articolo clark.pdf Key words intraplate seismicity – seismic hazard – Australia – paleoseismology 1. Introduction On the 27th of December 1989 a magnitude ML 5.6 earthquake near Newcastle NSW shat- tered the commonly held view that damaging earthquakes do not occur in Australia. This event resulted in the loss of 13 lives and is, to this time, the most destructive and costly natu- ral disaster to have occurred in Australia (e.g., Sinadinovski et al., 2002, table 3-1). While being the most costly, the Newcastle earthquake was certainly not the first damaging event to affect a populated centre in Australia (e.g., 1954 Adelaide event, McCue, 1975; 1968 Meckering and 1970 Calingiri events, Gordon and Lewis, 1980; 1979 Cadoux event, Lewis et al., 1981). Australian paleoseismology: towards a better basis for seismic hazard estimation Dan Clark (1) and Kevin McCue (2) (1) Geoscience Australia, Canberra, Australia (2) Australian Seismological Centre, Jamison Centre, Australia Abstract Probabilistic seismic hazard analyses in Australia rely fundamentally on the assumption that earthquakes record- ed in the past are indicative of where earthquakes will occur in the future. No attempt has yet been made to assess the potential contribution that data from active fault sources might make to the modelling process, despite suc- cessful incorporation of such data into United States and New Zealand hazard maps in recent years. In this paper we review the limited history of paleoseismological investigation in Australia and discuss the potential contri- bution of active fault source data towards improving our understanding of intraplate seismicity. The availability and suitability of Australian active fault source data for incorporation into future probabilistic hazard models is assessed, and appropriate methodologies for achieving this proposed. Australia experiences an earthquake of suffi- cient magnitude to cause structural damage (M. .5.5) once every two years on average (McCue, 1990). However due to the very clus- tered nature of Australia’s population, and the continent’s large area, most earthquakes are far from populated centres and infrequently cause more than superficial damage. Australia resides within the Indo-Australian plate, and is classified as a Stable Continental Region (SCR) according to the definition of Johnston et al. (1994) – the landmass is largely unaffected by currently active plate boundary processes, and has not been influenced by sig- nificant orogenic or extensional events for tens of millions of years. SCRs worldwide are char- acterised by very low strain rates, and corre- spondingly low levels of seismicity relative to active continental regions and plate margin regions. Such areas account for less than one percent of global moment release (Johnston et al., 1994). Consequently, the larger more dam- aging SRC earthquake events are rare relative to the period of historic observation. This fact poses problems for seismologists undertaking 1087 ANNALS OF GEOPHYSICS, VOL. 46, N. 5, October 2003 Mailing address: Dr. Dan Clark, Geoscience Australia, P.O. Box 378, Canberra ACT 2601, Australia; e-mail: dan.clark@ga.gov.au probabilistic seismic hazard analyses that rely heavily on the assumption that earthquakes recorded in the past are indicative of where earthquakes will occur in the future – such assumptions underpin the earthquake hazard maps used in the Australian Building Code (AS1170.4, 1993). The historic record of 100- 200 years is far too short to accurately reflect the long-term activity on the faults that generate these events (cf. Machette et al., 1993). The problem is compounded when it is considered that the largest, least frequent events dominate the moment budget. Strategies that have been employed to over- come this problem fall into two mutually de- pendant categories: 1) obtaining a better under- standing of the patterns and characteristics of contemporary intraplate seismicity, and 2) extending the historic record by consulting the record of seismicity recorded in the landscape (i.e. paleoseismology). The following sections will examine each of these areas in turn for the Australian context. After a brief introduction to Australian intraplate seismicity and some of its geomorphological ramifications, we present a review of paleoseismological investigation in Australia, and offer a discussion on what has been learnt about Australian seismicity from these studies. The future of active fault source data in providing a better basis for seismic haz- ard assessment in Australia is also discussed. 1.1. Australian intraplate seismicity Earthquakes in Australia have been moni- tored with various degrees of completeness since 1888 when the first seismograph was in- stalled. Figure 1 presents an epicentre map of earthquakes with magnitude M 4 for the pe- riod 1901-2001. The data is from the World Earthquake Database maintained by Geosci- ence Australia with contributions from univer- sity, state and private seismological agencies. The database is probably complete for magni- tude M 6 since 1901, M 5 since 1963 and M 3.2 since 1995. Focal depth control in the database is most- ly poor, ostensibly due to a combination of incompletely characterised earth models, and sparse seismograph density. However, some generalisations may be made. With a few notable exceptions (e.g., McCue and Michael- Lieba, 1993), earthquakes initiate in the depth range two to twenty kilometres. Within the ancient shield areas of Western and South Australia, and the Northern Territory (e.g., the Achaean Yilgarn, Pilbara and Gawler cratons, and the Pine Creek inlier, cf. Palfreyman, 1984) most foci are generally at the shallow end of the range, with some events occurring in the top two kilometres. Two of the larger Australian earthquakes, the 1968 MS 6.8 Meckering event and the 1988 Tennant Creek sequence (see fig. 1 for location) have calculated hypocentral depths of the order of 6 km or less (Langston, 1987; Bowman and Dewey, 1991). Hypocentres are more evenly distributed within the range in the predominantly younger rocks (largely Phanerozoic) of Eastern Australia and in East- ern South Australia. Beyond identification of the depth of the brittle-ductile transition, no attempt has been made to explain these apparently shallow hy- pocentral depths. However, analysis of shallow- crustal stress measurements from across Australia (e.g. Denham et al., 1979, 1981; Den- ham and Windsor, 1991; Hillis et al., 1999; Hillis and Reynolds, 2000), and the propensity for shallow rock failure in mines (Max Lee, Australian Mining Consultants Pty Ltd., per- sonal communication), indicates that in the top several kilometres of crust the maximum prin- cipal stresses are horizontal, of high magnitude, and are coupled with highly deviatoric stress re- gimes. Such conditions are likely to be con- ducive to shallow rupture initiation. Earthquake fault plane solutions construct- ed for a selection of larger events are consis- tent with the stress data, with the majority indicating thrust source mechanisms (Hillis and Reynolds, 2000; Clark and Leonard, 2002; Leonard et al., 2002). Strike-slip mechanisms are locally important in the Flinders Ranges of South Australia, and in Northwest Western Australia. Normal faulting mechanisms are relatively rare; there were two in Southeastern Western Australia (1985 ML 5.4 Norseman event; 2001 ML 5.2 Ravensthorpe event), one in the highlands of Victoria (1966 ML 5.6 Mount 1088 Dan Clark and Kevin McCue Hotham event), and another in central west New South Wales (1996 ML 5.1 Range event). Perhaps the least understood facet of Australi- an earthquakes is their relationship to the geology. Hypocentre precision estimates are to tens of kilo- metres, so earthquake events cannot be confidently assigned to known structures, except where events produce a surface rupture (see Section 1.2). Aus- tralian epicentres were overlain on various geolo- gical and geophysical datasets at a continental scale (McCue et al., 1998) to see if any obvious patterns were evident. The study concluded that no consistent relationships were apparent, which is perhaps not surprising given the complexity of Australian geology and that the earthquake cata- logue contains only forty years of complete data for magnitudes down to five. The possibility that this and other discrepancies are just a function of the short recording period can in part be addressed through paleoseismological investigation. In the next sections we discuss what is known of the geomorphic expression and lon- gevity of features born of earthquake events in Australia. The questions we address are: how much paleoseismological information is currently out there and what is its nature? 1089 Australian paleoseismology: towards a better basis for seismic hazard estimation SA WA NT QLD NSW VIC TAS 4-4.99 5-5.99 >6 Earthquake magnitude Tennant Creek Lort RiverHydenMerredin Meckering Mt Narryer Lake Edgar Cadell Marryat Ck Roopena/ Ash Reef Calingiri Cadoux Ri ve r H uon 0 5 km LAKE PEDDER Deniliquin Echuca RochesterVictoria New South Wales 0 30 km Calcarra 0 400 m Calingiri 3 km0 Cadoux pipeline 0 6 km Meckering 0 5 km Roopena Ash Reef Hyden 0 10 km Lo rt R iv er 5 km0 2 km0 Gosses Bore 3 km0 Tennant CreekLake Surprise MT NARRYER B yro 0 10 km Merredin 0 5 km Mt Lofty/ Flinders Ranges E as te rn H ig hl an ds Fig. 1. Seismicity of Australia, 1900-2002, and recent fault scarps (modified after McCue, 2001). Earthquakes relating to the northern margin of the Australian plate have been removed from the image for clarity. Earthquake magnitudes are presented as ML for M < 6 and MS for M > 6. WA = Western Australia; NT = Northern Territory; QLD = Queensland; SA = South Australia; NSW = New South Wales; VIC = Vic- toria; TAS = Tasmania. 1090 Dan Clark and Kevin McCue T ab le I. S um m ar y ta bl e of h is to ri c su rf ac e ru pt ur es a nd s el ec te d pr e- hi st or ic t ec to ni c sc ar ps f or w hi ch p al eo se is m ol og ic al i nf or m at io n ha s be en ob ta in ed . N ot e th at t he T en na nt C re ek e ve nt o cc ur re d as a s er ie s of t hr ee m ai n ea rt hq ua ke s in a 1 2 h pe ri od , an d ea ch e ve nt i s th ou gh t to h av e pr o- du ce d an in de pe nd en t s ec ti on o f sc ar p (c f. C ro ne e t a l. ,1 99 3) . M ag ni tu de s fo r pr e- hi st or ic e ve nt s ha ve b ee n ca lc ul at ed u si ng th e re la ti on sh ip s of W el ls an d C op pe rs m it h (1 99 4) a nd b as ed o n su rf ac e sc ar p le ng th . Ea rth qu ak e lo ca tio n D at e of Ea rth qu ak e La t Lo ng Ru pt ur e/ fa ul t M ax sc ar p Re ac tiv at io n Se le ct ed re fe re nc es la st ev en t m ag ni tu de le ng th (k m ) he ig ht (m ) hi sto ry (i f k no w n) H is to ri c 1 C ut ch ,I nd ia 18 19 M s 7. 25 -8 .2 5 23 .6 69 .6 > 90 7- 9 Q ui ttm ey er a nd J ac ob (1 97 9) 2 A cc ra ,G ha na 19 39 M 6. 5 5. 2 – 0. 13 9- 17 0. 5 Ya rw oo d an d D os er (1 99 0) 3 C en tra l S ud an ,A fr ic a 19 66 M b 5. 1 12 .6 30 .8 6 0 Q ur es hi a nd S ad ig (1 96 7) 4 M ec ke rin g, W A ,A us tra lia 19 68 M s 6. 8 – 31 .7 11 7. 0 37 2. 5 re ac tiv at es a nc ie nt fa ul t G or do n an d Le w is (1 98 0) 5 C al in gi ri, W A ,A us tra lia 19 70 M b 5. 7 – 31 .1 11 6. 5 3 < 0. 4 re ac tiv at es a nc ie nt fa ul t Le w is e t a l. (1 98 1) 6 C ad ou x, W A ,A us tra lia 19 79 M s 6. 0 – 30 .8 11 7. 2 28 < 1. 4 La ng er e t a l. (1 98 7) 7 G ui ne a, A fr ic a 19 83 M s 6. 2 11 .9 – 13 .5 9 0. 13 M ac he tte e t a l. (1 99 3) 8 M ar ry at C k, SA ,A us tra lia 19 86 M s 5. 8 – 26 .2 13 2. 8 13 0. 9 > 1 ev en t, po ss ib ly re ac tiv at es a nc ie nt fa ul t C ho y an d B ow m an (1 98 9) 9 Te nn an t C k, N T, A us tra lia 19 88 M s 6. 3, 6. 4, 6. 7 – 19 .8 13 4. 0 32 1. 8 2 ev en ts ,p en ul tim at e > 50 k a, C ro ne e t a l. (1 99 3) re ac tiv at es a nc ie nt fa ul t 10 U ng av a, Q ue be c, C an ad a 19 89 M s 6. 3 60 .1 – 73 .6 10 1. 8 re ac tiv at es a nc ie nt fa ul t A da m s et a l. (1 99 1, 19 92 ) 11 K ill ar i ( La tu r) ,I nd ia 19 93 M s 6. 4 18 .1 76 .6 3 < 0. 5 Se eb er e t a l. (1 99 3) Pr e- hi st or ic 12 M ee rs F au lt, U .S .A . 1. 1 ka < 6. 9 34 .8 98 .5 26 -3 7 3. 6 2 ev en ts < 2 ka ,r ea ct iv at es a nc ie nt fa ul t C ro ne a nd L uz a (1 99 0) 13 C he ra w F au lt, U .S .A . < 7. 7 ka 7. 0 38 .3 10 3. 5 44 4. 0 3 ev en ts < 25 k a C ro ne e t a l. (1 99 7) 14 H yd en S ca rp ,W A ,A us tra lia < 30 k a 6. 9 – 32 .5 11 9. 0 35 2. 5 2- 3 ev en ts < 10 0 ka C la rk e t a l. (2 00 1a ); M ik e M ac he tte (p er s. c om m .) 15 Lo rt R iv er S ca rp ,W A ,A us tra lia Q ua te rn ar y 7. 0 – 33 .5 12 1. 3 40 2 Th om (1 97 2) ; M cC ue (1 97 3) 16 M er re di n Sc ar ps ,W A ,A us tra lia Q ua te rn ar y 6. 5 – 31 .6 11 8. 3 16 C hi n (1 98 5) 17 M t. N ar ry er S ca rp s, W A ,A us tra lia 18 85 ? 7. 0 – 26 .5 11 6. 4 43 1. 5- 2 re ac tiv at es a nc ie nt fa ul t W ill ia m s (1 97 9) ; W ill ia m s et a l. (1 98 3) 18 C ad el l F au lt, V IC /N SW ,A us tra lia > 20 k a 7. 1 – 36 .0 14 4. 8 50 3- 10 > 1 ev en t < 65 k a Ti ck le a nd H um ph re ys (1 98 7) ; B ow le r a nd H ar fo rd (1 96 6) 19 La ke E dg ar F au lt, TA S, A us tra lia < 20 k a 6. 8 – 43 .0 14 6. 4 30 5- 7 2 ev en ts < 20 k a, re ac tiv at es M cC ue e t a l. (2 00 3) an ci en t f au lt 20 G el l R iv er F au lt, TA S, A us tra lia Q ua te rn ar y? 6. 2 – 42 .5 14 6. 2 10 M cC ue e t a l. (2 00 3) 21 B ar ro w C re ek ,N T, A us tra lia Q ua te rn ar y 6. 1 – 21 .9 13 4. 3 8 1- 2 C ro ne e t a l. (1 99 7) 22 A vo nm or e/ C am pa sp e Sc ar p, Q ua te rn ar y < 7. 1 – 36 .5 14 4. 8 30 -5 0 2 Ti ck le a nd H um ph re ys (1 98 7) V IC ,A us tra lia 23 Ta tu ra S ca rp ,V IC ,A us tra lia Q ua te rn ar y < 6. 2 – 36 .5 14 5. 3 3- 10 2. 5- 3 Ti ck le a nd H um ph re ys (1 98 7) 24 A sh R ee f S ca rp ,S A ,A us tra lia > 14 0 ka 6. 0 – 32 .6 13 7. 3 7 3- 4 H ut to n et a l. (1 99 4) 25 R oo pe na S ca rp ,S A ,A us tra lia < 30 k a 6. 7 – 32 .6 13 7. 3 24 3- 4 3 ev en ts < 14 0 ka H ut to n et a l. (1 99 4) 26 W ilk at an a Sc ar p, SA ,A us tra lia < 30 k a > 6. 2 – 32 .1 13 8. 0 > 10 2- 3 W ill ia m s (1 97 3) 1.2. Historic fault scarps Seven instrumentally recorded earthquakes in Australia are known to have produced sur- face ruptures (table I). Curiously, all of these earthquakes have occurred in Central and Western Australia, and in the last forty years – there were no documented surface rupturing earthquakes in the period between European settlement in 1788 and the 1968 Meckering earthquake. The magnitude of the earthquakes that pro- duced the seven scarps ranges from ML(I.) 5.6 to MS 6.8 (ML(I.) is a Richter magnitude equi- valent scale based on the felt area or radius of perceptibility, McCue, 1980). Two of these events were smaller than magnitude six, the 1970 ML(I.) 5.6 Calingiri WA earthquake and the 1986 MS 5.8 Marryat Creek SA earthquake. The magnitude of the Calingiri earthquake may be an underestimate because in the early seven- ties there were no wide dynamic range seismo- graphs within 600 km, and all nearby seismo- graphs were saturated. Furthermore, the event occurred at 3:15 a.m. Western Standard Time when most people were asleep, so the radius of perceptibility is probably an underestimate. Its assigned body wave magnitude (mb.) was 5.7. The surface ruptures relating to these events range from 3.5 km to 37 km in length, and 0.4 m to 2.5 m in height. All the scarps have a dom- inant component of reverse displacement, and arcuate thrust geometry (cf. Everingham et al., 1969). In detail, some of the rupture traces are seen to be a composite of thrust and oblique- slip components. For example, the 1979 Cadoux surface rupture comprises northerly oriented thrust segments and easterly oriented strike-slip segments (Lewis et al., 1981). Similar complexi- ty in the Tennant Creek surface rupture has been ascribed to complex interactions between subja- cent fault sets in the subsurface (Crone et al., 1993). The historic and instrumental record sug- gests that there have been at least 14 M > 6 on- shore earthquakes in the last 100 years, yet we know of only seven surface ruptures that can be related to these recorded events. It is suggested that this can to a large degree be related to the sparsely populated nature of Australia – it is very likely that there are more ‘historic’ scarps to be discovered. The largest onshore event to be recorded in Australia, the 1941 Meeberrie WA earthquake of magnitude MS 6.9, is a prime candidate. How recognisable these features may be in the landscape depends upon many factors, including the local rate of degradation of topography. 1.3. Degradation of historic scarps All seven historic Australian surface rup- tures occur in areas with little appreciable re- lief and low rainfall. The topography in the Meckering-Calingiri-Cadoux area comprises a flat to rolling landscape punctuated by low, bare, rounded granite hills. The average annual precipitation is in the order of 400 mm, which occurs mainly in the wintertime as showers as- sociated with frontal systems (Bureau of Meteo- rology, 2001). Agriculture is the main land use in the area, with the result that up to 90% of the ground surface has been cleared of its native vegetation and tilled. In general, the soil profile consists of a thin layer of transported sandy soil overlaying a duricrust layer (dominantly fer- ricrete), which in turn overlays weathered bedrock (Gordon and Lewis, 1980). Without anthropogenic intervention, the scarp preserva- tion potential within this soil profile might be expected to be relatively high, at least on a time-scale of decades. This is certainly the case for the 100 m long section of the 1968 Meckering surface rupture that was fenced off as a geological mon- ument shortly after the event. The original scarp height at this location was in the order of 1.5 m (fig. 2a). Thirty-four years later some of the fine structural detail has been lost, but the scarp remains a remarkable feature in the landscape (fig. 2b). This good state of preservation is in a large part due to the resistant nature of the fer- ricrete horizon defining the scarp at this site. Elsewhere, farming activities, principally plough- ing, have destroyed all evidence for the former existence of the scarp. This is also the case for the Calingiri and Cadoux scarps. The Marryat Creek and Tennant Creek scarps occur in deeply weathered arid lands of 1091 Australian paleoseismology: towards a better basis for seismic hazard estimation very low relief. Bedrock outcrop is very rare. The average annual precipitation is less than 300 mm, most of which is delivered in the summer months during often violent storms (Bureau of Meteorology, 2001). In contrast to the Meckering area, the soil profile in these regions is characterised by up to tens of me- tres of alluvium and colluvium overlying deep- ly weathered bedrock (Coats, 1963; Connor, 1978; Machette et al., 1993). The ground sur- face is sparsely populated with woody herbs and grasses, typically of the genus’ Acacia and Spinifex. During dry periods, over-grazing by cattle and rabbits leaves the ground surface very prone to erosion by wind and during storm e- vents. The scarp preservation potential within this soil profile might be expected to be rela- tively low because of the significant depth to durable bedrock. This suggestion is apparently borne out by repeat topographic data collected from the Marryat Creek scarp in 1986 and 1990. Comprehensive levelling data collected soon after the event in 1986 record a maximum ver- tical offset of 0.9 m (Bowman and Barlow, 1991), whereas four years later a maximum off- set along the same section scarp of only 0.6 m was measured (Machette et al., 1993). Despite this rapid degradation, Machette et al. (1993) reported that scarps, small ground ruptures and other surficial features were still evident along much of the rupture length after 4 years. How- ever, erosion and the action of cattle had de- stroyed most evidence for lateral slip and other fine structural features. A similar intensity of scarp degradation was reported from the Tennant Creek scarp two years after its forma- tion (Crone et al., 1993). Due in large part to extreme remoteness, neither scarp has been vis- ited recently. The above discussion has important impli- cations for where paleoscarps might be pre- served in Australia. In general, the arid regions of Australia are deeply weathered and bedrock is often covered with a significant veneer of unconsolidated sediment. Scarp preservation potential in these areas is low, especially where a significant portion of the local rainfall is delivered by intense storms. The Mount Nar- ryer scarps in Western Australia (fig. 1) may be 1092 Dan Clark and Kevin McCue Fig. 2a,b. Images of a section of the 1968 Meckering scarp, looking south. a) Captured in 1970, and b) cap- tured in May 2002. Scarp preservation has been as- sisted by the durable ferricrete and weathered bedrock layer exposed in the hangingwall. Note the rolling to- pography of farmland in the background. a b a good example. Available evidence suggests that the topographic expression of these scarps has been erased in under one hundred years (see next section for more details; Williams, 1979). That scarps do not appear to be preserved in deeply weathered areas also implies very low long-term slip rates on individual structures, else bedrock would be brought to the surface and tec- tonic relief maintained. In contrast, regions where shallow sediments overly a duricrust and/or bedrock appear to have relatively good scarp preservation potential. The documented occur- rence of paleoscarps in Southern Western Australia (e.g., Lort River, Hyden, Merredin), and on the Eyre Peninsula in South Australia (e.g., Ash Reef, Roopena) supports this observation. 2. Paleoseismological investigations in Australia Figure 1 presents a map of Quaternary and se- lected historic fault scarps that have been investi- gated in more than cursory detail. Characteristics of the activity on each feature are summarised in table I. The first trenching investigation of a sus- pected Quaternary fault in Australia was in 1973 (McCue, 1973). The objective of the study was to determine whether the then recently iden- tified Lort River scarp (Thom, 1972) in West- ern Australia was a fault scarp, or related to flu- vial processes. The investigation arose as part of the considerable interest in determining how common surface ruptures were in Australia fol- lowing the Meckering 1968 surface rupture. Evidence to suggest that the 40 km long and 2 m high Lort River scarp was indeed a fault scarp, and a relatively recent addition to the land- scape, was provided by aerial photography over the area. Several small streams are clearly trun- cated, and have ponded against the scarp. The trench log produced by the study clearly shows that the scarp relates to an easterly-dipping reverse fault with about 2 m of vertical displace- ment (fig. 3; McCue, 1973). The former ground surface, rich in laterite nodules and likely of Tertiary age (cf. Thom et al., 1977), could be traced back under the overthrust block. No attempt was made by the investigators to take samples for dating. However, the thick accumula- tion of unconsolidated fine white sand overlying 1093 Australian paleoseismology: towards a better basis for seismic hazard estimation 1m0 0 1 2 3 4 5 m fine white sand weathered granite zone of weathered laterite nodules fine brown sand scarp line limit of trench see inset present ground surface thrust block colluvial wedge East West possible fault plane Fig. 3. Sketch of the ground profile revealed on the southern wall of a trench excavated across the Lort River Scarp in Western Australia (modified after McCue, 1973). the scarp suggests an age of Late Pleistocene or older. Several years later, two northeasterly trend- ing fault scarps were identified in the Mount Narryer region of Western Australia during routine geological mapping (Williams, 1979; Williams et al., 1983). The westerly scarp is approximately 30 km long and has little associ- ated relief. The easterly scarp is 13 km long and was reported to have a west-side-up relief of around 1.2 m. Both scarps are extremely degrad- ed, and were identified on the basis of the promi- nent vegetation lineaments associated with them. It was originally though that the scarps might relate to the 1941 Meeberrie earthquake as the epicentre for this event occurs less than 50 km to the south west – less than the uncertainty in the epicentre location. However, the results of dendrochronological analysis of Acacia sp. trees growing in colluvium related to the scarp were used as evidence to link the scarps with reports of a significant earthquake which was felt in the Geraldton area in 1885 (Williams, 1979). It has been estimated from felt reports (Everingham and Tilbury, 1972) that the local magnitude of the 1885 event was in the order of 6.5. Because of the sparse population of Western Australia at that time, the epicentral location of the earthquake is very poorly con- strained, so a definitive link cannot be made on seismological grounds. In the early nineties Australia became the target for integrated studies of surface-faulting earthquakes in stable continental regions be- cause half of the known historic cases of sur- face-rupturing earthquakes in such regions of the world have occurred in Australia. As men- tioned in the previous section, investigations were conducted of the surface ruptures produced by the 1988 Tennant creek earthquake sequence (Crone et al., 1993, 1997), the 1986 Marryat Creek event (Machette et al., 1993; Crone et al., 1997), and the 1968 Meckering event (Crone et al., 1997). Some evidence was revealed at the former two localities for pre-historic surface rupturing earthquakes at the site of the historic events. Two trenches excavated across the western arm of the main arcuate Tennant Creek scarp (Crone et al., 1993) revealed the presence of a Late Quaternary scarp buried by aeolian sand deposits. The vertical relief on this prehistoric scarp is at least equal to that of the contemporary scarp at those sites ( 0.8 m), which formed con- sequent to the second earthquake event in the sequence (MS 6.4, Choy and Bowman, 1989). This scarp was not reactivated during the 1988 events, and could not be directly dated. How- ever, thermoluminescence dating of the lower layers of the overlying sand deposits suggests that accumulation of this sediment began ca. 50 ka (Crone et al., 1993; Hutton et al., 1994). Most evidence for prehistoric (Pleistocene) movement on the Marryat Creek scarp has been removed by erosion (Machette et al., 1993). How- ever, trenching revealed that the contemporary scarp exploits a 10-15 m wide zone of pervasive shearing and alteration in the granite bedrock. Only selected planes in this zone were reacti- vated in the 1986 event, suggesting that the earthquake reactivated faults that probably have a long history of recurrent movement. A 2-5 m high linear ridge at the southern end of the scarp may relate to a portion of this postu- lated movement (McCue et al., 1987; Crone et al., 1997). The age of the oldest surficial sed- iments overlying inactive strands of the fault zone, which provide a minimum age for penul- timate surface faulting, was estimated visually to be in the order of 100 ka (Machette et al., 1993; Crone et al., 1997). A cursory investigation of a trench excavated through the Meckering scarp as part of a sympo- sium on «Recent Intraplate Seismicity Studies» (Gregson, 1990) revealed no obvious evidence for earthquake-related features predating the 1968 event (Crone et al., 1997). However, Gordon and Lewis (1980) noted that parts of the 1968 ruptures are marked by abundant quartz fragments, pro- viding circumstantial evidence that the scarps exploit an ancient mineralised fault zone. Further evidence that the scarp follows an ancient line of weakness is provided by the course of the Mortlock River, which has an arcuate shape which parallels the 1968 scarp for 12 km at a dis- tance of about 1.5 km (Gordon and Lewis, 1980). This geometry was established prior to the 1968 surface rupturing event. The Meckering trench was not logged or interpreted. International interest in Australia’s Quaternary fault scarps continued in the late nineties with 1094 Dan Clark and Kevin McCue paleoseismological investigations being conduct- ed over the Hyden scarp in Western Australia, and the Roopena scarp in South Australia (Crone et al., 2003). The detailed results of these studies have not yet been published, but preliminary results of optically stimulated lumi- nescence dating suggest at least two surface faulting earthquakes occurred on the Hyden scarp, at 30 and 50 ka, and three surface fault- ing earthquakes occurred on the Roopena scarp, at 30, 100, and 150-200 ka (Mike Machette, pers. com.). Estimates of 140 ka were made for the age of basal sediments within small scarp-related lakes occurring at the foot of the Roopena scarp (Hutton et al., 1994), which is consistent with the age of the oldest event pos- tulated by Crone et al. (2003). The total vertical displacement across the 30 km long Hyden scarp, distributed amongst the two events, is in the order of 2.5 m. Approximately 3.9 m of ver- tical displacement must be distributed amongst the three postulated Roopena scarp events (cf. Miles, 1952; Dunham, 1992). There is also the suggestion of significant lateral displacement on the 28 km long Roopena scarp. The 30 km long and more than 5 m high Lake Edgar Fault scarp in Southwest Tasmania was identified as a fault scarp in the 1960’s (Carey and Newstead, 1960; fig. 1). The first trench excavat- ed over the scarp was part of an investigation into the feasibility of the Lake Edgar Dam project (Roberts et al., 1975). However, it was not until the nineties that a paleoseismological investiga- tion was conducted (McCue et al., 1996; Van Dissen et al., 1997; McCue et al., 2003). The paleoseismological study re-occupied the original dam project trench, which was excavated near the centre of the scarp where the vertical displace- ment is in the order of 2.5 m. The trench excava- tion provided evidence that the fault had generated at least two surface-faulting earthquakes. Geomor- phological evidence was used to suggest that these events were of Quaternary age, the youngest event having occurred within the last 20.000 years. Each event is associated with a vertical displacement in the order of 2.5 m. An attempt to provide better constraint on the time of faulting using the radio- carbon technique proved unsuccessful. Despite the apparent age of the Lake Edgar scarp, and a high local annual rainfall by Australian standards ( 2000 mm, Bureau of Meteorology, 2001), the feature is still a sharp break in the land surface (McCue et al., 2003). This characteristic can in a large part be attrib- uted to the peat-dominated soils displaced by the faulting (cf. Williams, 1977, Kiernan, 1990). The competence of these materials is demonstrated at the site of the McCue et al. (2003) investigation, where the walls of the 4 m deep trench have remained standing for 30 years, even through the trench is permanently half-filled with water. In mid-2001, a consortium led by Mike Den- tith from the University of Western Australia retrenched the Hyden scarp 4 km to the south of the Crone et al. (2003) trench (Clark et al., 2001a,b). The soil profile at the site of the trench consists essentially of a mantle of aeo- lian sand overlying a ferricrete layer that had been disrupted by reverse faulting (fig. 4). The vertical displacement across the various fault strands depicted in fig. 4 is ~ 2.5 m. It is appar- ent that subsequent to the last faulting event, and prior to the deposition of the sand, the fer- ricrete surface has undergone significant ero- sion. Stratigraphic evidence that might have revealed the number of surface faulting events that the structures in the trench reflect has therefore been removed. However, preliminary optically stimulated luminescence ages on sam- ples from the base of the sand layer suggest that the last faulting event at this locality occurred prior to 90 ka. It is therefore not clear at this early stage of the study how the structures revealed in this trench relate to those exposed in the Crone et al. (2003) trench. There is a wealth of paleoseismological infor- mation yet to be recovered from the geomorpho- logical record of Australia. Many references have been made in Australia’s geologic and geomor- phic literature to post-Tertiary faulting (e.g., Vict- orian scarps, Hills, 1960 – Cadell Scarp, Harris, 1938 and Bowler and Harford, 1964, 1966 – Australian scarps in general, Twidale, 1968 – Wilkatana Scarp and other Flinders Ranges and Mount Lofty Ranges scarps, Williams, 1973 and Sandiford, 2003 – Merredin Scarps, Chin, 1985 – Gell River Fault, Roberts et al., 1975 and Mc- Cue et al., 2003 – Tatura Scarp, Tickell and Humphrys, 1987 – Palmer Fault, Bourman and 1095 Australian paleoseismology: towards a better basis for seismic hazard estimation Lindsay, 1989 – Avonmore Scarp, Cherry and Neivandt, 1995 – Barrow Creek Scarp, Crone et al., 1997). These accounts generally focus on observations of fault scarps, changes in drainage such as ponding against scarps, and stream diver- sion, and make no attempt to associate the fea- tures with pre-historic earthquakes. 3. Discussion: towards a better basis for seis- mic hazard assessment 3.1. What has been learned about Australian seismicity, and surface faulting earthquakes in particular? 3.1.1. Magnitude versus scarp length and height relations The largest known earthquake to produce a sur- face rupture in Australia in historic times was the 1968 MS 6.8 Meckering event, which produced a scarp 37 km long. Similarly, the 1988 MS 6.3-6.7 Tennant Creek events produced approximately 32 km of surface rupture. There are pre-historic scarps yet to be fully characterised that are significantly longer than those produced by historic surface rup- turing earthquakes (up to 50 km, table I), and pre- sumably relate to larger or multiple events. Relationships were developed for estimating the magnitude of pre-historic events based upon the lengths and heights of the seven Australian his- toric scarps (McCue, 1990). Because of the small sample-space these relationships are not statisti- cally robust, and must therefore be treated with caution. However, the McCue (1990) relationships are comparable to similar relationships derived from reverse faults worldwide (e.g., Wells and Coppersmith, 1994; fig. 5, table I), and further- more appear to be indicative of several charac- teristics that distinguish Australian surface rup- tures, or at least those from the central and western regions of Australia. There is some indication that for a given event magnitude, surface ruptures in Western and Central Australia tend to be longer and involve greater dis- placements than those in the world data set. This finding is counter-intuitive, as one might expect that rupture planes in intraplate areas would be compact because of the inherent strength of cold, thick crust. The January 2001 MW 7.6 Bhuj earth- quake is perhaps an extreme example of a compact rupture, being only 40 km long by 36 km deep (Arch Johnston, personal communication). The reason why this might be so has not been studied in detail and is largely beyond the scope of this contribution to answer. However, it is tempting to speculate that a combination of high shear stress at shallow depth (as suggested in Section 1.1) com- bined with the stress regime becoming less com- pressive with depth (there is an indication from in situ stress data that this might be the case, Hillis and Reynolds, 2000; Richard Hillis personal com- munication, 2002), might be responsible. In this scenario, hypocentre nucleation would be favou- red at shallow depth, and downward propagation 1096 Dan Clark and Kevin McCue Fig. 4. Grid map of the ground profile revealed on the southern wall of a trench excavated across the Hyden scarp in Western Australia (after Clark et al., 2001b). of ruptures along a given structure would be hin- dered by a progressively less favourable stress regime. Alternatively, a barrier to downward propagation of a shallowly nucleated rupture might be provided by the gross geological struc- ture. For example, a seismic reflection profile across the seismogenic zone in south western Western Australia (Dentith et al., 2000) revealed that shallowly dipping near-surface structures favourably oriented for failure in the prevailing east-west stress field sole into a sub-horizontal detachment surface at 8 km depth. Because there have been no historic surface ruptures in Eastern Australia it is not possible to estimate the magnitude of the events which formed pre-historic scarps with any confidence. However, if one were to apply magnitude versus rupture length relationships of the kind presented by McCue (1990) and Wells and Coppersmith (1994) to the longest known scarps (e.g., Cadell, Avon- more) events of around magnitude seven, or slight- ly above, are obtained (table I). There are no indi- cations in the known geomorphic record that events of a magnitude discernibly greater than this have occurred. 3.1.2. Reactivation and recurrence Several of the scarps discussed in previous sec- tions preserve evidence for multiple Quaternary displacement episodes (table I). In addition, there is evidence that many historic and pre-historic surface ruptures exploit ancient fault systems, or zones of weakness. The Lake Edgar Fault is per- haps the best example of both these characteristics. Prior to its two Quaternary reverse faulting episodes (McCue et al., 2003) the structure is thought to have been active in the Paleozoic as a strike-slip fault, with more than 12 km of right lateral slip (Carey and Newstead, 1960, Roberts et al., 1975). Similarly, abundant quartz float in the vicinity of the Meckering and Calingiri surface ruptures was taken as evidence that the ruptures occurred along lines of ancient weakness (Gordon and Lewis, 1980). Direct evidence for reactivation was seen in one of the two trenches excavated across the Mar- ryat Creek scarp, where multiple fault strands not activated in the 1986 event were recorded with- in the Proterozoic crystalline bedrock underlying Quaternary sediments (Machette et al., 1993). These older fault strands do not displace the Qua- ternary sediments, and are not associated with sig- nificant relief on the bedrock/sediment interface. An attempt to provide a minimum age for the penultimate event by dating the lowermost Qua- ternary sediments (based upon Ca++ accumu- lation in the soil) produced equivocal results, but with the suggestion that the sediments began accu- mulating in the order of 100 ka. Parts of the 1988 Tennant Creek scarp also show direct evidence for pre-historic surface 1097 Australian paleoseismology: towards a better basis for seismic hazard estimation Fig. 5. Comparison of McCue (1990) and Wells and Coppersmith (1994) relationships tying rupture length ver- sus magnitude and displacement versus magnitude. Note that McCue (1990) uses ML for magnitudes below 6.0, and MS for those above, which approximates MW. A fault dip of 45 degrees was assumed in order to convert dis- placement in the Wells and Coppersmith (1994) relationship to scarp height. Error bars are 2 . faulting. The 0.8 m high buried scarp exposed in two trenches excavated across the western Lake Surprise scarp was interpreted to reflect a reactivation of a pre-existing fault zone (Crone et al., 1993, 1997). Luminescence dating of un- faulted sediments overlying the paleoscarp, sug- gest that it formed more than 50 kyr before the 1988 scarp (Crone et al., 1993). In apparent con- tradiction to the paleoseismological evidence, there is anecdotal historical evidence to suggest that one or two large (M > 6?) earthquakes occurred in the vicinity of Tennant Creek as recently as 1883 (McCue, 2001). However, it is not known whether these events activated parts of the future 1988 scarp, or occurred on another as yet undiscovered fault in the region. Although the data are still few, there appears to be a pattern emerging where surface rupturing earthquakes in Australia occur preferentially on a few pre-existing and often ancient faults. These faults seem to be quiescent for long periods of time between surface rupturing events, in the order of tens of thousands to a hundred thousand years or more (cf. Crone et al., 1993, 1997; Johnston et al., 1994, figs. 4-8). The preliminary data from the Hyden and Roopena scarps (Crone et al., 2003; Mike Machette personal communication, 2002) support this interpretation. The data on reactivation of Australian surface rupturing faults are too few to meaningfully assess whether they demonstrate the successive occurrence of events of similar dis- placement, generating ‘characteristic’ magnitude earthquakes (cf. Schwartz and Coppersmith, 1984). However, paleo- and historic scarps of equal height at Tennant Creek (Crone et al., 1993), and evidence that the two Quaternary events on the Lake Edgar scarp both produced displacements of 2.5 m (McCue et al., 2003), suggest that the concept of ‘characteristic event’ may have some merit in the Australian context. It is noteworthy that while it appears that long time intervals separate surface rupturing earth- quakes Australia-wide, the expression of this seis- micity in the landscape is very different from east to west. Western and Central Australia is char- acterised by very low relief (e.g., fig. 2b) and modest fault scarps that relate to one, or only a few events (e.g., Crone et al., 1993, 1997; Machette et al., 1993; Clark et al., 2001a,b). The indication is that after a limited number of events, the fault systems lock-up and seismicity migrates elsewhere. In contrast, the eastern high- lands in Victoria and New South Wales, and the Mount Lofty and Flinders Ranges regions of South Australia, are characterised by scarps with much greater relief and upon which many events are likely to have occurred (e.g., Twidale, 1968; Tokarev et al., 1998; Sandiford, 2003). This is a fundamental property of Australian seismicity which is yet to be satisfactorily explored. The implications for seismic hazard assessment are obvious, and are further discussed in a follow- ing section. 3.1.3. Segmentation There is no conclusive evidence that Australian intracratonic faults rupture in a segmented fashion. However, several lines of circumstantial evidence, including both geometric/geologic and seismolog- ical arguments, suggest that segmented behaviour may occur on a limited number of fault systems. For example, Crone et al. (1993) postulate that the Tennant Creek Fault System is capable of seg- mented behaviour. These authors suggest that the topographic low known as Lake Surprise, which coincides with an area where the 1988 net cumula- tive offset was small, reflects a segment or rupture boundary in the sub-surface. The discovery of evi- dence for prior surface rupturing on only one part of the 1988 scarp may reflect the postulated seg- mental behaviour. It is noteworthy that the 1970 Calingiri surface rupture occurred 70 km to the northwest of the 1968 Meckering rupture. The dominant structural grain in the area is NW-SE (e.g., Myers and Hocking, 1998; Whitaker and Bastrakova, 2002). Hence, it is conceivable that these localities both occur on a single structural discontinuity, which ruptures in a segmented fashion. A similar pattern is potentially emerging at present from the Cadoux area, 90 km to the northeast of Meckering. Fol- lowing the 1979 Cadoux surface rupture seismici- ty in the area rapidly decayed to a background rate marginally higher than before 1979. This period of relative quiescence was broken in September 2001 by an ML 5.0 earthquake, located less than 30 km to the NW of the Cadoux rupture, again along the regional structural grain (cf. Myers and 1098 Dan Clark and Kevin McCue Hocking, 1998; Whitaker and Bastrakova, 2002). Since that time, over 18.000 earthquakes have been recorded in the area by Geoscience Australia (Leo- nard, 2002). Four of these events have been of magnitude five or greater, but none have produced a known surface rupture. The epicentres of these events describe a trend to the northwest of the September 2001 epicentre, again parallel to the re- gional structural grain. The geometric alignment of discrete pre-his- toric scarps can also be suggestive of segmental rupture behaviour. For example, the Gell River Fault lies 40 km to the north along the strike of the Lake Edgar Fault. The intervening ground is characterised by an abundance of ultramafic rocks, which McCue et al. (2003) postulate may act as a rupture barrier. The authors suggest that this litho- logical boundary could force the Lake Edgar and Gell River faults to rupture independently. In the Echuca area of Northern Victoria exist three collinear but separately mapped faults. South to north they are the Mount Ida./Colbin- abbin, Echuca South and Cadell faults (Bowler and Harford, 1966; Cochrane et al., 1995). The latter two are associated with Quaternary scarps. The Cadell Fault has the larger vertical maximum dis- placement of about 10 m, compared to 3-4 m for the Echuca South scarp. Very little is known about the rupture history of these structures, including whether they rupture independently or together. The difference in scarp height would suggest that the former possibility is typically the case, but simultaneous rupture cannot be excluded. The above discussion provides an indication that fault segmentation is a phenomenon that should be considered in the Australian context. At present the data are too few, and the links too cir- cumstantial, to draw conclusions that may be re- garded with any confidence. 3.2. Comparison of the Australian setting with surface rupturing SCR earthquakes else- where Few SCR faults have been studied in detail, and only eleven worldwide are known to have produced historic surface ruptures, the most recent being the 1993 MW 6.2 Killari (Latur) event in India (table I). Discussions of Australian surface ruptures in the context of known surface ruptures in other SCR regions have been pre- sented by Crone et al. (1993, 1997), Machette et al. (1993) and Johnston et al. (1994). Al- though conclusions are based upon only a few faults, consistent patterns are emerging. Quaternary surface ruptures on SCR faults often exploit ancient faults or fault zones. Paleo- seismological investigations of many Australian fault scarps (table I), the Meers Fault in the U.S.A. (Crone and Luza, 1990), and the Ungava Fault in Canada (Adams et al., 1991, 1992), reveal the presence of pre-existing fault strands that were not activated during the latest surface rupturing event. SCR faults are also characterised by very low long-term slip rates (e.g. Crone et al., 1997) reflecting the low strain rates in SCR crust (Johnston et al., 1994). Evidence from the Meers (e.g., Crone and Luza, 1990) and Cheraw faults (Crone et al., 1997) in the U.S.A. suggest that activity is also highly episodic, with periods of activity numbering one or two events being sep- arated from prior activity by intervals that may be up to 100 kyr or more. The amazing se- quence of three surface rupturing earthquakes in eleven years (1968-1979) in the southwest of Western Australia suggests that episodic activity might also be the norm in Australia. However, more paleoseismological information is required to be confident of this interpretation, as there is some indication, proposed in this review, that faults in Central and Western Aus- tralia are abandoned after one or two surface rupturing events. A characteristic that is particularly pertinent for hazard assessment is that SCR surface rup- turing faults are not typically associated with historic seismicity. The Tennant Creek, Mar- ryat Creek, Ungava and Killari events occurred in areas of low perceived seismic hazard (e.g., GSHAP report, Giardini, 1999), revealing the limitations of relying solely on the record of instrumentally recorded seismicity for hazard assessments. Furthermore, because SCR events are infrequent, and often not flagged by con- temporary seismicity, the populations of SCR regions are generally poorly prepared, so even relatively small events can and have been ex- tremely damaging (e.g., the 1989 Newcastle 1099 Australian paleoseismology: towards a better basis for seismic hazard estimation event and the 1993 Killari event). The hazard is compounded by low attenuation of seismic en- ergy in continental interiors (e.g., Hanks and Johnston, 1992). For example, it has been cal- culated that an earthquake in the New Madrid seismic zone of the Eastern U.S.A. may have up to twenty times the damage area than a compa- rable event in San Francisco (Hamilton and Johnston, 1990). The 2001 MW 7.6 Bhuj event in India acts as a warning for those attempting to reconstruct histories of seismicity on SCR faults from pa- laeoseismological information. That the rupture ensuing from this large event did not break the ground surface, nor even approach within 8-9 km of the surface (Arch Johnston, person- al communication) casts doubt on the validity of all estimates of paleoseismicity based upon fault scarp length and height in SCR regions (cf. McCue, 1990; Wells and Coppersmith, 1994). 3.3. The future: improving seismic hazard assessment The recognition that geologic data from active faults can provide an important input to probabilistic seismic hazard analysis is well established. The current hazard maps for the Western United States (Frankel et al., 1996), and for New Zealand (Stirling et al., 1998, 2002), incorporate 500 and 350 well-quantified active faults as earthquake source zones respec- tively. The Stirling et al. models in particular show an overwhelming dominance of active fault sources over distributed seismicity sources in controlling the hazard for return periods of 475 and 1000 years. The methodology underpinning the incor- poration of geologic data into the hazard mod- elling process is reasonably robust for plate margin areas where slip rates on the major faults are large and the recurrence intervals for significant or ‘characteristic’ (cf. Schwartz and Coppersmith, 1984) events are in the order of hundreds of years. However, applying these methodologies to SCRs, with very low slip rates and return periods on active structures in the tens of thousands of years, has proved more problematic. Several different approaches have been adopted in the Central and Eastern Unit- ed States in order to allow for a contribution to the hazard from active intracratonic faults (e.g., EPRI, 1988; Frankel, 1995; Frankel et al., 1996). In the New Madrid area and the Wabash Valley in Southern Indiana and Illinois, the geometry of faulting is not well characterised and no surface ruptures are known. The recur- rence rates for large events in these areas has been estimated based upon paleoliquefaction studies (e.g., Johnston and Schweig, 1996; Ober- meier et al., 1992), while a characteristic mag- nitude event is derived from historical data (e.g., Johnston, 1996a,b). In the hazard modelling process, rupture areas are synthesised using semi-empirical models and the constraints im- posed by the geologic data. The combination of 500 year recurrence intervals and characteris- tic magnitude events in the order of 7.5 to 8.0 results in these features contributing sig- nificantly to the hazard for the longer return pe- riods (e.g., 1000 and 2500 years, Frankel et al., 1996). Where Holocene fault scarps are known, for example the Meers Fault in Southwestern Oklahoma (cf. Crone and Luza, 1990) and the Cheraw Fault in Eastern Colorado (cf. Crone and Machette, 1995), maximum magnitude events are derived from the fault length using relations such as those of Wells and Copper- smith (1994). Recurrence intervals are based on geologic measurements of slip rates. The recur- rence interval is perhaps the most critical parameter deciding the hazard posed by the ac- tive fault source. For example, the Meers Fault has an estimated return time for its ‘characteris- tic’ event of 4000 years (Crone and Luza, 1990), and so makes very little contribution even to the 2500 year return time hazard (Frankel et al., 1996). The most recent probabilistic seismic haz- ard analysis of the whole Australian continent was published in 1995 (AS1170.4; McCue et al., 1998). This study does not include geo- logic data from active fault sources, and so relies fundamentally on the assumption that the previously recorded distribution of seismicity is indicative of where earthquakes will occur in the future. In Australia, and in other intracra- tonic regions worldwide, this approach has 1100 Dan Clark and Kevin McCue proved to be unreliable for the larger events. This is mainly due to the order of magnitude difference between the time interval separating M > 6 events in a given region compared to the time interval over which seismicity has been recorded. As the database of paleoseismologi- cal information grows in Australia, a critical mass will be reached were active faults sources may be used to enhance probabilistic seismic hazard analyses for long return periods. The data provided in this contribution provides important insight into what data is likely to be available in the Australian context, and what methodologies should be employed to make best use of it for hazard estimation. The most important implications of what we presently know, or can make an educated guess on, are summarised below. In Eastern and Southern Australia, there are many fault scarps of known length and height for which evidence of Quaternary movement has been proposed. Perhaps the most easily quantifiable of these are the faults that bound the Flinders and Mount Lofty Ranges of South Australia (cf. Bourman and Lindsay, 1989; Tokarev et al., 1998; Sandiford, 2003). On these faults, which support displacements of up to several hundred metres, the concept of recur- rence of a characteristic event (cf. Schwartz and Coppersmith, 1984) may be applicable. If slip rates were to be quantified for these structures, thus tying down long-term seismicity rates, the faults themselves may be modelled as earth- quake source zones, as has been done in New Zealand (Stirling et al., 2002) and the United States (Frankel et al., 1996). A similar strategy could be applied to the Lake Edgar scarp in Tasmania (cf. McCue et al., 2003), the Cadell Fault in New South Wales (cf. Bowler and Harford, 1964, 1966), and the many reportedly active faults in Victoria (cf. Hills, 1960). In contrast, the idea of recurrence of a char- acteristic event may not be applicable to scarps in Western and Central Australia. If the indi- cations prove correct, and activity on these scarps is limited to one or two events before the system/segment is abandoned and seismicity migrates elsewhere, it is not appropriate to assign a characteristic magnitude event and use ruptured Quaternary faults themselves as active source zones for hazard assessment. Instead, an alternate approach similar to that used for the New Madrid seismic zone (e.g., Frankel et al., 1996) could be adopted. Rather than incorpo- rating individual fault sources into the hazard framework, average parameters derived from faults in a region of concern could be assigned to synthetic source zones whose geometry is constrained by geologic data. Data from each Quaternary/Holocene fault within the region of concern could contribute towards defining parameters such as the maximum likely magni- tude event for the region (or possibly character- istic event in some cases), typical source zone geometry, patterns of migration in seismicity, re- gional slip rates, and recurrence rates for sur- face rupturing events. These parameters are ob- tainable through paleoseismological investiga- tion and have the potential to place important constraints on probabilistic hazard models. The immediate value of paleoseismological investi- gation in Central and Western Australia will be realised in the development of an understanding of the behaviour of the faults in this large por- tion of Australia. 4. Concluding remarks The review of paleoseismological investiga- tion presented in this contribution provides important insight into the nature of Australian intraplate seismicity, and a guide to how geolog- ic data may be usefully incorporated in future revisions of the Australian seismic hazard map. Perhaps the most important realisation is that the methodologies employed to include active fault source zones into hazard assessment in New Zealand (e.g., Stirling et al., 1998, 2002) and the Western United States (e.g., Frankel et al., 1996) may not be appropriate for the Australian con- text. The limited data available indicate that Aus- tralian active faults are typified by return periods for surface rupturing events in the order of tens of thousands of years or more (cf. Crone et al., 1993, 1997, 2003; Machette et al., 1993). If future investigations confirm this indication, each fault, when considered in isolation, is unlikely to contribute significantly to hazard for normal structures (cf. the Meers Fault, Crone and Luza, 1101 Australian paleoseismology: towards a better basis for seismic hazard estimation 1990). However, if other active faults are pre- sent in a region, as is certainly the case in the Flinders/.Mount Lofty Ranges and in East- ern Australia, then the hazard is proportionately larger. We put forward the hypothesis that the con- cept of recurrence of a ‘characteristic’ magnitude event on a single fault in the western and central parts of Australia may not be applicable, as there is no paleoseismological evidence, nor evidence in the landscape, of more than a couple of surface rupturing events on any given fault. In this con- text, estimates of hazard must be driven by an understanding of the patterns in migration of seis- micity, and on an knowledge of the distribution of potentially seismogenic faults. Faults active in the Quaternary may not themselves contribute to the hazard, but can provide critical information on the long-term character of the seismicity in a region. This information can provide useful con- straints on probabilistic hazard assessments. Paleoseismology is still in its infancy in Aust- ralia. Many instances of known Quaternary faults that could provide valuable information on the character of Australian seismicity have not yet been investigated in detail. Because of the sparse- ly inhabited nature of the Australian continent it is very likely that more Quaternary and younger fault scarps will be found (in spite of high scarp degradation rates over much of arid Australia). Some of these may even relate to historic events. 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