An EMP Attack on the U.S. Power Grids and Critical National Infrastructure
There are 12,000 nuclear weapons in the world. 4 of them can destroy the U.S.
Late one cold winter night, during a massive winter storm that covers most of the Central and Eastern United States, a 100-kiloton nuclear warhead suddenly explodes 100 miles above Dallas, Texas. Two minutes later, identical nuclear warheads explode over Las Vegas, Nevada, and Columbus, Ohio. Then a fourth and larger 800-kiloton warhead explodes over the southern Yucatan Peninsula.
The electromagnetic pulses (EMPs) produced by the first three nuclear detonations will act to almost instantly destroy the solid-state electronics that control the operation of most U.S. critical national infrastructure – including the Emergency Power Systems and active Emergency Core Cooling Systems of 26 commercial nuclear reactors. The EMP E3A Blast Wave from the fourth detonation will create a final collapse of all three U.S. electric power grids, which will be knocked out of service for a year or longer.
Figure 1: The three U.S. electric power grids.[2]
The nuclear warheads are “delivered” to their target areas by ballistic missiles launched from a submarine located 200 miles south of Pensacola in the Gulf of Mexico. The exact identity of the attacker is unknown because nuclear subs are virtually impossible to detect and track when traveling under the sea. This is a surprise attack from an unknown enemy, a “bolt from the blue”.
The submarine requires only one minute to fire the missiles from a depth of 150 feet. Three missiles are fired on depressed trajectories to reduce the time required for their warheads to reach their designated targets; their flight times last 5 to 7 minutes from launch to detonation. U.S. Early Warning systems spot the launches, but U.S. missile defense systems don’t have enough time to intercept the missiles or their nuclear warheads before they explode high over the U.S.
The location of these three high-altitude nuclear detonations did not have to be precise – detonations over other eastern and western locations (over Indiana, Ohio, Kentucky, Alabama, or Seattle and Los Angeles) would produce very similar results. But the detonations must occur above the Earth’s atmosphere and during the darkest hours of the night. The altitude of 106 miles and extreme weather conditions were chosen to maximize the destructive effects of the EMP.[3]
The skies suddenly light up above the U.S., but the detonations occur silently because the atmosphere is too thin at these altitudes to transmit sound waves. No blast effects or fires are created on Earth, but a massive burst of powerful gamma rays released by the detonations travels downward at 186,000 miles per second. As the gamma rays enter the atmosphere, they rip the electrons from air molecules and send them spinning toward Earth at almost the speed of light. The Earth’s magnetic field interacts with these massive clouds of spinning electrons, creating gigantic EMPs that will strike hundreds of thousands of square miles of the Earth’s surface.
EMP consists of three distinct waves. The three initial EMP E1 waves centered over Ohio, Nevada, and Texas strike Earth’s surface only a few billionths of a second after the high-altitude nuclear detonations. Ordinary surge protectors do not act fast enough to protect electronic devices against the effects of E1. A fraction of a second later, the EMP E2 waves arrive with effects resembling those of lightning. Surge protectors that normally would protect against lightning are likely to be disabled by the E1 waves. The final EMP E3 waves (E3A and E3B) will strike the Earth roughly 1 to 2 seconds after the initial E1 waves.
The targets over the continental U.S. were chosen to maximize the effects of both the E1 and E3B waves on each of the three U.S. power grids. The synergistic effects of these EMP waves will ruin most electronic devices and virtually eliminate the long-distance transmission of electric power in the U.S.
Figure 2: Exposure areas for EMP E1 waves from nuclear detonations 106 miles above Columbus Ohio, Dallas Texas, and Las Vegas, Nevada. The large circles depict the ranges of EMP E1 exposure, and the inner blue circles illustrate the areas where power surges created by EMP E1 incident waves can damage solid-state electronic devices that are not plugged into the grid.[4]
EMP E1 Destroys the Solid-State Electronics Required to Operate Critical National Infrastructure
EMP does not harm people, animals, or plants, nor will it cause structural damage to buildings. However, an EMP E1 wave will instantly induce highly destructive electric voltages and currents into any electrically conductive material located in the huge circular areas beneath the nuclear detonations. Each nuclear detonation creates a large circular area of EMP E1 exposure covering more than 100 thousand square miles (Figure 1). Power lines, telecommunication lines, computer cables, wires, antennas, and even many AC power cords that are hit by the E1 waves will suddenly have enormous voltages and currents surging through them.
The E1 waves induce 2 million volts and currents of 5,000[5] to 10,000[6] amps within medium distribution power lines. Overvoltages of 200,000 to 400,000 volts (beyond design capacity) occur in the 15 kilovolt-class (kV) power distribution lines that connect to most homes, farms, and businesses.[7] In less than one millionth of a second, these damaging voltages and currents surge through the U.S. power grids. Unless specifically protected from E1, any modern electronic device that contains solid-state circuitry (microchips, transistors, and integrated circuits) that is plugged into the grid will be disabled, damaged, or destroyed by this huge blast of electricity. This includes the electronic devices required to operate all U.S. critical national infrastructure.
The regions located beneath the points of detonation (depicted as dark blue circles in Figure 2) suddenly experience E1 waves powerful enough to induce damaging voltages and currents into electronic devices that are not plugged into the grid. 50,000 volts and 100 amps of current surge into unshielded AC power cords.[8] Cell phones are disabled along with cell towers; almost all forms of telecommunication cease. Virtually everything powered by electricity suddenly stops working.
Ground, air, and sea transportation systems, water and sanitation systems, telecommunication systems, and banking systems are all knocked out of service. Food and fuel distribution cease. Emergency medical services become unavailable. The multitude of electronic devices that society depends on have suddenly stopped working.
EMP E1 Knocks Out Power Through the Destruction of Glass Insulators on 15 kV Power Lines
Massive voltages and currents induced in power transmission lines by E1 waves, combined with extreme weather conditions, act to overload, short-circuit, and destroy millions of glass insulators (in a process called “flashover”) that are commonly used on 15 kilovolt (kV) electric power distribution lines throughout the United States (Figure 3). 78% of all electricity in the US is delivered to end users (residential, agricultural, commercial) through these 15 kV lines.[9] The loss of a single glass insulator on a line can knock out power distribution on the entire line.
Figure 3: Flashover destroys glass insulators on a power distribution line.[10]
As subzero weather conditions prevail across much of the U.S., the lights and power suddenly go out in American homes,
Chaos
In an instant, almost every electronic device required for modern living stops working. The computers, modems, routers, programmable logic controllers, and Supervisory Control and Data Acquisition (SCADA) systems used to monitor, control, and automate complex industrial processes all go dead. All Hell breaks loose.
All rail, port, and air traffic control ceases to function. GPS and fiber optic systems fail. Planes fall from the sky. Motorized valves that control the flow of gas and oil in millions of miles of pipelines suddenly freeze, causing ruptures and explosions. Water delivery systems fail. Control is lost at refineries and offshore platforms. Major furnace and boiler explosions take place at coal-fired power plants. Control over all industrial processes and assembly lines is lost. Remote-control systems in every industry suddenly cease operations.
Annie Jacobsen, in her remarkable book, Nuclear War: A Scenario, vividly describes what happens after nuclear war begins and an EMP E1 wave suddenly disables the critical national infrastructure of the United States.
“Of America’s 280 million registered vehicles, “10 percent of the vehicles on the road [are] suddenly not running anymore . . . Without power steering or electric brakes, vehicles coast to a stop or crash into other vehicles, into buildings, into walls. Stalled and crashed vehicles block lanes of traffic on roads and bridges everywhere, no longer just in places where people have been fleeing nuclear bombs but in tunnels and on overpasses, on big and small roads, in driveways and in parking lots across the nation . . . Electric pumping of fuel has just come to a permanent and fatal end . . .
There will be no more fresh water. No more toilets to flush. No sanitation. No streetlights, no tunnel lights, no lights at all, only candles, until there are none left to burn. No gas pumps, no fuel. No ATMs. No cash withdrawals. No access to money. No cell phones. No landlines. No calling 911. No calls at all. No emergency communication systems except some high-frequency (HF) radios. No ambulance services. No hospital equipment that works. Sewage spills out everywhere. It takes less than fifteen minutes for disease-carrying insects to swarm. To feed on piles of human waste, on garbage, on the dead . . .
Billions of gallons of water passing through America’s aqueducts surge uncontrollably. Dams burst. Mass flooding begins sweeping infrastructure and people away . . . thousands of subway trains, passenger trains, and freight trains traveling in every direction, many on the same tracks, collide with one another, crash into walls and barriers, or derail. Elevators stop between floors, or speed to the ground and crash. Satellites (including the international space station) shift out of position and begin falling to Earth. America’s fifty-three remaining nuclear power plants, are now operating on backup systems, have just begun to collectively run out of time.”[11]
However, not all nuclear plants will be running on emergency backup systems.
Reactor Meltdowns at Nuclear Power Plants
In the Eastern U.S., 14 large commercial nuclear reactors at nuclear power plants are located in areas where peak EMP E1 incident fields are in a range of 12,500 volts per meter to 50,000 volts per meter. Five more commercial reactors in the Western U.S. and seven commercial reactors in the Southern U.S. are also located in areas with similar ranges of EMP E1 (Figure 3). In these E1-saturated areas, damaging electric voltages and currents are induced within the unshielded cables, lines, and solid-state electronic equipment inside the buildings and structures at these nuclear power plants, as well as into the many above and below-ground power lines, phone lines, cables, etc. that enter and exit these plants.
Figure 4: 26 Commercial Nuclear Reactors are located in circled red areas that experience peak EMP E1 incident fields equal to 12,500 volts per meter to 50,000 volts per meter.[12]
Thousands of solid-state electronic components (control units, motor-driven pumps, motor-operated valves, temperature and pressure sensors, rectifiers, inverters, switches, etc.) are required to monitor, control, and safely operate nuclear reactors. These components are found throughout the various parts of the active Emergency Core Cooling Systems (ECCS) at each nuclear reactor; they are also found within the Emergency Diesel Generators and Battery Banks that make up the Emergency Power Systems at each nuclear power plant. All these solid-state components are unprotected from and highly susceptible to damage from the high voltages and currents created by EMP E1.
The moment the E1 waves knocked out the grids, the loss of off-site electric power triggered an emergency shutdown of every nuclear reactor operating in the U.S. No electricity is required for an emergency shutdown. However, emergency cooling systems must begin cooling the nuclear reactor core within seconds following an emergency shutdown. Otherwise, the hundreds of millions of watts of heat that remain in the reactor core[13] (the heat is produced by the highly radioactive fuel rods) will cause the reactor core to overheat to the point of self-destruction in a matter of several hours or less.[14]
In a millionth of a second, the damaging voltages and currents created by the EMP E1 wave disable the motor-operated pumps and motorized valves within the emergency cooling systems of all these 26 nuclear reactors. This power surge also knocks out the emergency power systems at the nuclear power plants where the reactors are located. The loss of the active Emergency Core Cooling Systems and Emergency Power Systems has suddenly made it impossible for these 26 nuclear reactors to remove the massive heat remaining within their reactor cores following their emergency shutdowns.
The solid-state controls in the gigantic Emergency Diesel Generators no longer work; the AC/DC interfaces located between the Battery Banks and plant electric systems have failed. There is no longer any off-site or on-site electric power available to run the active Emergency Core Cooling Systems, which would not work anyway because the solid-state electronics found in the motor-operated pumps and valves are damaged and disabled. A forced flow of water cannot be resumed through the reactor core (hundreds of thousands of gallons of water are pumped through the core each minute during normal operation). In most of these reactors, approximately two hundred million watts of decay heat remains in the reactor core – and it cannot be removed from the core before the uranium fuel rods begin to self-destruct.
The failure of these emergency systems will rapidly lead to reactor core meltdowns at each of these 26 nuclear power plants.[15] This happened because U.S. nuclear power plants (and those of many other nations) are not designed or retrofitted to withstand the effects of EMP. The U.S. Nuclear Regulatory Commission (NRC) continues to maintain that EMP poses no danger to the nuclear power plants that it regulates – although it has never conducted the comprehensive testing necessary to validate its theories (in 2019, the Electromagnetic Defense Task Force of the U.S. Air Force forced the NRC to respond to their concerns about the lack of EMP protection at U.S. nuclear power plants, but the NRC declined to take any actions to protect U.S. nuclear power plants from EMP).[16]
Spent Fuel Pool Fires at Nuclear Power Plants
A complete loss of off-site and on-site electrical power at a nuclear power plant also makes it impossible to operate the large cooling systems required to remove the heat from the spent fuel pools, where highly radioactive used or “spent” uranium fuel rods are stored. These pools contain some of the largest concentrations of radioactivity on the planet.[17] Intensely radioactive spent fuel also generates a huge amount of heat that must continuously be removed from the pool or else the water in the pool will heat to the point of boiling.
For the 26 reactors that no longer have any off-site or on-site electrical power, the only remaining way to cool the spent fuel pools is to continuously pump cooling water into them. However, the meltdown of the reactor and the corresponding release of radiation, combined with the chaos created by the EMP attack, makes this impossible. The water in these pools boils off in a matter of hours or days.
When falling water levels in the pools eventually expose the spent fuel to steam and air, this causes the rods to heat to the point of rupture or ignition and release enormous amounts of radioactivity.[18] Fuel rods recently removed from the reactor core begin burning at temperatures exceeding 1800 degrees Fahrenheit, and the fire spreads to older rods in the pool. The radioactivity released from one spent fuel pool fire makes an uninhabitable radioactive wasteland that is 60 times larger than the Chernobyl radioactive exclusion zone.[19]
Figure 5: Contamination areas from a hypothetical fire in a single high-density spent fuel pool at the Peach Bottom Nuclear Power Plant in Pennsylvania releasing 1600 PBq of Cesium-137 on four dates in 2015[20]
The enormous amounts of radiation released by the destroyed reactors and their burning 26 spent fuel pools will turn much of the continental U.S. into an uninhabitable radioactive exclusion zone.
EMP E1 Wave Begins Destruction of U.S. Power Grids
The huge E1-induced power surge also struck the Extra High Voltage substations across the U.S. (Figure 6), destroying most of the protective solid-state relays[21] that shield electrical systems within the grid from damage.[22] This included the relays that activated the Extra High Voltage (EHV) Circuit Breakers, which provided the primary protection from damaging currents to the Large Power Transformers (LPTs).[23] There are approximately 5000 EHV Circuit Breakers of 345 kilovotls (kV) and higher operating voltage in the three U.S. power grids.[24]
Figure 6: 1765 Extra High Voltage Substations Exposed to E1 from the nuclear detonation over Columbus, Ohio, which are 83% of such substations in the U.S.[25]
LPTs are used at power generation facilities to increase the voltage before long-distance transmission (this reduces power loss) and then at the end of transmission lines to reduce (step down) the voltage when power is distributed to American households, agriculture, and industry. LPTs are absolutely required for the transmission of electric power in the U.S. (Figure 7). 90% of the electricity in U.S. power grids passes through aging 345 kV (345,000 volts), 500 kV, and 765 kV LPTs; there are only several thousand of these LPTs within the three U.S. national power grids.[26]
Figure 7: The role of Large Power Transformers (LPTs) in the power grid. LPTs are circled in red[27]
The massive voltages and currents created by the E1 waves, which formed within power transmission lines, also damaged and destroyed the series capacitors on these lines that protected LPTs from dangerous power surges.[28] The E1 power surge also disabled the electronics within the LPT cooling systems (that are required by LPTs),[29] and burned tiny holes in the insulation of the windings within the LPTs.[30] This left the LPTs susceptible to internal short circuits and overheating.
In other words, the EMP E1 waves disabled the safety systems required to protect LPTs, as well as damaging some LPTs and leaving all of them quite vulnerable to the effects of the following EMP E3 waves.[31]
EMP E3B Waves Wreck the EHV Circuit Breakers and LPTs – U.S. Grids Go Down for a Year or Longer
One or two seconds after the nuclear detonations over Columbus, Las Vegas, and Texas, the EMP E3B Heave Waves created by these detonations induce current flows into both above and below-ground power transmission lines. Scientists have confirmed, by “all means of measurement”, that the threat potential posed by EMP E3 exceeds the intended stress limit the aging U.S. power network is designed and tested to withstand.[32] Figures 8, 9, and 10 depict the impact of the three E3B Heave Waves.
Figure 8: E3B Heave Wave from nuclear detonation over Columbus, Ohio collapses the power grid in the outlined region. Extreme weather conditions spread the collapse to Florida and Maine.[33]
Figure 9: E3B Heave Wave from nuclear detonation above Las Vegas, Nevada collapses the grid in the outlined region.[34]
Figure 10: E3B Heave Wave from nuclear detonation above Las Vegas, Nevada collapses the grid in the outlined region.[35]
Because the U.S. has failed to shield its electric power grids from EMP, all the 765 kV LPTs, two-thirds of the 500 kV LPTs, and at least 20% of the 345 kV LPTs are quite vulnerable to the effects of EMP E3.[36] Both the LPTs – and the EHV Circuit Breakers that protect them – are about to be damaged, disabled, and destroyed by the combination of effects from the E1 and E3B waves.
Figure 11: Moving a 460,000-pound Large Power Transformer. The combined weight of the transformer and equipment required to move it was 944,800 pounds[37] LPTs cannot be quickly installed even after their replacements are manufactured and delivered to the U.S.
The EMP E3B waves induce Direct Current (DC) within long power transmission lines as well as in the Earth itself. The loss of the protective relays (following the E1 waves) allows direct currents of hundreds to thousands of amps to flow into EHV Circuit Breakers and LPTs.[38] The EHV Circuit Breakers explode and LPTs overheat and self-destruct. LPTs often contain many thousands of gallons of oil for cooling and high-voltage insulation purposes; this oil becomes fuel for generating large fires that rapidly engulf major portions of the substation and/or power plant facility where the LPTs are located.[39]
Removing LPTs and EHV Circuit Breakers from the grid leaves most of the United States without electric power for up to a year or longer. This is because EHV Circuit Breakers[40] and LPTs are not stockpiled. It now takes 40 to 60 weeks to replace EHV Circuit Breakers.[41] LPTs must be custom-designed and manufactured and about 80% of LPTs are made overseas.[42] The current wait time for LPT manufacture is 80 to 210 weeks.[43]
A Final E3A Blast Wave Increases the Destruction of LPTs and EHV Circuit Breakers
The target of the fourth missile fired by the nuclear sub in the Caribbean Sea is a point 300 miles above the southern Yucatan Peninsula of Mexico. The missile carries an 800-kiloton nuclear warhead; its detonation creates an E3A Blast Wave that produces its most severe effects 2000 miles north of the point of detonation.[44]
Figure 12: EMP E3A Blast Wave from high-altitude nuclear detonation over Central America; the most severe effects are felt across the northern tier of the U.S., 2000 miles north of the blast.[45]
The current flows induced by the E3A Blast Wave are many times more powerful than those created by the E3B Heave wave.[46] Every state from the East Coast to the West Coast states of Washington, Oregon, and California, and from Maine to Florida and Texas will have more than enough current from this single detonation to collapse the entire U.S. power grid (Figure 13). The E3A Blast Wave provides a massive blow to the surviving LPTs and EHV Circuit Breakers in the three U.S. power grids.
Figure 13: The effects of an EMP E3A Blast Wave from a nuclear detonation over the Yucatan Peninsula collapses the entire U.S. power grid.[47]
Societal Collapse
It is the dead of winter, in the middle of a major winter storm, and electricity is no longer available for most Americans, who now find themselves in dark, freezing cold homes where nothing works anymore. No lights, no running water, no phone, internet, or TV, and soon, no food. If their cars can still start, they will find the highways blocked by other cars that were disabled by the initial E1 wave. Gasoline can no longer be pumped out of underground tanks. Food deliveries to the cities stop. People attempt to flee from regions receiving massive radioactive fallout that are downwind of destroyed nuclear reactors and spent fuel pools. Society collapses as millions of starving, desperate people do anything to try to survive.
The Chairman of a Congressional Committee that investigated the effects of a nuclear EMP attack on the United States has estimated that most Americans would not survive an EMP attack that knocked out U.S. power grids and disabled critical national infrastructure.[48] Despite such warnings, the United States has not acted to shield its power grids and critical national infrastructure – including its nuclear power plants – from the effects of EMP.
Postscript
Technology exists that could effectively protect the U.S. power grid from destruction. Likewise, the vulnerable components in U.S. critical national infrastructure can also be shielded to a significant degree from EMP (this also applies to the vulnerable components of the active Emergency Core Cooling Systems and Emergency Power Systems at nuclear reactors). Several detailed technical papers explain how this can be accomplished.[49] [50] [51] [52] [53] Cost estimates to add this protection are in the tens of billions of dollars, which is a small fraction of what the U.S. spends each year on its defense budget.
The U.S. military long ago acted to shield its weapons and communication systems from EMP, however, all attempts to mandate U.S. critical national infrastructure be shielded from EMP have been defeated. Twice – in 2013 and 2015 – Bills mandating EMP protection failed to come to a final vote in Congress because the nuclear and electrical utilities lobbied against them. Their opposition arose from the wording in the bills that required the utilities to pay for the shielding.
Consequently, no significant steps have yet been taken to install equipment and modifications that would protect the U.S. national electric grid and U.S. critical national infrastructure from EMP.
Author’s note: Russian and Chinese open-source military texts describe Super-EMP weapons that create EMP E1 waves that are two to four times more powerful than those described and illustrated in this article.[54] If Super-EMP weapons are used in an attack against the U.S., the effects of even one nuclear high-altitude electromagnetic plus could be significantly more severe than those described in this paper.
(For a more detailed explanation of this subject, please read my book, Nuclear High-Altitude Electromagnetic Pulse: A Mortal Threat to the U.S. Power Grid and U.S. Nuclear Power Plants).
Footnotes
[1] Federal government of the United States, Public domain, via Wikimedia Commons. https://upload.wikimedia.org/wikipedia/commons/0/03/Hardtack_I_Teak_002.jpg
[2] U.S. Environmental Protection Agency, “U.S. Electricity Grid and Markets”, retrieved September 1, 2024 from https://www.epa.gov/green-power-markets/us-electricity-grid-markets
[3] Gilbert, J., Kappenman, J., Radasky, W. (2010). “The Late-Time (E3) High-Altitude Electromagnetic Pulse (HEMP) and Its Impact on the U.S. Power Grid”, Metatech Corporation, Meta R-321, Section 3. http://www.futurescience.com/emp/ferc_Meta-R-321.pdf
[4] Image derived from Savage, E., Gilbert, J., Radasky, W. (2010). “The Early-Time (E1) High-Altitude Electromagnetic Pulse (HEMP) and Its Impact on the U.S. Power Grid”. Metatech Corporation, Meta R-320, p. 7-20 and p. 2-30, also https://commons.wikimedia.org/w/index.php?curid=183521
[5] The worst-case HEMP E1 used by the military in MIL-STD-188-125-1 for an E1-induced powerline current of 5,000 amperes. The characteristic impedance for a power line is approximately 400 ohms, thus providing a peak worst-case voltage level of 2 MV. Op. cit. “The Early-Time (E1) High-Altitude Electromagnetic Pulse (HEMP) and Its Impact on the U.S. Power Grid”, p. 7-3
6] Cybersecurity Division of the Cybersecurity and Infrastructure Security Agency, National Coordinating Center for Communications, February 5, 2019. “Electromagnetic Pulse (EMP) Protection and Resilience Guidelines for Critical Infrastructure and Equipment”, version 2.2 UNCLASSIFIED, p. 29.
[7] Op. cit. “The Early-Time (E1) High-Altitude Electromagnetic Pulse (HEMP) and Its Impact on the U.S. Power Grid”. p. 7-27.
[8] Op. cit. “Electromagnetic Pulse (EMP) Protection and Resilience Guidelines for Critical Infrastructure and Equipment”, p. 29.
[9] Ibid. p. 7-25
[10] Orient Power Insulators, retrieved September 19, 2024. https://www.composite-insulator.com/learn-more-about-insulator-flashover-and-how-to-prevent-insulator-flashover.html
[11] Jacobsen, A. (2024). Nuclear War: A Scenario. Penguin Random House, pp. 264-267
[12] Image derived from U.S. Nuclear Regulatory Commission. (2023). “Map of Power Reactor Sites”, retrieved August 29, 2024, from https://www.nrc.gov/reactors/operating/map-power-reactors.html
[13] Clarke, M., (June 2020). “Battery Backups for Nuclear Power Plants” M.E.T.T.S. Consulting Engineers”. https://www.metts.com.au/battery-backups-for-nuclear-power-plants.html
[14] Cook, D. Greene, S. Harrington, R. Hodge, S. Yue, D. (1981). “Station Blackout at Brown’s Ferry Unit One – Accident Sequence Analysis”, Oak Ridge National Laboratory, Prepared for the Nuclear Regulatory Commission, Table 9.7
[15] Three nuclear reactors melted down at the Fukushima Daichi power plant after an earthquake wiped out the power lines coming into the plant and a tsunami subsequently destroyed the Emergency Diesel Generators that provided the primary backup source of electric power (the Battery Banks, which supply a secondary source of electric power only operate for 8 hours or less). Once all offsite and on-site electric power was lost, it became impossible to pump cooling water through the reactor cores. Temperatures in the core of Unit 1 reached 5070°F in six hours and the reactor core melted through the steel containment vessel in less than 16 hours. Sample, Ian (29 March 2011). “Japan may have lost race to save nuclear reactor”. The Guardian. London. https://web.archive.org/web/20110330215722/http://www.guardian.co.uk/world/2011/mar/29/japan-lost-race-save-nuclear-reactor
[16] Stuckenberg, D., Woolsey, J., DeMaio, D. (August 2019). “Electromagnetic Defense Task Force (EDTF) Report 2.0, LeMay Paper No. 4”, Air University Press, Maxwell Air Force Base, Alabama, Appendix 1, pp. 53. https://www.airuniversity.af.edu/Portals/10/AUPress/Papers/LP_0002_DeMaio_ Electromagnetic_Defense_Task_Force.pdf
[17] Alvarez, R. (May 2011). “Spent Nuclear Fuel Pools in the US: Reducing the Deadly Risks of Storage”, Institute for Policy Studies, Washington D.C., p. 1. https://www.nrc.gov/docs/ML1209/ML120970249.pdf
[18] Alvarez, R. Beyea, J. Janberg, K. Kang, J. Lyman, E. Macfarlane, A. Thompson, G. von Hippel, F. (2003). “Reducing the Hazards from Stored Spent Power-Reactor Fuel in the United States”, Science and Global Security, 11:1–51, p. 2. https://scienceandglobalsecurity.org/archive/sgs11alvarez.pdf
[19] Op. cit. “Spent Nuclear Fuel Pools in the US: Reducing the Deadly Risks of Storage”, p. 1.
[20] von Hippel, F., Schoeppner, M. (August 16, 2016). “Reducing the Danger from Spent Fuel Pools”, Science and Global Security, Princeton University, p. 155. https://scienceandglobalsecurity.org/archive/sgs24vonhippel.pdf
[21] Solid-state relays are particularly vulnerable to EMP E1 (they have essentially replaced older electromechanical relays) and make up the majority of relays in Extra High Voltage substations.
[22] Relays detect abnormal currents and overloads and initiate protective actions to protect the electric system from damage. Types of relays include transformer protection relays, which monitor overcurrent, overvoltage, and temperature abnormalities) and differential relays, which that act to protect transformers from internal faults.
[23] Solid-state control systems were also damaged within some EHV Circuit Breakers.
[24] Gilbert, J., Kappenman, J., Radasky, W. (2010). “The Late-Time (E3) High-Altitude Electromagnetic Pulse (HEMP) and Its Impact on the U.S. Power Grid”, Metatech Corporation, Meta R-321, p. 4-2. https://www.futurescience.com/emp/ferc_Meta-R-321.pdf
[25] Op. cit. “The Early-Time (E1) High-Altitude Electromagnetic Pulse (HEMP) and Its Impact on the U.S. Power Grid”. p. 7-20
[26] Many LPTs are at the end of their life expectancy; ten years ago, the average age of installed LPTs in the United States was 38 to 40 years, with 70% of LPTs being 25 years or older. U.S. Department of Energy, Office of Electricity Delivery and Energy Reliability. (April 2014). “Large Power Transformers and the U.S. Electric Grid”, p. v. https://www.energy.gov/sites/prod/files/2014/04/f15/LPTStudyUpdate- 040914.pdf
[27] U.S.-Canada Power System Outage Task Force. (April 2004). “U.S.-Canada Power System Outage Task Force, Final Report on the August 14, 2003 Blackout in the United States and Canada: Causes and Recommendations”, Figure 2.1, p. 5
[28] Series capacitors are commonly used in the Western power grid and are less common in the Eastern and Texas power grids.
[29] Baker, G., Webb, I., Burkes, K., Cordaro, J. (2021). “Large Transformer Criticality, Threats, and Opportunities”, Journal of Critical Infrastructure Policy, Volume 2, Number 2. https://centerforsecuritypolicy.org/wp-content/uploads/2022/06/LARGE-TRANSFORMER-THREATS-OPPORTUNITIESJCIP-PUBLISHED-VERSION.pdf
[30] Op. Cit. “The Late-Time (E3) High-Altitude Electromagnetic Pulse (HEMP) and Its Impact on the U.S. Power Grid”, p. 7-34.
[31] Over the Horizon. (August 27, 2019). “Electromagnetic Pulse Threats to America’s Electric Grid: Counterpoints to Electric Power Research Institute Positions”, U.S. Air Force Air University Foundation, retrieved September 16, 2024, https://othjournal.com/2019/08/27/electromagnetic-pulse-threats-to-americas-electric-grid-counterpoints-to-electric-power-research-institute-positions/
[32] Op. Cit. “The Late-Time (E3) High-Altitude Electromagnetic Pulse (HEMP) and Its Impact on the U.S. Power Grid”, p. 3-2.
[33] Ibid, p. 3-7.
[34] Ibid. p. 3-12
[35] Ibid. p. 3-9.
[36] These are single-phase LPTs.
[37] Omega Morgan, “Going Heavy for a Transformer Transport Near Portland, Oregon”, retrieved September 11, 2024. https://www.omegamorgan.com/case-studies/specialized-transportation/going-heavy-for-a-transformer-transport-near-portland-oregon/
[38] Windings capable of carrying up to 3,000 Amps of alternating current can be destroyed by geomagnetic direct currents of only about 300 Amps. See Tennessee Valley Authority, (December 2010). “Initial Review of Extreme Geomagnetic Storms to TVA Operations”: Findings and Recommendations”, p. 5. https://www.governmentattic.org/31docs/EMPriskTVA_2010.pdf
[39] Op. cit., “The Late-Time (E3) High-Altitude Electromagnetic Pulse (HEMP) and Its Impact on the U.S. Power Grid”, p. 5-1.
[40] There are approximately 5000 345 kV and higher EHV Circuit Breakers operating in the U.S., see Gilbert, J., Kappenman, J., Radasky, W. (2010). “The Late-Time (E3) High-Altitude Electromagnetic Pulse (HEMP) and Its Impact on the U.S. Power Grid”, Metatech Corporation, Meta R-321. P. 4-2. https://www.futurescience.com/emp/ferc_Meta-R-321.pdf
[41] Colthorpe, A. (September 21, 2023). “Lithium Supply Chain Much Improved but transformers and other components a headache for BESS industry”, Energy Storage News. https://www.energy-storage.news/lithium-supply-chain-much-improved-but-transformers-and-other-components-a-headache-for-bess-industry/#:~:text=HV%20circuit%20breakers%20are%20on,versus%2010%2D40%20weeks%20previously.
[42] LPTs each weigh between 200 and 400 tons and must be shipped by sea and moving them to their final destination is quite difficult. LPTs can’t be moved by rail (100 tons is the normal weight limit for transport by train). LPTs are often too heavy to cross bridges; traffic lights and power lines must be moved for them to pass. Even under normal circumstances, this is a complex process, and trying to move them in post-apocalyptic circumstances – through the U.S. following a year without electric power – could prove to be next to impossible.
[43] Jacobs, K., Barr, A., Chopra, S., Boucher, B. (April 2, 2024). “Supply shortages and an inflexible market give rise to high power transformer lead times”, Wood Mackenzie. https://www.woodmac.com/news/opinion/supply-shortages-and-an-inflexible-market-give-rise-to-high-power-transformer-lead-times/
[44] There are two forms of EMP E3 waves; the E3B Heave Wave, which radiates from the areas of the nuclear detonation, and the E3A Blast Wave, which creates its most destructive effects far north of the nuclear blast; their effects on the power grid are most serious during the darkest hours of the night.
[45] Op. cit. “The Late-Time (E3) High-Altitude Electromagnetic Pulse (HEMP) and Its Impact on the U.S. Power Grid”, p. 2-4.
[46] Ibid. p. 3-13.
[47] Ibid. p. 3-16.
[48] Graham, Dr. William R., Chair, Commission to Assess the Threat to the United States from Electromagnetic Pulse (EMP) Attack. (July 10, 2008). “THREAT POSED BY ELECTROMAGNETIC PULSE (EMP) ATTACK”, COMMITTEE ON ARMED SERVICES, HOUSE OF REPRESENTATIVES, ONE HUNDRED TENTH CONGRESS. http://highfrontier.org/wp-content/uploads/2016/09/HASC-Report-110-156-Hearing-July-10-2008-at-p.-9.pdf
[49] Kappenman, J. (January 2010), “Low-Frequency Protection Concepts for the Electric Power Grid: Geomagnetically Induced Current (GIC) and E3 HEMP Mitigation”, Metatech Corporation, Meta-R-322. https://www.ferc.gov/sites/default/files/2020-05/ferc_meta-r-322.pdf
[50] The Foundation for Resilient Societies. (September 2020) “Estimating the Cost of Protecting the U.S. Electric Grid from Electromagnetic Pulse. https://www.resilientsocieties.org/uploads/5/4/0/0/54008795/estimating_the_cost _of_protecting_the_u.s._electric_grid_from_electromagnetic_pulse.pdf
[51] International Electrotechnical Commission. (May 17, 2017). “Electromagnetic compatibility (EMC) – Part 5-10: Installation and mitigation guidelines – Guidance on the protection of facilities against HEMP and IEMI https://standards.iteh.ai/catalog/standards/iec/b66818ad-403e-47ec-98bb- ba156e7cb367/iec-ts-61000-5-10-2017
[52] Radasky, W. (October 31, 2018). “Protecting Industry from HEMP and IEMI”, In Compliance Magazine. https://incompliancemag.com/article/protecting-industry-from-hemp- and-iemi/
[53] Radasky, W., Savage, E. (Jan 2010). “High-Frequency Protection Concepts for the Electric Power Grid”, Metatech Corp, Meta-R-324. https://www.ferc.gov/sites/default/files/2020-05/ferc_meta-r-324.pdf
[54] Vaschenko, A. (November 1, 2006). “Russia: Nuclear Response to America Is Possible Using Super-EMP Factor”, “A Nuclear Response To America Is Possible,” Zavtra; Zhao Meng, Da Xinyu, and Zhang Yapu, (May 1, 2014). “Overview of Electromagnetic Pulse Weapons and Protection Techniques Against Them” Winged Missiles (PRC Air Force Engineering University; Vaschenko, A., Belous, V. (April 13, 2007); “Preparing for the Second Coming of „Star Wars”, Nezavisimoye Voyennoye Obozreniye translated in Russian Considers Missile Defense Response Options CEP20070413330003
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