2021}, abstract = {

Australian heatwaves have a significant impact on society. Most previous studies focus on understanding them in terms of frequency, duration, intensity, and timing. However, understanding the spatial characteristics of heatwaves, particularly those occurring in contiguous regions at the same time (here referred to as contiguous heatwaves), is still largely unexplored. Here, we analyse changes in spatial characteristics of contiguous heatwaves in Australia during 1958-2020 using observational data. Our results show that extremely large contiguous heatwaves are covering significantly larger areas and getting significantly longer during the recent period (1989/90-2019/20) compared to the historical period (1958/59-1988/89). We also investigated the association of contiguous heatwaves in Australia with interactions of the El Ni{\~n}o{\textendash}Southern Oscillation (ENSO) and Indian Ocean Dipole (IOD) using a large multi-member ensemble of a physical climate model. We found that areal magnitude, total area, median duration, and maximum area of large and extremely large contiguous heatwaves in Australia are significantly higher (lower) during the strong El Ni{\~n}o (Es), strong El Ni{\~n}o co-occurring with strong IOD positive (Es-IPs), and with moderate IOD positive (Es-IPm) (co-occurring strong La Ni{\~n}a with the strong IOD negative (Ls-INs)) seasons relative to the neutral seasons (where both ENSO and IOD are in neutral phase). During the Es, Es-IPm, and Es-IPs seasons, the large-scale physical mechanisms are characterised by anticyclonic highs over the southeast and cyclonic lows over the northwest of Australia, favouring the occurrence and intensification of heatwaves in Australia. These results provide insights into the driving mechanisms of contiguous heatwaves in Australia.

}, keywords = {Climate and Earth system modelling, ENSO, heatwaves, IOD}, doi = {https://doi.org/10.1088/1748-9326/ac3e9a}, url = {https://iopscience.iop.org/article/10.1088/1748-9326/ac3e9a}, author = {P Jyoteeshkumar reddy and Sarah Perkins-Kirkpatrick and Jason J. Sharples} } @article {bnh-7839, title = {Mitigating the effects of severe fire, floods and heatwaves through the improvements of land dryness measures and forecasts - final project report}, number = {646}, year = {2021}, month = {02/2021}, institution = {Bushfire and Natural Hazards CRC}, address = {Melbourne}, abstract = {

This Bushfire and Natural Hazards CRC project, titled Mitigating the effects of severe fires, floods and heatwaves through the improvements of land dryness measures and forecasts, was a partnership with the Bureau of Meteorology, and examined the use of detailed land surface models, satellite measurements and ground-based observations for the monitoring and prediction of landscape dryness. This project addresses a fundamental limitation in our ability to prepare for fires, floods and heatwaves and is directly linked to pre-event planning as well as forecasting of events. The research conducted in the present project solely focuses on the application of soil and land dryness/moisture in the context of fire danger and fire management practices. The lack of focus on flood and heatwave is circumstantial. The research priorities were set and driven by the requirements of the project end-users, all of them from various fire management agencies across Australia. Hence, the end-use interest was solely on the application of the research in fire management. Nevertheless, it is worth pointing that there is a substantial amount of research literature which establishes the importance of soil moisture in flood and heatwave prediction and applications.

Currently, landscape dryness for fire management is estimated in Australia using simple empirical models developed in the 1960s. The most prominent of those used in Australia are the Keetch-Byram Drought Index (KBDI) and the Soil Dryness Index (SDI). An initial study performed as part of this project suggested that analyses of soil moisture can be improved by using physics-based land surface models, remote sensing measurements and data assimilation.

JASMIN prototype

To address this, the present project developed a standalone prototype land surface modelling system, called Joint UK Land Environment Simulator based Australian Soil Moisture Information (JASMIN) to produce daily soil moisture analyses at 5km resolution and 4 soil layers. Verification against ground-based soil moisture observations shows that this prototype system is significantly more skilful than both KBDI and SDI.

Though JASMIN can supplement many applications that require accurate soil moisture estimates, the biggest beneficiary of this new system will be the fire agencies. The soil moisture estimate from the new system provides a robust alternative to the methods currently used in fire prediction. This is evident from the verifications performed against in situ measurements. KBDI and SDI show large errors over regions where they are used operationally. KBDI, for example, has a large wet bias over southern regions that could undermine fire danger ratings. The JASMIN system can produce reliable soil moisture information over a wide range of land-use types, which potentially extends its applicability to other fields as well. Also, JASMIN is shown to have good skill for both surface and deep soil horizons.

JASMIN calibration

To promote an effective adoption of JASMIN in current operational practices, calibration methods were applied to the native JASMIN soil moisture datasets. The key aim of these methods was to calibrate JASMIN outputs in units of moisture excess to moisture deficit values that range from 0{\textendash}200, as required by McArthur{\textquoteright}s Forest Fire Danger Index (FFDI; McArthur, 1967). The calibration offers a simple, faster and cost-effective way to make significant upgrades to the existing operational systems used by fire and other environmental agencies.

The calibration methods applied were minimum-maximum matching, mean-variance matching, and cumulative distribution function matching. The selection of these calibration methods was based on the potential end-user requirement, whether that is to simply replace the legacy systems with a new product with high skill (e.g., minimum-maximum method), or to replace the existing system that captures the temporal variations better while preserving the climatology of the older system (e.g., mean-variance and cumulative distribution function matching). The latter could be useful if existing operating systems are already tuned to offset the bias in the current soil moisture deficit methods.

Improving high spatial resolution mapping

This project also aimed to improve applications such as fire danger mapping that may require soil moisture information at higher spatial resolution due to the large spatial variability of soil moisture in the landscape. A common practice to overcome such a problem is to employ downscaling methods to increase the spatial scale of the product. Recent advances in optical remote sensing have allowed researchers to use different remote sensing products that reflect soil moisture variability as ancillary information. A method based on a {\textquotedblleft}universal triangle{\textquotedblright} concept is used in several previous studies, which establishes a relationship between soil moisture, vegetation index, and surface radiant temperature from optical remote sensing. This project applied three downscaling methodologies: two based on regression and one based on a physics-based approach.

Results from the downscaling methodologies indicate that it is feasible to improve the spatial resolution of JASMIN using all three disaggregating algorithms and preserve the general large-scale spatial structure seen in JASMIN soil moisture estimates. However, the seasonal means obtained at 1 km show that each product displays characteristic soil moisture spatial variability at fine scales. Results from the comparison with ground-based soil moisture measurements indicate that there is no significant degradation of the bias in the three methods when moving to higher spatial resolution.

Predicting live fuel moisture content

Prediction of the moisture status in live fuels is an important gap in current fire management practices which, if filled, can potentially be useful for spatial and temporal assessment of landscape dryness. The final objective of the project was thus to explore the relationship between soil moisture and live fuel moisture content (LFMC) using the datasets from JASMIN and Australian Flammability Monitoring System (AFMS), respectively. The analysis carried out indicates that soil moisture is a leading indicator of LFMC. This project developed a simple yet skilful model to predict live fuel moisture content for the whole of Australia.

The key variable is the 0-350 mm layer soil moisture derived from the JASMIN system. The modelling strategy pursued consists of a linear combination of two sub-models: one to capture the annual cycle and one to capture the daily variations. A time function represents the LFMC annual cycle model. The daily deviations in LFMC are captured by using a linear regression model with 14-day lagged daily deviations in soil moisture as the input. The daily changes in soil moisture are computed by deviations from its annual cycle.

When evaluated over 60 sites, the approach returned an average R2 of 0.64 with normalised root mean square error values of \<25\% at all sites. As researchers were employing a gridded soil moisture product, this strategy facilitates the reconstruction of past events, as well as data gap filling. The lag of 14 days implies a lead time of 14 days for predicting the LFMC. This has significant operational implications, as daily variations in LFMC can be predicted using soil moisture information from JASMIN on a national scale.

JASMIN is currently run as a prototype research system, with soil moisture analysis done only near-real-time. However, JASMIN can be extended to produce both real-time analysis and forecasts. The prognostic mode can provide soil moisture forecasts for up to 10 days. This means a maximum lead time of 24 days can be achieved by utilising soil moisture forecasts.

JASMIN utilisation

A key focus of the project from its inception was to create pathways for easier utilisation of the project deliverables. This is reflected in both the scientific and technical approaches adopted in this project. For example, the calibration of JASMIN to KBDI and SDI was done to facilitate the ready utilisation of JASMIN in the existing operational system. A total of 8 calibrated JASMIN soil dryness products were developed and made available through the Bureau of Meteorology{\textquoteright}s THREDDS server. The JASMIN soil moisture in volumetric units at 4 layers are also provided via the THREDDS server for interested parties to evaluate. The volumetric soil moisture fields from the top two JASMIN layers (0-100 mm and 100-350 mm) are available via AFMS as well.

The datasets on both THREDDS and AFMS are updated near-real-time. There is a continuing interest in the end-user community in utilising JASMIN for various fire management applications. In that respect, JASMIN has been assessed in the Western Australian Department of Biodiversity, Conservation and Attractions study on tall wet forest fuel availability. Tasmania Parks and Wildlife has also been using JASMIN as a decision-support tool to restrict the use of open fires in national parks. Also, JASMIN data were updated specifically to assist with Tasmanian decision-making for 2018-19 seasonal bushfire assessment workshop and preseason consultative committee on fire weather.

The JASMIN system can produce reliable soil moisture estimates over a wide range of land-use types and can support many applications that require accurate soil moisture information. However, there is still scope for improvements to the JASMIN system, whether it be the skill or the scale.

An immediate focus could be the use of data assimilation techniques to improve the skill of JASMIN. Data assimilation allows uncertainties in land surface model soil moisture to be offset to some extent by routinely updating the hydrological conditions using the information provided by observations on state variables used by land surface models. The assimilation of satellite observations is shown to improve the model soil moisture state. In that respect, the use of NASA{\textquoteright}s land information system (LIS) is being evaluated at the Bureau. The LIS is a complex framework that uses extensible interfaces to allow the incorporation of new domains, land surface models, land surface parameters, meteorological inputs, data assimilation and optimisation algorithms. The extensible nature of these interfaces, and the component style specifications of the system, allow rapid prototyping and development of new applications. The JASMIN system can be incorporated within LIS to facilitate the assimilation of various observation types. Further, it can be leveraged to run JASMIN with an enhanced spatial resolution, desirably at 1 km.

}, keywords = {Floods, forecasts, heatwaves, land dryness, measures, mitigation, severe fire}, issn = {646}, author = {Vinod Kumar and Imtiaz Dharssi and Paul Fox-Hughes} } @article {bnh-7834, title = {Modulating influence of drought on the synergy between heatwaves and dead fine fuel moisture content of bushfire fuels in the Southeast Australian region}, journal = {Weather and Climate Extremes}, volume = {31}, year = {2021}, month = {03/2021}, abstract = {

During the 2019-20 summer season, Australia experienced frequent heatwave events with scorching temperatures and massive bushfires with dense smoke. These catastrophic heatwaves and bushfires resulted in huge socio-economic and ecological losses. The frequency and intensity of both heatwaves and bushfires are projected to increase in the future warming world. While considerable effort has been directed at understanding the physical mechanisms of these individual extreme events, an investigation of their interaction is lacking. We focus on the relationship between heatwaves and bushfire fuels by considering dead fine fuel moisture content, a critical factor that regulates the intensity, spread rate and the likelihood of profuse spotting of fires. We investigate the relationship by exploring the statistical correlations between various heatwave characteristics (frequency, duration, magnitude, and amplitude) and mean dead fine fuel moisture content over southeast Australia in the peak heat and fire season. This relationship varies among different heatwave characteristics as well as with regions. The prolonged duration of a heatwave is well associated with dead fine fuel dryness around the southeastern parts of the Southeast Australian region, whereas the hotter heatwave season favours the lower dead fine fuel moisture content over the Northeast parts of the Southeast Australia and central Victorian region. Results also suggest that dead fine fuel moisture content is significantly decreased on heatwave days compared to non-heatwave days. Lastly, we explored the effects of rainfall deficit on the relationship between heatwave and mean dead fine fuel moisture content by splitting the seasons based on the Standard Precipitation Index (SPI). Results show that the correlation strength is both seasonally and regionally dependent.

}, keywords = {Australia, bushfires, Drought, Extreme events, fuel moisture content, heatwaves}, doi = {https://doi.org/10.1016/j.wace.2020.100300}, url = {https://www.sciencedirect.com/science/article/pii/S2212094720303133}, author = {P Jyoteeshkumar reddy and Jason J. Sharples and Sophie Lewis and Sarah Perkins-Kirkpatrick} } @article {bnh-7944, title = {Intensifying Australian heatwave trends and their sensitivity to observational data}, journal = {Earth{\textquoteright}s Future}, year = {2020}, month = {12/2020}, abstract = {

Heatwaves are an accustomed extreme event of the Australian climate, which can cause catastrophic impacts on human health, agriculture, and urban and natural systems. We have analysed the trends in Australia-wide heatwave metrics (frequency, duration, intensity, number, cumulative magnitude, timing, and season duration) across 69 extended summer seasons (i.e., from Nov-1951 to Mar-2020). Our findings not only emphasise that heatwaves are becoming hotter, longer, and more frequent, but also signify that they are occurring with excess heat, commencing much earlier, and expanding their season over many parts of Australia in recent decades. The Australian heatwave trends have strengthened since last observed Australian study was conducted. We also investigated the heatwave and severe heatwave trends at a local city-scale using three different observational products (AWAP and SILO gridded datasets and ACORN_SATV2 station data) over selected time periods (1911-2019, 1911-64, and 1965-2019). Results suggest that heatwave trends are noticeably different amongst the three datasets. However, the results highlight that the severe heatwave cumulative magnitude and their season duration have been increasing significantly in recent decades over Australia{\textquoteright}s southern coastal cities (like Melbourne and Adelaide). The climatological mean of the most heatwave and severe heatwave metrics is substantially higher in recent decades compared to earlier periods across all the cities considered. The findings of our study have significant implications for the development of advanced heatwave planning and adaptation strategies.

}, keywords = {Australia, Climate change, heatwaves, urban}, doi = {10.1002/essoar.10505178.1 }, url = {https://www.essoar.org/doi/10.1002/essoar.10505178.1}, author = {P Jyoteeshkumar reddy and Sarah Perkins-Kirkpatrick and Jason J. Sharples} } @conference {bnh-6408, title = {Denaturalising heatwaves: gendered social vulnerability in urban heatwaves, a review }, booktitle = {Bushfire and Natural Hazards CRC Research Day AFAC19}, year = {2019}, month = {12/2019}, address = {Melbourne}, abstract = {

Heatwaves are dangerous and have killed more people in Australia than all other climate related disasters combined. Urban environments are considered especially vulnerable to heatwaves due to the Urban Heat Island effect. Increasing death rates from heatwaves are predicted to become one of Australia{\textquoteright}s most detrimental impacts of climate change (IPPC 2014) with major implications for emergency services and public policy development. The catastrophic dimensions of heatwave mortality are not spread evenly across society but are concentrated among specific population groups. Older people, especially women, are overrepresented in heatwave related excess mortality statistics internationally. Using a critical perspective, this paper aims to present a literature review exploring current research on social vulnerability of older women during urban heatwaves. It will illustrate how heatwave vulnerability is largely socially constructed through the intersection of deeply entrenched gender inequality with systemic socio-economic disadvantage. The review will highlight the need for heatwave intervention to be guided by a social justice perspective, to avoid older, poorer women becoming the shock absorbers of the climate crisis. This paper is part of my PhD research project at Monash University: {\textquoteleft}Denaturalising heatwaves: gendered social vulnerabilities in urban heatwaves and the use of public cool spaces as a primary heat health measure{\textquoteright}. The research has ethics approval.

}, keywords = {Climate change, deaths, heatwaves, urban, Vulnerability}, url = {https://knowledge.aidr.org.au/resources/australian-journal-of-emergency-management-monograph-series/}, author = {Margareta Windisch} } @article {bnh-5804, title = {Mitigating the effects of severe fires, floods and heatwaves through the improvements of land dryness measures and forecasts - annual report 2018-2019}, number = {507}, year = {2019}, month = {08/2019}, institution = {Bushfire and Natural Hazards CRC}, address = {Melbourne}, abstract = {

The Bushfire and Natural Hazards CRC project titled {\textquotedblleft}Mitigating the Effects of Severe Fires, Floods and Heatwaves through the Improvements of Land Dryness Measures and Forecasts{\textquotedblright} examines the use of detailed land surface models,
satellite measurements and ground-based observations for the monitoring and prediction of landscape dryness. This project will address a fundamental limitation in our ability to prepare for fires, floods and heatwaves and is directly
linked to pre-event planning as well as forecasting of events.

Currently landscape dryness is estimated in Australia using simple empirical models developed in the 1960{\textquoteright}s. The most prominent of those used in Australia are the Keetch-Byram Drought Index (KBDI; Keetch \& Byram 1968) and the Soil Dryness Index (SDI; Mount 1972). An initial study performed as part of this project suggest that analyses of soil moisture can be improved by using physically based land surface models, remote sensing measurements and data assimilation. The project has developed a stand-alone prototype land surface modelling system to produce daily soil moisture analyses at 5km resolution and at 4 soil layers. Verification against ground-based soil moisture observations show that this prototype system is significantly more skilful than both KBDI and SDI.

The present report documents the activities undertaken in 2018-2019. A major focus for the year has been on the downscaling of soil moisture from the JASMIN system, enhancing the spatial resolution from 5 km to 1km. Applications like fire danger mapping may require soil moisture information at higher spatial resolution due to the large spatial variability of soil moisture in the landscape. Another major outcome from the project during this year was the publication of a peerreviewed paper in the highly regarded Agriculture and Forest Meteorology journal.

}, keywords = {Emergency management, fires, Floods, Forecasting, heatwaves, land dryness}, issn = {507}, author = {Vinod Kumar and Paul Fox-Hughes and Imtiaz Dharssi} }