Modeling Geomagnetically Induced Currents in Australian Power Networks Using Different Conductivity Models

Marshall, R. A.; Wang, L.; Paskos, Garrick; Olivares‐Pulido, Germán; Walt, T. Van Der; Ong, C. M.; Mikkelsen, D. R.; Hesse, G.; McMahon, B. E.; Wyk, E. Van; Иванович, Готман Владимир; Spoor, D.; Taylor, C.E.; Yoshikawa, Akimasa

doi:10.1029/2018sw002047

Cited by 30 publications

(43 citation statements)

References 66 publications

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“…Recent integrations have brought this theory into quantitative focus. Three separate factors are important (e.g., Blake et al, ; Lucas et al, ; Mac Manus et al, ; Marshall et al, ; Torta et al, ): (1) the localized details of geomagnetic vector disturbance responsible for the induction in the Earth, (2) the geographic expression of the Earth's surface impedance tensor, giving the frequency dependent relationship between the inducing geomagnetic disturbance and the induced geoelectric field, and (3) the topology of the conducting network, since geomagnetically induced voltage is determined by the integrated projection of the geoelectric field onto line segments connecting grounding points. A conspiracy of these factors together allowed the magnetic storm of May 1921 to adversely impact the telephone and telegraph networks of New York, some of which were either colocated with or used to support the operation of train systems.…”

Section: Timeline and Geography Of Impactsmentioning

confidence: 99%

Intensity and Impact of the New York Railroad Superstorm of May 1921

2019

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Analysis is made of low-latitude ground-based magnetometer data recording the magnetic superstorm of May 1921. By inference, the storm was driven by a series of interplanetary coronal mass ejections, one of which produced a maximum pressure on the magnetopause of~64.5 nPa, sufficient to compress the subsolar magnetopause radius to~5.3 Earth radii. Over the course of the storm, low-latitude geomagnetic disturbance exhibited extreme local time (longitude) asymmetry that can be attributed to substorm disturbance extending to low latitudes. The storm attained an estimated maximum −Dst on 15 May of 907 ± 132 nT, an intensity comparable to that of the Carrington event of 1859. The May 1921 storm brought spectacular aurorae to the nighttime sky. It also interfered with and damaged telephone and telegraph systems associated with railroad systems in New York City and State. These later effects were due to a combination of three factors: the localized details of geomagnetic vector disturbance, the geographic expression of the Earth's surface impedance tensor, and the configurations and physical parameters of the electrical networks of the day.Plain Language Summary Historical records of ground-level geomagnetic disturbance are analyzed for the magnetic superstorm of May 1921. This storm was almost certainly driven by a series of interplanetary coronal mass ejections of plasma from an active region on the Sun. The May 1921 storm was one of the most intense ever recorded by ground-level magnetometers. It exhibited violent levels of geomagnetic disturbance, caused widespread interference to telephone and telegraph systems in New York City and State, and brought spectacular aurorae to the nighttime sky. Results inform modern projects for assessing and mitigating the effects of magnetic storms that might occur in the future.

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Section: Timeline and Geography Of Impactsmentioning

confidence: 99%

Intensity and Impact of the New York Railroad Superstorm of May 1921

2019

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“…Computations of the GEF within the second, most populated, group of papers (Beggan et al, ; Bailey et al, , ; Divett et al, ; Dimmock et al, ; Liu et al, ; Marshall et al, ; Nakamura et al, ; Püthe & Kuvshinov, ; Püthe et al, ; Pokhrel et al, ; Rosenqvist & Hall, ; Wang et al, , among others) rely on a numerical modeling of the GEF, either with a thin sheet or fully 3‐D conductivity models of the Earth. 3‐D conductivity models can be compiled using, for instance, results of regional MT surveys or/and exploiting global and regional maps of bathymetry, sediment thickness, etc.…”

Section: Introductionmentioning

confidence: 99%

Exploring the Influence of Lateral Conductivity Contrasts on the Storm Time Behavior of the Ground Electric Field in the Eastern United States

et al. 2020

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The intensification of the fluctuating geomagnetic field during space weather events leads to generation of a strong electric field in the conducting earth, which drives geomagnetically induced currents (GICs) in grounded technological systems. GICs can severely affect the functioning of such infrastructure. The ability to realistically model the ground electric field (GEF) is important for understanding the space weather impact on technological systems. We present the results of three‐dimensional (3‐D) modeling of the GEF for the eastern United States during a geomagnetic storm of March 2015. The external source responsible for the storm is constructed using a 3‐D magnetohydrodynamic (MHD) simulation of near‐Earth space. We explore effects from conductivity contrasts for various conductivity models of the region, including a 3‐D model obtained from inversion of EarthScope magnetotelluric data. As expected, the GEF in the region is subject to a strong coastal effect. Remarkably, effects from landmass conductivity inhomogeneities are comparable to the coastal effect. These inhomogeneities significantly affect the integrated GEF. This result is of special importance since the computation of GICs relies on integrals of the GEF (voltages), but not on the GEF itself. Finally, we compare the GEF induced by a laterally varying (MHD) source with that calculated using the plane wave approximation and show that the difference is perceptible even in the regions that are commonly considered to be negligibly affected by lateral nonuniformity of the source. Overall, the difference increases toward the north of the model where effects from laterally variable high‐latitude external currents become substantial.

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“…These developments have enabled derivation of fully 3D electrical conductivity models that are now becoming available for geomagnetic hazard applications. In fact, while the plane-wave Starting with the empirical geomagnetic and magnetotelluric data (green), one could either use interpolation methods to estimate real-time gridded geoelectric fields ("data-space workflow," shown in blue; e.g., Bonner and Schultz 2017;Campanyà et al 2019), or a conductivity model could be used for a physics-based variant of the interpolation ("model-space workflow," shown in red, e.g., Marshall et al 2019). Method 1: interpolation using multi-station transfer functions; not based on physics.…”

Section: Data and Model-space Approaches To Geoelectric Field Estimationmentioning

confidence: 99%

“…Indeed, a state-of-the-art validation analysis of GIC modeling using multiple different conductivity model formulations in Australia was recently published by Marshall et al (2019). Four electrical conductivity models were set up with varying degrees of complexity, ranging from a uniform conductivity model, to a couple of 1D models, to a fully 3D model, derived from AWAGS magnetometer data as in Wang et al (2014), from which gridded impedance data were then produced (as described in Fig.…”

Section: Australiamentioning

confidence: 99%

“…Overall, the 3D model was found to perform better than the simpler conductivity models, but with some caveats. According to Marshall et al (2019), the relatively good performance of all models could be attributed to the reduced coast effect and otherwise relatively high conductivity of the Earth beneath the footprint of this power grid. The 3D conductivity model resolution could also be substantially improved by applying community MT inversion software (e.g., Kelbert et al 2014) to the newly obtained AusLAMP MT data; this higher-resolution model could then be combined with the coarser AWAGSderived model at depths.…”

Section: Australiamentioning

confidence: 99%

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The Role of Global/Regional Earth Conductivity Models in Natural Geomagnetic Hazard Mitigation

Kelbert

2019

Surv Geophys

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Geomagnetic disturbances cause perturbations in the Earth's magnetic field which, by the principle of electromagnetic induction, in turn cause electric currents to flow in the Earth. These geomagnetically induced currents (GICs) also enter man-made technological conductors that are grounded; notably, telegraph systems, submarine cables and pipelines, and, perhaps most significantly, electric power grids, where transformer groundings at power grid substations serve as entry points for GICs. The strength of the GICs that flow through a transformer depends on multiple factors, including the spatiotemporal signature of the geomagnetic disturbance, the geometry and specifications of the power grid, and the electrical conductivity structure of the Earth's subsurface. Strong GICs are hazardous to power grids and other infrastructure; for example, they can severely damage transformers and thereby cause extensive blackouts. Extreme space weather is therefore hazardous to man-made technologies. The phenomena of extreme geomagnetic disturbances, including storms and substorms, and their effects on human activity are commonly referred to as geomagnetic hazards. Here, we provide a review of relevant GIC studies from around the world and describe their common and unique features, while focusing especially on the effects that the Earth's electrical conductivity has on the GICs flowing in the electric power grids.

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Modeling Geomagnetically Induced Currents in Australian Power Networks Using Different Conductivity Models

Cited by 30 publications

References 66 publications

Intensity and Impact of the New York Railroad Superstorm of May 1921

Intensity and Impact of the New York Railroad Superstorm of May 1921

Exploring the Influence of Lateral Conductivity Contrasts on the Storm Time Behavior of the Ground Electric Field in the Eastern United States

The Role of Global/Regional Earth Conductivity Models in Natural Geomagnetic Hazard Mitigation

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