Climatology of wind changes and elevated fire danger over Victoria, Australia
Graham Mills A D , Sarah Harris A B , Timothy Brown C and Alex Chen BA School of Earth, Atmosphere and Environment, Monash University, Clayton, Victoria, Australia.
B Fire and Emergency Management, Country Fire Authority, East Burwood, Victoria, Australia.
C Division of Atmospheric Science, Desert Research Institute, Reno, NV, USA.
D Corresponding author. Email: gam4582@gmail.com
Journal of Southern Hemisphere Earth Systems Science 70(1) 290-303 https://doi.org/10.1071/ES19043
Submitted: 12 April 2020 Accepted: 5 August 2020 Published: 8 October 2020
Journal Compilation © BoM 2020 Open Access CC BY-NC-ND
Abstract
Wind changes are a critical factor in fire management, particularly on days of elevated fire danger, and have been shown to be a factor in many firefighter entrapments in Australia and the USA. While there have been numerous studies of frontal wind changes over southeastern Australia since the 1950s, a spatial climatology of wind change strength and frequency over Victoria has hitherto been limited by the relatively low number of observation sites that have both high temporal resolution observations and sufficient length of record. This study used a recently developed high spatial (4-km grid) and temporal (1 hour) resolution, 46-year, homogeneous gridded fire weather climatology data set to generate a climatology of wind change strength by season at each gridpoint across Victoria. The metric used to define a wind change is the vector difference between the wind speed and direction over each 1-hour interval, with the highest value occuring on each day being selected for spatial analysis of strength and frequency. The highest values of wind change strength are found along the crest of the Great Dividing Range (the Great Divide), with a peak in spring. Elsewhere, the highest values occur in summer, with the areas south of the Great Divide, west of Melbourne and in central Gippsland showing higher values than the remainder of the state. The strength of wind changes generally decreases north of the Great Divide, although it is stronger in the northwest of the state in spring rather than in autumn. Lowest summertime (and other seasons) values occur in the northeast of the state and in far-east Gippsland. Exploring the frequencies of days when the highest daily Forest Fire Danger Index and the highest daily wind change strength jointly exceed defined thresholds shows that the northwest of the state has the highest springtime frequencies, whereas the highest autumn frequencies occur west of Melbourne and south of the Great Divide. The highest numbers of joint events in summer (when the greatest frequencies also occur) extend from central Victoria west to the South Australian border, with a secondary maximum in central Gippsland. These analyses offer important information for fire weather forecasters and for fire practitioners when preparing for a fire season or managing a fire campaign (for example, for allocating resources or understanding risks).
Keywords: Australia, bushfires, climatology, extreme weather, fire danger, fire management, firefighter entrapment, Victoria, wind changes.
References
Badlan, R. L., Lane, T. P., Mills, G. A., and Caine, S. (2012). Mesoscale modeling of two ‘drying events’: governing processes and implications for fire danger. Aust. Meteor. Oceanog. J. 62, 143–156.| Mesoscale modeling of two ‘drying events’: governing processes and implications for fire danger.Crossref | GoogleScholarGoogle Scholar |
Berson, F. A., Reid, D. G. and Troup, A. J. (1957). The summer cool change of southeastern Australia. I: General behaviour. Technical Paper No. 8. (CSIRO Division of Meteorological Physics: Mordialloc, Australia). 48pp.
Berson, F. A., Reid, D. G. and Troup, A. J. (1959). The summer cool change of southeastern Australia. II. Effects of differential heating and modification of advective change. Technical Paper No. 9. (CSIRO Division of Meteorological Physics: Mordialloc, Australia). 69 pp.
Bianco, L., Djalalova, I. V., Wilczak, J. M., Cline, J., Calvert, S., Konopleva-Akish, E., Finley, C., and Freedman, J. (2016). A wind energy ramp tool and metric for measuring the skill of numerical weather prediction models. Wea. Forecasting 31, 1157–1177.
| A wind energy ramp tool and metric for measuring the skill of numerical weather prediction models.Crossref | GoogleScholarGoogle Scholar |
Bond, N. A., Mass, C. F., and Overland, J. E. (1996). Coastally trapped wind reversals along the United States west coast during the warm season. Part 1: Climatology and temporal evolution. Mon Wea. Rev. 124, 430–445.
| Coastally trapped wind reversals along the United States west coast during the warm season. Part 1: Climatology and temporal evolution.Crossref | GoogleScholarGoogle Scholar |
Brown, T., Mills, G., Harris, S., Podnar, D., Reinbold, H., and Fearon, M. (2016). A bias corrected WRF mesoscale fire weather dataset for Victoria, Australia 1972-2012. J. South. Hemisph. Earth Syst. Sci. 66, 281–313.
| A bias corrected WRF mesoscale fire weather dataset for Victoria, Australia 1972-2012.Crossref | GoogleScholarGoogle Scholar |
Buckley, A. J. (1992). Fire behaviour and fuel reduction burning: Bemm River wildfire, October 1988. Australian Forestry 55, 135–147.
| Fire behaviour and fuel reduction burning: Bemm River wildfire, October 1988.Crossref | GoogleScholarGoogle Scholar |
Bureau of Meteorology (1984). Report on the meteorological aspects of the Ash Wednesday fires – 16 February 1983. (Bureau of Meteorology: Melbourne Australia). 143 pp.
Bureau of Meteorology (2014). Hazardous Weather Phenomena. Wind Shear. Available at www.bom.gov.au/aviation/knowledge-centre/. [Accessed 7 June 2010].
Case, J. L., Manobianco, J., Lane, J. E., Immer, C. D., and Merceret, F. J. (2004). An objective technique for verifying sea breezes in high-resolution numerical weather prediction models. Wea. Forecasting 19, 690–705.
| An objective technique for verifying sea breezes in high-resolution numerical weather prediction models.Crossref | GoogleScholarGoogle Scholar |
Cheney, P., Gould, J., and McCaw, L. (2001). The dead-man zone — A neglected area of fire fighter safety. Aust. For. 64, 45–50.
| The dead-man zone — A neglected area of fire fighter safety.Crossref | GoogleScholarGoogle Scholar |
Clarke, R. H. (1955). Some observations and comment on the sea breeze. Aust. Meteor. Mag. 11, 47–68.
Clarke, R. H. (1983). Fair weather nocturnal inland wind surges and atmospheric bores: Part 1 Nocturnal wind surges. Aust. Meteor. Mag. 31, 133–145.
Clarke, H., Evans, J. P., and Pitman, A. J. (2013). Fire weather simulation skill by the Weather Research and Forecasting (WRF) model over south-east Australia from 1985 to 2009. Int. J. Wildland Fire 22, 739–756.
| Fire weather simulation skill by the Weather Research and Forecasting (WRF) model over south-east Australia from 1985 to 2009.Crossref | GoogleScholarGoogle Scholar |
Colle, B. A., Mass, C. F., and Ovens, D. (2001). Evaluation of the timing and strength of MM5 and Eta surface trough passages over the eastern Pacific. Wea. Forecasting 16, 553–572.
| Evaluation of the timing and strength of MM5 and Eta surface trough passages over the eastern Pacific.Crossref | GoogleScholarGoogle Scholar |
Country Fire Authority (1999). Reducing the risk of wildfire entrapment. A case study of the Linton Fire. Country Fire Authority Report. (Country Fire Authority: Burwood East, Vic). 16 pp.
Cruz, M. G., Sullivan, A. L., Gould, J. S., Sims, N. C., Bannister, A. J., Hollis, J. J., and Hurley, R. J. (2012). Anatomy of a catastrophic wildfire: The Black Saturday Kilmore East fire in Victoria, Australia. Forest Ecol. Manag. 284, 269–285.
| Anatomy of a catastrophic wildfire: The Black Saturday Kilmore East fire in Victoria, Australia.Crossref | GoogleScholarGoogle Scholar |
Engel, C., Lane, T. P., Reeder, M. J., and Rezny, M. (2013). The meteorology of Black Saturday. Quart. J. Roy. Meteor. Soc 139, 585–589.
| The meteorology of Black Saturday.Crossref | GoogleScholarGoogle Scholar |
Fox-Hughes, P., Harris, R., Lee, G., Grose, M., and Bindoff, N. (2014). Future fire danger climatology for Tasmania, Australia, using a dynamically downscaled regional climate model. Int. J. Wildland Fire 23, 309–321.
| Future fire danger climatology for Tasmania, Australia, using a dynamically downscaled regional climate model.Crossref | GoogleScholarGoogle Scholar |
Garratt, J. R. (1986). Boundary layer effects on cold fronts at a coastline. Bound. Lay. Met. 36, 101–5.
| Boundary layer effects on cold fronts at a coastline.Crossref | GoogleScholarGoogle Scholar |
Garratt, J. R. (1988). Summertime fronts in southeast Australia - Behaviour and low-level structure of main frontal types. Mon. Wea. Rev. 116, 636–649.
| Summertime fronts in southeast Australia - Behaviour and low-level structure of main frontal types.Crossref | GoogleScholarGoogle Scholar |
Garratt, J. R., and Physick, W. L. (1986). Numerical study of atmospheric gravity currents. Part I: Simulations and observations of cold gravity currents. Beitr. Phys. Atmos. 59, 282–300.
Garratt, J. R., and Physick, W. L. (1987). Numerical study of atmospheric gravity currents. Part I: Simulations and observations of cold gravity currents. Beitr. Phys. Atmos. 60, 88–102.
Harris, S., Mills, G., and Brown, T. (2017). Variability and drivers of extreme fire weather in fire-prone areas of southeastern Australia. Int. J. Wildland Fire 26, 177–190.
| Variability and drivers of extreme fire weather in fire-prone areas of southeastern Australia.Crossref | GoogleScholarGoogle Scholar |
Harris, S., and Lucas, C. (2019). Understanding the variability of Australian fire weather between 1973 and 2017. PLoS ONE 14, e0222328.
| Understanding the variability of Australian fire weather between 1973 and 2017.Crossref | GoogleScholarGoogle Scholar | 31536523PubMed |
Harris, S., Mills, G., and Brown, T. (2019). Victorian fire weather trends and variability. In ‘23rd International Congress on Modelling and Simulation, Canberra, ACT, Australia’. Available at https://modsim2019.exordo.com/programme/presentation/590 [Accessed 6 September 2020]
Hart, T., and Mills, G. A. (2019). Abrupt wind speed changes on northern Port Phillip. Bulletin of the Australian Meteorological and Oceanographic Society 32, 10–15.
Huang, X., and Mills, G. (2006a). Objective identification of wind change timing from single station observations. Part 1: Methodology and comparison with subjective wind change timings. Aust. Meteor. Mag. 55, 261–274.
Huang, X., and Mills, G. (2006b). Objective identification of wind change timing from single station observations. Part 2: Towards the concept of a wind change climatology. Aust. Meteor. Mag. 55, 275–288.
Johnson, R. H., Schumacher, R. S., and Ruppert, J. H. (2014). The role of convective outflow in the Waldo Canyon fire. Mon. Wea. Rev. 142, 3061–3080.
| The role of convective outflow in the Waldo Canyon fire.Crossref | GoogleScholarGoogle Scholar |
Kepert, J., Tory, K., Thurston, W., Ching, S., Fawcett, R., and Yeo, C. (2016). Fire escalation by downslope winds. Hazard Note 24, Bushfire and Natural Hazards Cooperative Research Centre. Available at https://www.bnhcrc.com.au/hazardnotes/24 [Accessed 15 September 2020]
Lahaye, S., Sharples, J., Matthews, S., Heemstra, S., Price, O., and Badlan, R. (2018). How do weather and terrain contribute to firefighter entrapments in Australia? Int. J. Wildland Fire 27, 85–98.
| How do weather and terrain contribute to firefighter entrapments in Australia?Crossref | GoogleScholarGoogle Scholar |
Loewe, F. (1945). Frontal hours at Melbourne. R.A.A.F. Weather Research and Development Bulletin 3, 13–19.
Ma, Y., Huang, X., Mills, G. A., and Parkyn, K. (2010). Verification of mesoscale NWP forecasts of abrupt cold frontal wind changes. Wea. Forecasting 25, 93–112.
| Verification of mesoscale NWP forecasts of abrupt cold frontal wind changes.Crossref | GoogleScholarGoogle Scholar |
McArthur, A. G., Cheney, N. P., and Barber, J. (1977). The fires of 12 February 1977 in the western district of Victoria. Joint report by CSIRO Division of Forest Research, Canberra and the Country Fire Authority. (CSIRO Division of Forest Research: Canberra, ACT). 73pp
Mills, G. A. (2002). A case of coastal interaction with a cool change. Aust. Meteor. Mag. 51, 203–221.
Mills, G. A. (2005). On the sub-synoptic scale meteorology of two extreme fire weather days during the Eastern Australian fires of January 2003. Aust. Meteor. Mag. 54, 265–290.
Mills, G. A., and Pendlebury, S. (2003). Processes leading to a severe wind-shear incident at Hobart Airport. Aust. Meteor. Mag. 52, 171–188.
Mills, G. A., and Morgan, E. (2006). The Winchelsea Convergence – using radar and mesoscale NWP to diagnose cool change structure. Aust. Meteor. Mag. 55, 47–58.
Muir, L., and Reeder, M. J. (2010). Idealised modeling of land falling cold fronts. Quart. J. Roy. Meteor. Soc. 136, 2147–2161.
| Idealised modeling of land falling cold fronts.Crossref | GoogleScholarGoogle Scholar |
Page, W. G., Freeborn, P. H., Butler, B. W., and Jolly, W. M. (2019). A review of US wildland firefighter entrapments: trends, important environmental factors and research needs. Int. J. Wildland Fire 28, 551–569.
| A review of US wildland firefighter entrapments: trends, important environmental factors and research needs.Crossref | GoogleScholarGoogle Scholar |
Peace, M., McCaw, L., Kepert, J., Mills, G., and Mattner, T. (2015a). WRF and SFIRE simulations of the Layman fuel reduction burn. Aust. Meteor. Oceanog. J. 65, 302–317.
| WRF and SFIRE simulations of the Layman fuel reduction burn.Crossref | GoogleScholarGoogle Scholar |
Peace, M., Mills, G., Mattner, T., McCaw, L., and Kepert, J. (2015b). Fire-modified meteorology in a coupled fire-atmosphere model. J. Appl. Meteorol. Climatol. 54, 704–720.
| Fire-modified meteorology in a coupled fire-atmosphere model.Crossref | GoogleScholarGoogle Scholar |
Physick, W. L. (1988). Mesoscale modelling of a cold front and its interaction with a diurnally heated land mass. J. Atmos. Sci. 45, 3169–87.
| Mesoscale modelling of a cold front and its interaction with a diurnally heated land mass.Crossref | GoogleScholarGoogle Scholar |
Reeder, M. J. (1986). The interaction of a surface cold front with a prefrontal thermodynamically well-mixed boundary layer. Aust. Meteor. Mag. 34, 137–148.
Reeder, M. J., and Smith, R. K. (1987). A study of frontal dynamics with application to the Australian summertime cool change. J. Atmos. Sci. 44, 687–705.
| A study of frontal dynamics with application to the Australian summertime cool change.Crossref | GoogleScholarGoogle Scholar |
Reeder, M. J., and Smith, R. K. (1998). Mesoscale Meteorology. In ‘Meteorology of the Southern Hemisphere’. (Eds D. Vincent and D. J. Karoly.) pp. 201–242. (American Meteorological Society: Boston, USA). 420pp.
Reeder, M. J., and Tory, K. J. (2005). The effects of the continental boundary layer on the dynamics of fronts in a 2D model of baroclinic instability. II: Surface heating and cooling. Quart. J. Roy. Meteor. Soc. 131, 2409–2429.
| The effects of the continental boundary layer on the dynamics of fronts in a 2D model of baroclinic instability. II: Surface heating and cooling.Crossref | GoogleScholarGoogle Scholar |
Reid, D. (1957). Evening wind surges in South Australia. Aust. Meteor. Mag. 16, 23–32.
Rife, D. L., and Davis, C. A. (2005). Verification of temporal variations in mesoscale numerical wind forecasts. Mon. Wea. Rev. 133, 3368–3381.
| Verification of temporal variations in mesoscale numerical wind forecasts.Crossref | GoogleScholarGoogle Scholar |
Sharples, J. J., McRae, R. H. D., Mills, G. A., and Weber, R. O. (2010). Foehn-like winds and elevated fire danger conditions in southeastern Australia. J. Appl. Meteorol. Climatol. 49, 1067–1095.
| Foehn-like winds and elevated fire danger conditions in southeastern Australia.Crossref | GoogleScholarGoogle Scholar |
Smith, R. K., and Reeder, M. J. (1988). On the movement and low level structure of cold fronts. Mon. Wea. Rev. 116, 1927–1944.
| On the movement and low level structure of cold fronts.Crossref | GoogleScholarGoogle Scholar |
Teague, B., McLeod, R., and Pascoe S. (2010). 2009 Victorian Bushfires Royal Commission. Final report. Parliament of Victoria, Melbourne.
Tory, K. J., and Reeder, M. J. (2005). The effects of the continental boundary layer on the dynamics of fronts in a 2D model of baroclinic instability. I: An insulated lower surface. Quart. J. Roy. Meteor. Soc. 131, 2389–2408.
| The effects of the continental boundary layer on the dynamics of fronts in a 2D model of baroclinic instability. I: An insulated lower surface.Crossref | GoogleScholarGoogle Scholar |
Yarnell Hill Fire Investigation Report Team (2013). Yarnell Hill Fire: June 30, 2013. Serious Accident Investigation Report. (Arizona State Forestry Division, Office of the State Forester: Phoenix, AZ, USA). Available at https://www.documentcloud.org/documents/800042-yarnell-hill-serious-accident-investigation-report.html [Accessed 8 April 2020]