Abstract
A review of thunderstorm and lightning observations in Australia, with emphasis on studies of their spatial distribution and frequency over the Australian continent, is presented. Long-term thunderday records, lightning data obtained by ground-based lightning detection instruments CIGRE-500 and CGR3 and by NASA satellite-based instruments OTD and LIS have been analyzed to develop maps of total lightning flash density, Nt, (i.e. cloud-to-ground and intracloud) and of ground flash density, Ng. The peak lightning occurrence is in the north-western part of the Australian continent with Nt values up to about 35 km-2yr-1. Ground flash density (Ng) values vary from over 6 km-2yr-1 in the northern parts of Australia to about 1 km-2 yr-1 and below in the southern parts. There are significant seasonal and yearly variations in the frequency of thunderdays. Some aspects of the hazards from thunderstorms and lightning appear to be special to Australia, including lightning initiated wildfires, lightning injuries to telephone users and faults on power lines caused by high wind gust speeds.
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References
Anderson, R. B., and A. J. Eriksson (1980), Lightning parameters for engineering application, Electra, 69, 65–102.
Andrews, C. J., M. A. Cooper, M. Darveniza, and D. Mackerras (1992), Lightning injuries: electrical, medical and legal aspects, CRC Press, Boca Raton, Florida, Appendix 1: Special aspects of telephone mediated lightning injury: an Australian perspective, pp. 163–176.
Anderson, R. B., A. J. Eriksson, H. Kroninger, D. V. Meal, and M. A. Smith (1984), Lightning and thunderstorm parameters, paper presented at IEEE Int. Conf. Lightning and Power Systems, London, UK.
Anderson, R. B., H. R. van Niekerk, S. A. Prentice, and D. Mackerras (1979), Improved lightning flash counter, Electra, 66, 85–98.
Baral, K. N., and D. Mackerras (1992), The cloud flash-to-ground flash ratio and other lightning occurrence characteristics in Kathmandu thunderstorms, J. Geophys. Res., 97, 931–938.
Baral, K. N., and D. Mackerras (1993), Positive cloud-to-ground lightning discharges in Kathmandu thunderstorms, J. Geophys. Res., 98, 10331–10340.
Barham, R. A. (1965), Transistorised lightning flash counter, Electron. Lett., 1, 173.
Barham, R. A., and D. Mackerras (1972), Vertical-aerial CIGRE-type lightning flash counter, Electron. Lett., 8, 480–482.
Boccippio, D. J., K. L. Cummins, H. J. Christian, and S. J. Goodman (2001), Combined satellite- and surface-based estimation of the intracloud-cloud-to-ground lightning ratio over the continental United States, Mon. Wea. Rev., 129, 108–122.
Bunn, C. C. (1968), Application of electric field change measurements to calibration of lightning flash counters, J. Geophys. Res., 73, 1907–1912.
Christian, H. J., K. T. Driscoll, S. J. Goodman, R. J. Blakeslee, D. A. Mach, and D. E. Buechler (1996), The Optical Transient Detector (OTD), paper presented at 10th Int. Conf. on Atmospheric Electricity, Osaka, Japan, 10–14 June.
Christian, H. J., R. J. Blakeslee, S. J. Goodman, D. A. Mach, M. F. Stewart, D. E. Buechler, W. J. Koshak, J. M. Hall, W. L. Boeck, K. T. Driscoll, and D. J. Bocippio (1999), The Lightning Imaging Sensor, paper presented at 11th Int. Conf. on Atmospheric Electricity, Guntersville, Alabama, 7–11 June.
Christian, H. J., R. J. Blakeslee, D. J. Boccippio, W. L. Boeck, D. E. Buechler, K. T. Driscoll, S. J. Goodman, J. M. Hall, W. J. Koshak, D. M. Mach, and M. F. Stewart (2003), Global frequency and distribution of lightning as observed from space by the Optical Transient Detector, J. Geophys. Res., 108(D1), 4005, doi:10.1029/2002JD002347.
Coates, L. (1996), An overview of fatalities from some natural hazards in Australia. Proceedings of NDR96 Conference on Natural Disaster Reduction, Gold Coast, Australia.
Darveniza, M., C. Dunn, and B. Holcombe (2008), A comparison of faults and outages on an electrical distribution system caused by lightning and wind gusts, 29th Int. Conf. on Lightning Protection (ICLP), Uppsala, Sweden, June, paper 6b-2, 6pp.
Farnsworth, N., D. Mackerras, and M. Darveniza (2004), Lightning occurrence in Brisbane, Melbourne and Darwin thunderstorms recorded by CGR4 lightning flash counters, paper presented at Int. Conf. on Storms, Austral. Meteorol. and Oceanographic Soc. and Meteorol. Soc. of New Zealand, Brisbane, Australia, 5–9 July.
GPATS website, www.gpats.com.au
Huschke, R. E. (Ed.) (1959), Glossary of meteorology, 638pp., Am. Meteorol. Soc., Boston, Massachusetts.
Insurance Council of Australia (2000), Risk Zone Accumulation Guide, Appendix F.
Intergovernmental Panel on Climate Change (IPCC) (2007), Climate Change 2007, the Fourth Assessment Report, WMO and UNEP, Geneva, Switzerland.
Jayaratne, E. R., and Y. Kuleshov (2006), The relationship between lightning activity and surface wet bulb temperature, Meteorol. Atmos. Phys., 91, 17–24, doi:10.1007/s00703-004-0100-0.
Kattron website, www.lightning.net.au
Kotaki, M., I. Kuriki, C. Katoh, and H. Sugiuchi (1981), Global distribution of thunderstorm activity observed with ISS-b, J. Radio Res. Lab. Japan, 28, 48–71.
Kuleshov, Y., G. de Hoedt, W. Wright, and A. Brewster (2002), Thunderstorm distribution and frequency in Australia, Aust. Meteorol. Mag., 51, 145–154.
Kuleshov, Y., and E. R. Jayaratne (2004), Estimates of lightning ground flash density in Australia and its relationship to thunder-days, Aust. Meteorol. Mag., 53, 189–196.
Kuleshov, Y., D. Mackerras, and M. Darveniza (2006), Spatial distribution and frequency of lightning activity and lightning flash density maps for Australia. J. Geophys. Res., 111, D19105, doi:10.1029/2005JD006982.
Lightning Protection (2007), Australian Standard/New Zealand Standard 1768–2007, 188pp., Standards Australia, Sydney, Australia and Standards Association of New Zealand, Wellington, New Zealand.
Mackerras, D. (1978), Prediction of lightning incidence and effects in electrical systems, Electr. Eng. Trans., Inst. Eng. Aust., EE-14, 73–77.
Mackerras, D. (1985), Automatic short-range measurement of the cloud flash to ground flash ratio in thunderstorms, J. Geophys. Res. 90, 6195–6201.
Mackerras, D., and M. Darveniza (1992), Design and performance of CGR3 instruments for measuring the cloud flash-to-ground flash ratio in thunderstorms, Internal Report EE92/2, 99pp., Univ. of Queensland, St. Lucia, Australia.
Mackerras, D., and M. Darveniza (1994), Latitudinal variation of lightning occurrence characteristics, J. Geophys. Res. 99, 10813–10821.
Mackerras, D., M. Darveniza, R. E. Orville, E. R. Williams, and S. J. Goodman (1998), Global lightning: total, cloud and ground flash estimates, J. Geophys. Res., 103,19791–19809.
Mushtak, V., E. Williams, and D. Boccippio (2005), Latitudinal variations of cloud base height and lightning parameters in the tropics, Atmos. Res., 76, 222–230.
Natural Disasters in Australia (1985), Proc. 9th Symp. Australian Academy of Technological Sciences, Sydney, 16/17 October 1985, 373pp, AATSE, Melbourne, Australia.
Orville, R.E., and W. Spencer (1979), Global lightning flash frequency, Mon. Wea. Rev., 107, 934–943.
Pierce, E. T. (1956), The influence of individual variations in the field changes due to lightning discharges upon the design and performance of lightning flash counters, Archiv für Meteorologie, Geophysik und Bioclimatologie, Serie A: Meteorologie Und Geophysik, Band 9, 78–86.
Prentice, S. A. (1972a), CIGRE Lightning flash counter. Part 1 Specification. Part 2 Guide for estimating ground flash density CIGRE lightning flash counter, Electra, 22, 149–171.
Prentice S. A. (1972b), Lightning fatalities in Australia, Elec. Eng. Trans. Inst. Eng. Aust., EE8, September, 55–63.
Prentice, S. A., and D. Mackerras (1969), Recording range of a lightning flash counter, Proc. Inst. Elect. Eng. (London), 116, 294–302.
Rutledge S. A., E. R. Williams, and T. D. Keenan (1992), The Down Under Doppler and Electricity Experiment (DUNDEE): Overview and Preliminary results, Bull. Am. Meteorol. Soc., 73(1), 3–15.
Williams, E. R. (1992), The Schumann resonance: A global tropical thermometer, Science, 256, 1184–1187.
Williams, E. R. (1995), Meteorological aspects of thunderstorms, in Handbook of Atmospheric Electrodynamics, edited by H. Volland, pp. 27–60, CRC Press, London, UK.
Williams, E. R., S. A. Rutledge, S. G. Geotis, N. Renno, E. Rasmussen, and T. Rickenbach (1992), A radar and electrical study of tropical “hot towers”, J. Atmos. Sci., 49, 1386–1395.
Williams, E., and S. Stanfill (2002), The physical origin of the land-ocean contrast in lightning activity, C. R.-Acad. Sci. Phys., 3, 1277–1292.
Williams, E., V. Mushtak, D. Rosenfeld, S. Goodman, and D. Boccippio (2005), Thermodynamic conditions favorable to superlative thunderstorm updraft, mixed phase microphysics and lightning flash rate, Atmos. Res., 76, 288–306.
World Meteorological Organization (WMO) (1953), World distribution of thunderstorm days. Part 1: Tables. WMO Publ. 21, TP 6, WMO, Geneva, Switzerland.
Zhou, Y., and M. Darveniza (1994), Lightning initiated fires – the energy absorbed by fibrous materials from impulse current arcs, J. Geogphys. Res. Atmos., 99, 10663–10670.
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Kuleshov, Y., Mackerras, D., Darveniza, M. (2009). Spatial Distribution and Frequency of Thunderstorms and Lightning in Australia. In: Betz, H.D., Schumann, U., Laroche, P. (eds) Lightning: Principles, Instruments and Applications. Springer, Dordrecht. https://doi.org/10.1007/978-1-4020-9079-0_8
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