Telluric Field Variations as Drivers of Variations in Cathodic Protection Potential on a Natural Gas Pipeline in New Zealand

Ingham, M.; Rodger, Craig J.

doi:10.1029/2018sw001985

Cited by 23 publications

(27 citation statements)

References 33 publications

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“…Even if the former proves to be the case and annual means are of no assistance in predicting superstorms, characterizing the core of the distribution (as opposed to the extreme tail) is, however, still important in space weather applications where the integral of the space weather activity is of relevance and the threshold to the effect is not in the extreme tail. Examples would include the effect of GICs on pipeline corrosion (Boteler, ; Cole, ; Gummow, ; Ingham & Rodger, ; Pirjola, ; Pirjola et al, ; Pulkkinen et al, ; Viljanen et al, ); the effect of GICs on power grid transformer degradation (Gaunt, ; Kappenman & Radasky, ); the effect of energy deposition in the upper atmosphere on the orbits of LEO satellites and space debris (Doornbos & Klinkrad, ); and the effect of integrated radiation dose on the degradation of spacecraft electronics (Baker, ; Fleetwood et al, ). In all these examples, although the extreme superstorm events have a large effect, they are rare and a much larger number of smaller events, described by the core distribution, can also have a significant integrated effect.…”

Section: Introductionmentioning

confidence: 99%

The Development of a Space Climatology: 3. Models of the Evolution of Distributions of Space Weather Variables With Timescale

et al. 2019

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We study how the probability distribution functions of power input to the magnetosphere P α and of the geomagnetic ap and Dst indices vary with averaging timescale, τ, between 3 hr and 1 year. From this we develop and present algorithms to empirically model the distributions for a given τ and a given annual mean value. We show that lognormal distributions work well for ap, but because of the spread of Dst for low activity conditions, the optimum formulation for Dst leads to distributions better described by something like the Weibull formulation. Annual means can be estimated using telescope observations of sunspots and modeling, and so this allows the distributions to be estimated at any given τ between 3 hr and 1 year for any of the past 400 years, which is another important step toward a useful space weather climatology. The algorithms apply to the core of the distributions and can be used to predict the occurrence rate of large events (in the top 5% of activity levels): they may contain some, albeit limited, information relevant to characterizing the much rarer superstorm events with extreme value statistics. The algorithm for the Dst index is the more complex one because, unlike ap, Dst can take on either sign and future improvements to it are suggested.Plain Language Summary This is the third in a series of three papers aimed at developing a climatology of space weather that applies to all solar conditions between grand solar minimum and grand solar maximum. We generate empirical models to enable us to predict the probability of a given level of space weather disturbance, as quantified by either the ap of the Dst geomagnetic indices, in a year with a given average level of disturbance. The models can be used with averaging/integration times anywhere between 3 hr and 1 year. , et al. (2019). The development of a space climatology: 3. Models of the evolution of distributions of space weather variables with timescale. Space Weather, 17, 180-209. https://doi.

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Section: Introductionmentioning

confidence: 99%

The Development of a Space Climatology: 3. Models of the Evolution of Distributions of Space Weather Variables With Timescale

et al. 2019

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“…According to Martin (1993), the high corrosion rate is responsible for the 10 % penetration into the pipe over 14 years. Henriksen et al (1978) studied a Norwegian pipeline with 300 telluric events and found a corrosion rate of 0.04 mm yr −1 caused by these events.…”

Section: Corrosion Rate Estimationmentioning

confidence: 99%

“…Previous works on GICs were done in high latitudes and revealed specific interactions between the disturbances in the solar wind and the geomagnetic field (Campbell, 1980;Fernberg et al, 2007). The effects of GICs in pipelines have also been observed and published in Argentina (Osella et al, 1998), Australia (Marshall et al, 2010), and New Zealand (Ingham and Rodger, 2018) where engineers tried to find ways of dealing with the problem. Boteler and Cookson (1986) showed that the telluric voltage induced on pipelines can be calculated by using distributed source transmission line (DSTL) equations, and the telluric effects in the pipeline are not only influenced by space weather events but also depend on the Earth's conductivity, the pipelines' electromagnetic properties, and the geometric parameters.…”

Section: Introductionmentioning

confidence: 98%

Evaluation of possible corrosion enhancement due to telluric currents: case study of the Bolivia–Brazil pipeline

et al. 2020

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Abstract. The electric field induced in the Bolivia–Brazil gas pipeline (GASBOL) was calculated by using the distributed source line transmission (DSLT) theory during several space weather events. We used geomagnetic data collected by a fluxgate magnetometer located at São José dos Campos (23.2∘ S, 45.9∘ W). The total corrosion rate was calculated by using the Gummow (2002) methodology and was based on the assumption of a 1 cm hole in the coating of the pipeline. The calculations were performed at the ends of pipeline where the largest “out-of-phase” pipe-to-soil potential (PSP) variations were obtained. The variations in PSP during the 17 March 2015 geomagnetic storm have led to the greatest corrosion rate of the analyzed events. All the space weather events evaluated with high terminating impedance may have contributed to increases in the corrosion process. The applied technique can be used to evaluate the corrosion rate due to the high telluric activity associated with the geomagnetic storms at specific locations.

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“…The recommended expressions, generically denoted by P, are skill scores of the form given by Shim et al (2011), Murphy (1988), or Liemohn, McCollough, et al (2018. It has been used by Marsal (2015) or Marsal et al (2017) in geomagnetism, and after the work of Torta et al (2014), it has been recurrently used in the GIC literature (Bailey et al, 2018;Blake et al, 2018;Ingham et al, 2017;Ingham & Rodger, 2018;Torta et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Quantifying the Performance of Geomagnetically Induced Current Models

Marsal

Torta

2019

Space Weather

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We describe a metric that has been repeatedly applied to assess the performance of models aimed at predicting geomagnetically induced currents from Space Weather events. The used parameterization, based on the well‐known root‐mean‐square error between model and observations, is simple and intuitive. Its use is exemplified, and its advantages and disadvantages are discussed, as well as its relationship with the widely extended correlation coefficient, r. Although the use of r alone is inappropriate for purposes of evaluating the agreement between model and observations, its use is recommended to complement the described performance parameter.

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Telluric Field Variations as Drivers of Variations in Cathodic Protection Potential on a Natural Gas Pipeline in New Zealand

Cited by 23 publications

References 33 publications

The Development of a Space Climatology: 3. Models of the Evolution of Distributions of Space Weather Variables With Timescale

The Development of a Space Climatology: 3. Models of the Evolution of Distributions of Space Weather Variables With Timescale

Evaluation of possible corrosion enhancement due to telluric currents: case study of the Bolivia–Brazil pipeline

Quantifying the Performance of Geomagnetically Induced Current Models

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