A preliminary risk assessment of the Australian region power network to space weather

Marshall, R. A.; Smith, E. A.; Francis, M. J.; Waters, C. L.; Sciffer, M. D.

Title: A preliminary risk assessment of the Australian region power network to space weather
Creator: Marshall, R. A.; Smith, E. A.; Francis, M. J.; Waters, C. L.; Sciffer, M. D.
Relation: Space Weather Vol. 9, Issue 10
Publisher Link: http://dx.doi.org/10.1029/2011sw000685
Publisher: American Geophysical Union
Resource Type: journal article
Date: 2011
Description: It is well documented that power networks at high latitudes are vulnerable to the effects of space weather. In recent years the eastern Australia state power networks have been connected across state boundaries in order to improve robustness under increasing load demands and deliver power at competitive prices. However, this interconnectivity is likely to increase susceptibility of the network to space weather. Geomagnetically induced currents (GICs) flow in power transmission lines as the result of “geoelectric” fields and their associated geomagnetic field variations according to Faraday's Law. In this paper previously documented occurrences of GIC activity from regions around the world are investigated and categorized by their effects on nearby power networks. A frequency domain filter that produces an index representing GIC activity is applied to geomagnetic field data recorded at locations near the documented GIC activity to determine risk level “GIC index” thresholds. Geomagnetic field data from the Australian region are processed using the “GIC filter” to provide a preliminary risk assessment of space weather related GIC activity to the Australian power network. The analysis suggests lower limit threshold GIC_y indices of 50, 100, 250, and 600 corresponding to the risk levels of “low,” “moderate,” “high,” and “extreme,” respectively. Analysis of GIC_y indices derived from Australian magnetometer data shows that only southern Australian regions reached the “moderate” risk levels defined in this study with mainland southern Australia stations reaching this risk level twice over the previous two solar cycles. Southern Australian regions such as Tasmania reached moderate levels approximately 20 times during the previous solar cycle. Furthermore, elevated risk levels are typically only observed in Australia during solar maximum and its decline phase.
Subject: geomagnetically induced currents; magnetic fields; space weather; risk assessment; power networks; Australia
Identifier: http://hdl.handle.net/1959.13/1038110
Identifier: uon:13515
Identifier: ISSN:1542-7390
Language: eng
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