In my story a man who works in Military Intel gets early warning that a nuclear attack on his base is inbound. He abandons his post, grabs his wife and kid from on base housing, and books it out of there at 90 miles per hour with 20 minutes to spare. He is 30 miles away from ground zero when the strike happens. This is far enough away that he and his family are 10 miles outside of the air blast radius. The idea is that they continue driving as far as they can before running into clogged roads or running out of gas.

My question is, does the EMP stall their car? Does EMP affect cars? I know that EMP is not the magic anti-technology ray that Hollywood makes it out to be, but I don't know what the actual real world effects on a vehicle would be.

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    $\begingroup$ Is there even a significant (larger than, say 5-10 miles) EMP for a "direct hit", i.e. low altitude detonation? My thinking has it that unless you also do a HEMP, thanks to absorption and ionized air and all, nothing happens at 30 miles distance anyway. $\endgroup$
    – Damon
    Commented Sep 17, 2018 at 12:18
  • $\begingroup$ @Damon that's what I am seeing - gamma ray deposition is limited to 10 miles in low atmosphere. This article ece-research.unm.edu/summa/notes/SDAN/0032.pdf referenced from the Wikipedia entry on Nuclear EMP has the maths for Surface Burst EMP specifically on p4 of the pdf, but I don't have the time to re-educate myself on the maths to write a full answer - best wishes if you do $\endgroup$ Commented Sep 17, 2018 at 12:37
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    $\begingroup$ Glad to see that the site has finally loosened up its definition of world building. I asked a very similar question 2.5 years ago and it got closed as off topic. $\endgroup$ Commented Sep 17, 2018 at 13:09
  • $\begingroup$ You should read One Second After, by John Matherson. It delves into many aspects of an EMP attack, including the effects on cars $\endgroup$
    – Belgabad
    Commented Sep 17, 2018 at 16:18
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    $\begingroup$ I don't have the numbers on hand to form a proper answer, but I doubt it. I once worked on a project to make a remote car disabler (idea was for police to use in a chase) and it was remarkably hard to shut off engines with EM interference. We were able to do it, but had to place a powerful emitter right up against the target car. Obviously an EMP from a nuke is much more powerful, but inverse-square is also a b*tch. $\endgroup$
    – Gene
    Commented Sep 17, 2018 at 16:33

4 Answers 4


Depends on the car

It also depends on luck, sometimes an EMP will do permanent damage, sometimes it won't. The chances are you'll blow a bunch of fuses at the very least.

If you're running a diesel then it'll probably keep going. Not because the electronics are any more robust but because diesel doesn't actually need the glow plugs, it'll run on compression ignition. Depending on which fuses you blow, it may not start again if you stop the engine. If you fry the engine management system it'll run less efficiently, but it'll keep going. I once had a modern diesel running without fuel pumps, without glow plugs, without engine management, and only 3/4 cylinders, diesels keep going.

For petrol cars, the more modern and high spec the car, the more damage it's at risk of taking. If you're talking about a new BMW or Mercedes there's a reasonable chance it'll be completely knocked out from permanent damage to delicate electronics and drive by wire systems. Almost nothing you're holding is directly connected to the vehicle control it represents, it all goes through the computer first, even the steering.

If you're talking something from the 1970s with minimal electronics and all the refinement of a cart, it may even keep going with a brief cough as it cuts out during the pulse and then bump starts itself from the momentum.

Of course you're not the first to consider this issue.

The EMP Commission (appears legitimate) have written a report that includes considering the damage to vehicles from EMP which implies that there's no real issues.

However it should be noted that this report only covers vehicles up to 2002, current high spec vehicles have a far higher level of "drive by wire" computer control.

From page number 115 (pdf page 131)

We tested a sample of 37 cars in an EMP simulation laboratory, with automobile vintages ranging from 1986 through 2002. Automobiles of these vintages include extensive electronics and represent a significant fraction of automobiles on the road today. The testing was conducted by exposing running and nonrunning automobiles to sequentially increasing EMP field intensities. If anomalous response (either temporary or permanent) was observed, the testing of that particular automobile was stopped. If no anomalous response was observed, the testing was continued up to the field intensity limits of the simulation capability (approximately 50 kV/m).

Automobiles were subjected to EMP environments under both engine turned off and engine turned on conditions. No effects were subsequently observed in those automobiles that were not turned on during EMP exposure. The most serious effect observed on running automobiles was that the motors in three cars stopped at field strengths of approximately 30 kV/m or above. In an actual EMP exposure, these vehicles would glide to a stop and require the driver to restart them. Electronics in the dashboard of one automobile were damaged and required repair. Other effects were relatively minor. Twenty-five automobiles exhibited malfunctions that could be considered only a nuisance (e.g., blinking dashboard lights) and did not require driver intervention to correct. Eight of the 37 cars tested did not exhibit any anomalous response.

Based on these test results, we expect few automobile effects at EMP field levels below 25 kV/m. Approximately 10 percent or more of the automobiles exposed to higher field levels may experience serious EMP effects, including engine stall, that require driver intervention to correct. We further expect that at least two out of three automobiles on the road will manifest some nuisance response at these higher field levels. The serious malfunctions could trigger car crashes on U.S. highways; the nuisance malfunctions could exacerbate this condition. The ultimate result of automobile EMP exposure could be triggered crashes that damage many more vehicles than are damaged by the EMP, the consequent loss of life, and multiple injuries.

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    $\begingroup$ @L.Dutch True, but OP was clearly asking about cars in general, not specifically diesel cars. $\endgroup$
    – Neil
    Commented Sep 17, 2018 at 9:18
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    $\begingroup$ Apparently computerized fuel injection systems significantly pre-date the date of this report; I was a little surprised by that. Certainly cars contain much more sophisticated electronics now. Buried in this video youtube.com/watch?v=OobLb1McxnI you will find out that the reason they could make their hack work over the internet is that all the vehicles with this system have a connection to the Verizon mobile phone network. $\endgroup$
    – Ton Day
    Commented Sep 17, 2018 at 9:31
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    $\begingroup$ @DaytonWilliams, that's a classic case of The 'S' in 'IoT' stands for security. $\endgroup$
    – Separatrix
    Commented Sep 17, 2018 at 9:50
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    $\begingroup$ This report from 2010 also suggests that cars should mostly survive, and though it posits that that might change, it places more blame on potential use of non-metallic materials, rather than increased use of computers. $\endgroup$
    – Cadence
    Commented Sep 17, 2018 at 10:29
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    $\begingroup$ @Reed, I know very little about electric cars in terms of the engineering, but somehow I suspect that the amount of internal electrical noise they normally generate will mean that everything is more heavily shielded to protect it from itself, and hence it may be completely unaffected. $\endgroup$
    – Separatrix
    Commented Sep 17, 2018 at 13:32

One other consideration is the car in the line of sight of the nuclear blast at detonation or not. Estimating a Nuclear Bomb's destructive capacity is a very imprecise science. For example, the Nagasaki device (Fat Man) was theoretically more destructive than the Hiroshima device (Little Boy). In reality, the reverse was observed. This was because Little Boy was detonated over what was an open field with little to stop the destructive forces of the bomb. Fat Man detonated below the mountain tops of a valley, which contained much of the destructive energy of the blast to the valley's sparing the bulk of the city, which could still witness the destruction.

The destructive portion of the bomb's blast are light/heat radiation and the over-pressure. In order, you will first see the light, then feel the heat, and then see the overpressure. The former two are near instantaneous. if you are in line of sight, I personally call this the "Simba's Kingdom Fire" because everything that the light touches will burst into flames. The closest known survivor to Hiroshima Ground Zero was in a bank vault at the time of the raid and was not exposed to the light/heat as the rest of the bank became engulfed in an inferno and then blown away. It's distance to GZ was measured in meters. The overpressure will be felt at progressively larger time gaps from ground zero. An air burst is more destructive than a ground burst because there is little to stop this, though the destruction of most of Nagasaki was prevented by obustructions that contained the blast, the affected industrial area was absolutely destroyed. Meanwhile, damage from the light at radiation at Hiroshima could be traced all the way to a grove of trees on a hill overlooking the Jinkaku-ji Temple in Kyoto... a distance of 361.2 km (225 miles) from ground zero.

This is true of the EMP as it is line of sight only... it was believed that a full on Soviet nuclear war would start with a very high altitude burst over the continental US... high enough that no target is damaged... but almost every electronic device is put out of commission on the North American Continent. The car may however still survive if something was obstructing line of sight from the blast. Being under a tunnel might give you the chance to get out of the way... the EMP in a full on attack on the US will normally proceed the attack's more destructive capability. A closer to earth air burst will likely be safe if he is safe from the light/fire destruction.

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    $\begingroup$ "Simba's Kingdom Fire" is such a cheerful name for something so abjectly horrifying. $\endgroup$
    – anon
    Commented Sep 17, 2018 at 16:49
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    $\begingroup$ Your answer is a little wrong -- it's not anything in line of sight. Detonate an EMP high enough and, no matter what it sees, it won't do jack to the things below; it dissipates before it can hit the ground. The reason high-altitude nukes generate such massive damage isn't that they have line-of-sight on everything, it's that the comparatively small EMP creates a much, much bigger one in the atmosphere. See this Wikipedia article. $\endgroup$
    – anon
    Commented Sep 17, 2018 at 16:51
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    $\begingroup$ Extremely intense light can also mess with electronics in interesting ways ... though most of the stuff in a car is in rather thoroughly opaque housings... $\endgroup$ Commented Sep 17, 2018 at 19:29
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    $\begingroup$ @NicHartley: Thank you. The Lion King is always on my mind in Nuclear Bomb discussions because you are almost required to say "everything the light touches" to describe what catches fire. Further tying it to such a well known movie really helps get the point across. $\endgroup$
    – hszmv
    Commented Sep 17, 2018 at 19:49
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    $\begingroup$ Not quite. Non conductors don't do much to block EMP. So a plywood and shingle roof doo little, while a tin roof may help a lot. $\endgroup$ Commented Sep 18, 2018 at 18:34

Powertrain: Dumb luck will be the ruling factor

It's all going to depend on the luck of the draw and how the hit occurs and how EMP waves bend around local terrain and the metalwork of the particular car.

First, remember the powertrain is already substantially inside a Faraday cage. The hood is metal, the unibody is metal and so is the engine - this largely wraps the engine package.

Nonsense to dismiss: that some cars are "mechanical" and will Just Keep Working. Nosirree. Every modern car is FADEC. Even the diesels, remember when VW cheated the Smog tests by detecting when the car was on a test stand and detuning the engine during those times? The only way to do that is with FADEC. All the other builders who were not cheating also required FADEC. So all modern cars are computer controlled.

I.E. the computer decides when (i.e. which microseconds) the fuel injector fires, and it does this in real-time on the fly. If the computer gets borked, the car doesn't stay at the last throttle position, it simply forgets to inject fuel starting right now, so the engine dies instantly.

The days of there being a basically mechanical carb/FI system with computers "only doing trim optimization" started in the 1970s with carburetors, and ended in the early 1990s -- killed off dead in 1996 when OBDII became law. OBDII requires FADEC.

But even in 1991 you'd be hard pressed to find a non-FADEC engine, probably in a light truck. Why? It's a darn good technology that makes engines run better, much longer, and more powerful too, by enabling other performance tech.

Older automobiles are practically extinct on the road

The current mix of automobiles found on the highway contain essentially zero pre-FADEC era cars. You might find older trucks without FADEC, the bigger the more likely, but only up to a certain size.

California has achieved a practical peace with classic car lovers, based on the following fact: There aren't enough of them left to make a difference. No, I mean there are loads. But they're not daily drivers. They run so rarely that they don't have a significant impact. Simply put, they're not worth regulating.

As an author, that means if you prioritize a search for an EMP-proof car, look for well-cared-for but rarely-driven collector cars. You won't find one in an office parking lot, though. It'll be in an enthusiast's garage. Or out back up on blocks, but that one won't run.

Creature comforts: All bets are off

Powertrain computers on modern cars are already extremely hardened - not against EMP but just against failing generally. Some fool shorting an oxygen sensor to 12V, a wiring harness meltdown in transmission control wiring, whatever. That's powertrain.

Now modern cars have a whole second *tranche of computers in the carbody, and those don't run the powertrain, they run the human/creature comforts. For instance the left door has 1 power window motor and Four power window switches. 14 wires? Not anymore, now it's 2 power/ground wires, and two thin little signal wires, and embedded computers in every door that chat over the signal wires.

And in recent years, as you well know, this "body-side" stuff has exploded to be the reason you buy a car - built in Nav, Siri, Alexa, smartphone integration, your music, Sirius Radio, all the smart-car stuff potentially including the autopilots - some cars more than 50% of the cost of the car is in this consumer-appeal electronic cruft.

This stuff is all body-side, and there are places where the body is not steel, but the dash and door panel interiors are not steel at all. EMP will ignore all that and reflect in unpredictable ways off the parts of the car which are metal, exposing the body-side stuff to a lot of potential damage.

So there's a pretty good chance that your engine will work but your speedo will not. Sirius works but ONStar does not, turn signals fail, and you can't roll down your windows. And the A/C won't turn on because the sophisticated comfort control took a hit, that doesn't doom you, but the fan won't run either, and that dooms you.

Ever drive a car with no fan and no windows in the summer? You cook. It's the same exact physics as dogs and babies dying from being abandoned in the car, except you happen to be moving.

However if the blower works, and a smart person could "jumper it so it's hard on" depsite blown electronics, that makes the car interior livable - though if it's a sunny day over 60F, you will need quite a bit of hydration, solar load beats you up bad. Actually for best freeway fuel economy you want windows up, A/C off, blower on max. "Windows down" is bad due to aero-drag, and A/C on takes a lot of fuel.

  • $\begingroup$ Would this actually lock the passengers in? I'd think doors must be openable mechanically from the inside, but at least on the rear it's common to have electronic child locks. Ventilating the car by pushing the doors open a little works quite well, albeit with very turbulent draft. $\endgroup$ Commented Sep 18, 2018 at 12:05
  • $\begingroup$ @leftaroundabout doors that don't work from the inside is a feature that is exploding. It used to be a special order as part of a police car package. Now most newer family cars have a switch in the jamb, and it's often on without the driver realizing, just a "quirk of the car". Smash the window is easy, and pull the outside handle, but if the power lock was snapped shut at EMP time, that won't work. So you climb out the window, shattered temp glass is pretty harmless. It's designed to be harmless. $\endgroup$ Commented Sep 18, 2018 at 15:17
  • $\begingroup$ @Harper, they might not have a little metal button to pull up on the top of the door to unlock the door, but every new car that I have owned does have a mechanical lever that unlocks the door. I don't have a reference, but I'm pretty sure a car that could possibly lock you inside due to electrical failure would probably fail some pretty basic safety tests. $\endgroup$
    – JPhi1618
    Commented Sep 18, 2018 at 15:54
  • $\begingroup$ @JPhi1618 perhaps you did not have family cars, or, like many drivers are simply unaware of the jamb switch which disables that. Heck most don't even know how their shifter interlock actually works. I am mainly referring to rear doors in family cars (and before that police cars) where, yes, Virginia, the specific design purpose is to render rear seat occupants unable to escape the vehicle. Of course you can always bust out glass in a real pinch, so "unable" is too strong a word. $\endgroup$ Commented Sep 18, 2018 at 16:06

There are two things to be concerned about, EMP and nuclear radiation. Both will affect the engine.

At the distance you are talking about, the mechanical parts of a car are unaffected by nuclear radiation or EMP. The only part of the engine that is affected is the electronics.


One thing to consider is that the body of most cars is metal and forms a Faraday cage around the engine and all its electronics. The shell of the car will provide a lot of shielding from E-field components of the EMP. If the shell happens to be steel (as in an older car) then it will also provide H-field shielding.

For EMP specifically, there is a momentary voltage gradient throughout the space of the car. it can look like a voltage is applied on various points (according to the field gradient in the pulse). Note that the smaller the distance the smaller that voltage will appear.

The copper wiring in the car is not directly damaged by radiation or EMP. But it can act as an antenna that can gather energy and put it into circuit cards, where it can do damage.

Most modern electronics include ESD protection devices in nearly every microchip. There is also power supply capacitors on each circuit card. All of the power supply capacitors and ESD devices will actually try and locally absorb the EMP.

For highly miniaturized electronics (like integrated circuits) the effect can be quite small and won't directly do much damage. Modern CMOS integrated circuits contain opposing pairs of transistors between power and ground. Normally only one of each pair is on. But when exposed to EMP induced voltages both can turn on, causing a short between power and ground, which can destroy the chip.

For the most part, the destructive energy that kills electronics exposed to EMP comes not from the radiation itself, but rather from the batteries or AC outlets that power those electronics. Turning off the car and disconnecting the battery will drastically reduce the damage.


The fiberglass material that the circuit cards are made from is immune. As well as the copper traces and planes that form the connections in the circuit cards. Ceramic capacitors and film resistors are largely unaffected.

The only items that are really affected by nuclear radiation are semiconductors (diodes, transistors, integrated circuits). When particle radiation from an atomic detonation hits semiconductors it causes them to conduct. For diodes, the reverse leakage current increases. For transistors, they can become turned on. Unless the exposure is at a very high does rate, or for a very long time the effects will disappear once the radiation disappears.

Modern CMOS integrated circuits contain opposing pairs of transistors between power and ground. Normally only one of each pair is on. But when exposed to radiation both can turn on, causing a short between power and ground, which will destroy the chip.

With respect to the radiation, if you simply remove power from the device, then its likely that it may not suffer damage. In general electronics are usually only damaged by nuclear radiation when they have power applied. For the most part, the destructive energy that kills electronics exposed to radiation comes not from the radiation itself, but rather from the batteries or AC outlets that power those electronics.

If you knew when the blast was about to happen, then just stop the car, pop the hood, and disconnect the battery. Once the EMP has passed, reconnect the battery and you should be OK.


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