oa Preview Number 133

References

1. Liu, G., 1998, Effect of transmitter current waveform on airborne TEM response: Exploration Geophysics, 29, 35–41.
2. Macnae, J., King, A., Stolz, E., Osmakoff, A., and Blaha, A., 1998, Fast AEM processing and inversion: Exploration Geophysics, 29, 163–169.
3. Macnae, J., 2007, Developments in broadband airborne electromagnetics in the past decade, in Milkereit, B. (ed.), Exploration in the new millennium: Proceedings of Exploration 07, Toronto, 387–400.
4. Raiche, A., 2001, Choosing an AEM system to look for kimberlites – a modelling study: Exploration Geophysics, 32, 1–8.
5. Sattel, D., 2006, A brief discussion of helicopter time-domain EM systems: Proceedings of the Australian Earth Sciences Convention, Melbourne, Australia.
6. Smith R.S., and Lee T.J., 2002, The moments of the impulse response: a new paradigm for the interpretation of transient electromagnetic data: Geophysics, 67, 1095–1103.
7. IAEA, 2003, Guidelines for radioelement mapping using gamma ray spectrometry data, technical report series, no. 1363: International Atomic Energy Agency, Austria.
8. Hofmeyer, G.M., and Affleck, C.A., 1994, Rotating Accelerometer Gradiometer, US Patent 5,357,802.
9. Lee, J.B., Boggs, D.B., Downey, M.A., Maddever, R.A.M., Turner, R.J., and Dransfield, M.H., 2006, First test survey results from the Falcon™ helicopter-borne airborne gravity gradiometer system: Abstracts from Australian Earth Sciences Convention, Melbourne, Australia.
10. Lumley, J.M., White, J.P., Barnes, G., Huang, D., Paik, H.J., and Lane, R.J.L., 2001, A superconducting gravity gradiometer tool for exploration: Gradiometry Workshop, Abstracts from SEG International Exposition and 71st Annual Meeting, San Antonio, USA.
11. Main, B., 2006, Noise Effects on the Resolution of the GEDEX AGG, Abstracts from Australian Earth Sciences Convention, Melbourne, Australia.
12. Metzger, E.H., 1982, Development experience of gravity gradiometer system: IEEE PLANS, 82, 323–332.
13. Nobel Prize for Physics 1997 for development of methods to cool and trap atoms with laser light, awarded to Steven Chu, Claude Cohen-Tannoudji and William D. Phillips: http://nobelprize.org/ nobel_prizes/physics/laureates/1997/.
14. Nobel Prize for Physics 2001 for the achievement of Bose–Einstein condensation in dilute gases of alkali atoms, and for early fundamental studies of the properties of the condensates, awarded to Eric A. Cornell, Wolfgang Ketterle and Carl E. Wieman: http://nobelprise.org/nobel_prizes/physics/laureates/2001/.
15. Thomson, S., 2007, Exploration 07 Presentation: Airborne Geophysics: Evolution and Revolution, Toronto, Canada.
16. Tryggvason, B.V., 2003, High resolution airborne gravity gradiometer based on an orthogonal mass quadrupole: European Geophysical Society, Geophysical Research Abstracts, Vol. 5, 02913.
17. Veryaskin, A.V., 2000, A novel combined gravity and magnetic gradiometer system for mobile applications: Extended Abstracts from SEG International Exposition and 70th Annual Meeting, Calgary, Canada.
18. Allen, S.C.R., and Greenslade, D.J.M. A Spectral Climatology of Australian Tide Gauges, BMRC Research Report, submitted.
19. Cummins, P.R., 2005, Geoscience Australia’s role in the Australian Tsunami Warning System: AusGeo News, 78.
20. Dominey-Howes, D., 2007, Geological and historical records of tsunami in Australia: Marine Geology, 239, 99–123.
21. Dziewonski, A.M., Chou, T.-A., and Woodhouse, J.H., 1981, Determination of earthquake source parameters from waveform data for studies of global and regional seismicity: Journal of Geophysical Research, 86, B4, 2825–2852.
22. Greenslade, D.J.M., Simanjuntak, M.A. Burbidge, D., and Chittleborough, J., 2007, A first-generation real-time forecasting system for the Australian Region: BMRC Research Report No. 126, Bur. Met. Australia.
23. Kikuchi, M., and Kanamori, H., 2003, Note on Teleseismic Body- Wave Inversion Program: http://www.eri.u-tokyo.ac.jp/ETAL/ KIKUCHI/.
24. Lamarche, G., and Lebrun, J-F., 2000, Transition from strike-slip faulting to oblique subduction: active tectonics at the Puysegur Margin, South New Zealand: Tectonophysics, 316, 67–89.
25. Polet, J., Thio, H.K., Earle, P., Cummins, P.R., and Bathgate, J., 2006, Near real-time determination of earthquake source properties and tsunami potential using long period surface waves: Eos Trans. AGU, 87(52), Fall Meet. Suppl., Abstract S13B-0222.
26. Ruff, L.J., Given, J.W., Sanders, C.O., and Sperber, C.M., 1989, Large earthquakes in the Macquarie Ridge complex: transitional tectonics and subduction initiation: Pure Applied Geophysics, 128, 1–2, 72–129.
27. Satake, K., 1987, Inversion of tsunami waveforms for the estimation of a fault heterogeneity: method and numerical experiments: J. Phys. Earth, 35, 241–254.
28. Satake, K., 1995. Linear and nonlinear computations of the 1992 Nicaragua earthquake Tsunami: Pure Appl. Geophys., 144, 455–470.
29. Thio, H. K., Graves, R. W., Somerville, P. G., Sato, T., and Ishii T., 2004, A multiple time window rupture model or the 1999 Chi- Chi earthquake from a combined inversion of teleseismic, surface wave, strong motion, and GPS data: J. Geophys. Res., 109, B08309, doi:10.1029/2002JB002381.
30. Titov, V.V., and C.E. Synolakis, 1998, Numerical Modeling of Tidal Wave Runup: J. Waterw. Port Coast. Ocean Eng, 124(4), 157–171.
31. Tsuboi, S., Abe, K., Takano, K., and Yamanaka, Y., 1995, Rapid determination of Mw from broadband P waveforms: Bulletin of the Seismological Society of America, 85, 2, 606–613.