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Space weather impact on ground-based technological systems
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SPACE WEATHER IMPACT ON GROUND-BASED TECHNOLOGICAL SYSTEMS
Rubrics: REVIEWS
UDK 55 Геология. Геологические и геофизические науки
Pilipenko Vyacheslav 1
Authors:
1.  Space Research Institute

Schmidt Institute of Physics of the Earth, RAS

Geophysical Center RAS

Moscow, Russian Federation
Type:
Article
DOI:
https://doi.org/10.12737/szf-73202106
Pages:
from 72 to 110
Status:
Published
Received:
25.11.2020
Accepted:
28.06.2021
Published:
28.09.2021
Subject area:
UDK 55 Геология. Геологические и геофизические науки
Language:
Russian, English
Keywords:
space weather, geomagnetically induced currents, power transmission lines, transformers, pipelines, railways automation, magnetospheric storms, substorms, Pi3/Ps6 pulsations
Funding:
The work was financially supported by RFBR as part of scientific project No. 19-15-50240
Abstract and keywords
Abstract (English):
This review, offered for the first time in the Russian scientific literature, is devoted to various aspects of the problem of the space weather impact on ground-based technological systems. Particular attention is paid to hazards to operation of power transmission lines, railway automation, and pipelines caused by geomagnetically induced currents (GIC) during geomagnetic disturbances. The review provides information on the main characteristics of geomagnetic field variability, on rapid field variations during various space weather mani-festations. The fundamentals of modeling geoelectric field disturbances based on magnetotelluric sounding algorithms are presented. The approaches to the assessment of possible extreme values of GIC are considered. Information about economic effects of space weather and GIC is collected. The current state and prospects of space weather forecasting, risk assessment for technological systems from GIC impact are discussed. While in space geophysics various models for predicting the intensity of magnetic storms and their related geomagnetic disturbances from observations of the interplanetary medium are being actively developed, these models cannot be directly used to predict the intensity and position of GIC since the description of the geomagnetic field variability requires the development of additional models. Revealing the fine structure of fast geomagnetic variations during storms and substorms and their induced GIC bursts appeared to be important not only from a practical point of view, but also for the development of fundamentals of near-Earth space dynamics. Unlike highly specialized papers on geophysical aspects of geomagnetic variations and engineering aspects of the GIC impact on operation of industrial transformers, the review is designed for a wider scientific and technical audience without sacrificing the scientific level of presentation. In other words, the geophysical part of the review is written for engineers, and the engineering part is written for geophysicists. Despite the evident applied orientation of the studies under consideration, they are not limited to purely engineering application of space geophysics results to the calculation of possible risks for technological systems, but also pose a number of fundamental scientific problems.

Keywords:
space weather, geomagnetically induced currents, power transmission lines, transformers, pipelines, railways automation, magnetospheric storms, substorms, Pi3/Ps6 pulsations
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