Don Shift Sends: Aboveground Radiation Protection Without Shielding
With World War III literally approaching, it’s time to discuss nuclear survival skills. Do you live in an above-ground house on a concrete slab with no basement or storm shelter? Are you wondering how you might survive nuclear fallout? Thanks to the inverse square law, you might not actually die from radioactive fallout if you’re forced to shelter in your house. There is hope for us suburbanites and us ranch house people.
Protection from radiation is achieved through three means: time, distance, and shielding. Shielding is the best method but also the most difficult to achieve because of the weight and expense of the material. Nuclear fallout protection to most means living a shelter behind thick walls of masonry or in a basement. I too struggled with this in my own examination of what to do in case of a nuclear war. Stacking sandbags might be possible, but overhead cover was a problem and the thin walls of a house do little to stop radiation.
What I overlooked is a common mistake that many people seem to make. I am guilty of overlooking it in some of my novels or applying it improperly. This is distance, properly known as the inverse square law. Plainly, radiation gets weaker the further you are from the source. A proper definition is “the radiation intensity is inversely proportional to the square of the distance.” This is true for any radiation, including the dangerous gamma radiation from nuclear fallout.
Now there will be no algebra here, but if you double the distance from the source, the strength of the radiation becomes one-quarter as intense. Ten times the distance the exposure is 100 times less. For example, if the radiation level is 100 R/hr outside the exterior wall, and you are ten feet inside the house, the radiation inside will be 1 R/hr inside. You go from a 50/50 chance of death to perhaps a slightly increased risk of cancer.
The way this works is that the photons of the gamma radiation is spreading out as it travels making it less concentrated and thus less likely to hit you. The lower the concentration, the less intense the radiation. There is more space than there are photons so what is happening is the chance of being struck is decreasing as you move away from the source. Imagine the radiation is like birdshot, except this birdshot keeps flying. Eventually, the pattern of the shot will spread out so much that the odds will get higher and higher for a duck to actually get hit.
This is why people are told to shelter in the center of buildings. Once you understand the inverse square law the advice to go to an interior room or hall and hide underneath a mattress doesn’t sound so stupid. Lower overall radiation outside really helps enhance survivability, but the point is if you can get well away from the fallout and keep the house sealed against it getting in, fallout doesn’t have to be a death sentence if you are aboveground without shielding.
Radioactive fallout is caused by surface bursts which suck dirt and debris into the fireball where it is irradiated and falls out. Most major cities will probably be hit by air bursts which stomp large areas flat and start fires, but don’t create appreciable fallout. So if you live miles away from a major urban area or non-hardened target, you should not have your house destroyed. If you live downwind of say a missile silo that required a ground burst to destroy the missile inside, you will have to worry about radiation.
For instance, those in Ventura, California, will have to worry about fallout from Vandenburg SFB if there are ground bursts, but there will be no blast damage (unless the nearby Navy bases are nuked). Check out the Nuke Map and look at your risk. As we’ll see, a lack of blast damage will be important.
Rooms
To take advantage of the inverse square law, shelter should be sought in the part of the house that is further from the outside; the most interior portion, both vertically and horizontally. How far into the house you’ll need to go is dictated by the radiation level outside. I’m working with 100 R/hr, which is a high-plausible dose. To get the 1 R/hr, using distance alone and not counting on any shielding effect from the construction material, that’s 10 feet from the nearest exterior wall or roof.
For some this could be a large room, the corner of a room, a closet, or a hallway. The protection factor will decrease the further you move towards the exterior, but overall fairly gradually. So if you aren’t at the absolute center of the house, don’t panic. Ideally, you will want a room that doesn’t have a direct line of sight to exterior doors or windows, that is a wall in between you and the outside, but again, don’t panic because a window or wall will make little difference to the laws of physics.
Vertical protection is the hardest problem because fallout will settle on the roof and radiate downward. In a one-story house, you’ll need to sit or lie on the floor for the most protection. I would get a very stout table and stack whatever dense objects I had on top and spend most of the time lying under it. In a two-story house, the ground floor is best as the second floor will give you the protection of the space of the rooms above you.
Fallout Infiltration
Note that we’re assuming that the house is intact to start with. The roof is not ripped off, the windows are not broken, and there are no holes in the wall. Broken windows can and should be boarded up or have cardboard placed over them AND sealed tightly with plastic and tape. Some structural breaches can be fixed the same way, but you should probably find an intact structure to shelter in instead.
Fallout must be kept outside. It’s not a poisonous gas, but instead bits of pulverized material down to microscopic dust in size. The first line of defense against ingress of particles is by shutting all the doors and windows. A sealed house will still admit some fallout through infiltration. Usually this is via comparatively large gaps like vents, door sill gaps, and bad (or no) weatherstripping. Smaller cracks and gaps all over the house can let in more.
Air also naturally enters a home through small cracks, gaps, and joints where floors, walls, and roofs connect. This uncontrolled air flow could be characterized as leaks. All homes have minute gaps in the construction where air moves around between the walls instead of windows, doors, and deliberate vents. One term for this is “adventitious ventilation.” In other words, all the joints that opened slightly over time or were constructed loosely. If you have a draft or bugs coming through a wall from outside, that’s what we’re talking about.
Tightly built houses need mechanical ventilation to exchange the air. A newer house will be tighter and have less leakage than a new house, generally speaking. There really is no good way to find out on the fly if your house has adventitious ventilation. However, worst case scenario, you’re probably not going to suffocate in a “tight” house with the windows closed and vents covered.
This kind of poor construction or natural aging can aid you in a fallout situation because the gaps aren’t going to admit radioactive particles into to the house very well. Some airflow will be permitted with everything closed and sealed off through these gaps. I would not rely on this and for normal living the gaps should probably be sealed anyway for efficiency and less pest intrusion.
You will need to pay special attention to the designed openings of your home to prevent gross fallout infiltration. While all homes share some features, each case will vary. Let’s look at what needs to be closed off.
The Chimney
Fallout may enter through the chimney, even if topped with a cap or spark arrestor. It is a big liability. Particles need to be trapped within the brick or steel of the chimney/firebox or stove/pipe as the bricks will offer the best shielding. If fallout enters the firebox, the radiation will come into the room at the level of the hearth. Therefore preventing fallout particles from falling into the firebox. Top and bottom should be closed, but the most accessible for average folks is from inside.
Close fireplace or stove damper. Dampers are usually closed by means of a lever at the top of the firebox. Push inwards towards the back to close, like a drawer. Typical dampers do not close tightly. The gap around the damper blade to the brick interior of the smoke chamber is ¼” (good and uncommon) to ¾” (typical).
Large particles can be stopped by wedging a carefully sized piece of cardboard into the flue, but this can come dislodged or still have gaps. You may also tape plastic on the bottom of the damper to create a seal, but note fallout will be resting inside the firebox instead of the flue.
Another alternative is to stuff the chimney above the damper with whatever you can, such as blankets pr newspapers. Only do this before fallout arrives as any radioactive particles that enter may get caught in the soot which you may dislodge.
Close any doors or vents in the face. If the face is open, put cardboard or something similar in and seal both open and glass fronts with taped plastic sheeting. Block the firebox opening with shielding such as a thick piece of steel, sandbags, boxes filled with earth, bricks, or thick books. Stoves with a tightly sealing doors should be alright as-is due thick steel construction if the chimney is closed as above.
The second and most important line of defense is the top of the chimney to prevent ingress in the first place. The problem with this is that not many people will have ladders. If you can do so with reasonable safety from both falls and radiation exposure, seal the top of the chimney in plastic. This may require removal of a cap or spark arrestor because wind tugging on the plastic may be shredded by the metal edges of the topper.
All the sealing media has to do is not come flying off in the wind and remain air and weather tight. Plastic sheeting or a few layers of thick trash bags can be folded over the top of the chimney like a bag, with plenty of overlap (at least a foot) over the sides. The overlap is then tightly tied or otherwise secured around its circumference. Bungee cords, ratchet straps, or taught rope can be used.
Make sure everything is cool before attempting anything! Clean the wood ash out of the firebox before beginning. If you are unable to do any of this and fallout enters the firebox, promptly sweep and remove them outdoors, while wearing PPE.
Note that as stoves are typically mounted further into a room, any radiation inside will enter the room from all angles of the stove, where as with a chimney roughly half will be going outside. Rooms with contaminated stoves should not be used to shelter in if possible. Be sure to remove all obstructions and sealing materials before use. Also have a professional sweep clean the chimney as soon as possible, if they still exist.
Windows, Doors, and Hatches
Sealing the windows is most important if they are broken out. If you have not replaced your cheap aluminum framed windows with double-paned insulated windows, you may have a poor weather seal and may want to seal even if intact. Tightly fitted modern windows with no drafts should do fine on their own without additional sealing.
Tape windows before a blast in a X pattern to help prevent shattering or shards, especially if they are older non-laminated panes. If you have storm shutters or can board the windows up, do so. You will need a ladder that is tall enough to get you to at least eye level with the top of the window frame of your highest window.
Seal windows with plastic sheeting and duct tape airtight to prevent ingress of fallout particles. Taping the outside of the window is best because any wind blowing against the plastic should flatten the sheeting against the window, creating a more effective seal. Sheeting needs to be securely taped without gaps or tightly stapled directly to the wall. If using staples there should be no gaps in the plastic between staples.
Aluminum siding or stucco may require furring strips to secure the plastic as it will be difficult to staple into those materials. The furring strips can go over the plastic to “pinch” it in place or the plastic can be stapled to the strips. In the pinch method, the plastic and furring has to go in at the same time. Note that in either case, the edges and gaps will need to be sealed with duct tape or caulking. For staples, the punctures from the staples may weaken in the wind and tear, so tape over those to lessen the possibility of fallout dust entering there.
If you are unable to install furring strips or staple the plastic directly to the walls, tape it to the window frame. This is a lot easier if the window frame is wide. Cut the plastic slightly larger than the glass to overlap just enough to get good contact with the tape. Tape should be on about half frame, half plastic. Be sure to cover or tape any small vents or drains in the frame.
Exterior doors should be sealed the same as windows. The last door, the one used to go back inside the house, should have the plastic secured at the top so it drapes over the door. Extra plastic should be used to allow for overlapping. One method is to weight the bottom overlap down with a hand going around the side of the plastic while the door is open. The intent it to pull the plastic tight enough that it affords some protection.
The second method is to pull the overlap in the door and shut the door on it. Tape the gap between the door and the doorframe with duct tape and optionally seal the interior side of the door with plastic. Plastic on the inside is an insurance policy to keep any fallout from getting any further into the room if the outer plastic doesn’t do its job.
Garage doors will be tricky because of their size. Replace your weatherstripping ahead of time if you can. One sign of this being a potential problem is dirt and leaves that are blown in even though the door is shut. The bottom can be protected by piling dirt up along the bottom outside, sand-filled socks intended to stop drafts, or closing the door on blankets put underneath.
Tape the gaps between the roll-up panels. Tape the top, bottom, and side gaps along the doorframe. Hang plastic tightly if you can, weighting the bottom heavily with lots of overlap extending on to the driveway. Place sheeting on the inside as well. If you can only sheet one side, the inside might be easier. You may only be able to sheet the top and sides of the garage door, but this is still okay. Be sure to seal any “suicide vents” or louvers in the garage as well.
Seal the attic hatch or access; attics will probably be the second leakiest place next to the garage as both are ventilated. Treat it like an exterior door or window. You may want to wrap duct work as well. Close the HVAC registers in each room and consider sealing them as well. Remember that contaminated attics just bring the fallout closer to your head, so treat them as part of the interior.
Vents
Homes are filled with an abundance of vents that can admit fallout and these will probably be the biggest liability you have beyond poor condition weatherstripping around the garage door. Seal all exterior vents not intended for ventilation. Vents intended for sheltering ventilation should have filters placed over them.
Some example of vents to check for are:
- Louver attic or garage vents.
- Gable attic vents.
- Soffit vents.
- Static rooftop vents, such as “Whirlybird” turbine vents.
- Heater exhausts.
- Crawl space vents (don’t let the radiation “shoot you” from below).
- Dryer vents.
- Ridge vents (which can be hard to see).
- Garage suicide vents.
Rooftop vertical vents are easily; get up there and basically bag them. Soffit vents may be small but numerous. Gable vents I would place filters over (more on this below).
Ventilation
You have to let some air in. This becomes more important the newer and “tighter” your house is built. Using the adventitious ventilation is possible in a lot of homes that are older or built cheaply with a lot of gaps, but it shouldn’t be relied on.
Frankly I would go into the attic and put a quality furnace (heater) filter over the inside of the gable vents, taping the edge gaps tightly, and do the same thing on the outside. The outside filter will be less effective because of greater exposure to the elements. Depending on the weather and degree of fallout, I may seal the southwest vent and use the northeast one because it has more wind protection.
I can then leave the attic hatch open if I want to let air come in to the house proper. We will have the protection of the rooms and hallways in between to catch any fallout that comes in. One way of moving air inside the house is to use what’s basically the sheet flapping method to generate air movement. Cresson Kearny details this well and several more efficient methods to just fan the air to get circulation going.
Probably for peace of mind I would also setup an exhaust fan to blow air out. With a proper seal and enough force, fallout will not enter against the force of the fan. If you’re hiding in a closet or have taped up a hallway with plastic, you’ll need to filter the air. Most likely you’ll be doing this if the house is breached and contaminated. You will need to construct a homemade air filter using objects around the house, which is totally possible with some imagination.
If you need to get ventilation from a window or something, open it. The higher the window is off the ground, the better as it will be further away from the majority of fallout which will be on the ground.
As long as the window is intact, leave it or the opening half uncovered by plastic. Get some sort of filter on the outside, taped up securely so all air passes through the filter. If you can’t get a filter, use bedsheets or something that will let air through, but not dust. Put this on the outside. If you can manage enough airflow, put one on the inside as well. Leave the window open until the air freshens up and repeat as necessary.
I would choose a window that is not exposed to prevailing winds nor would I open it in anything stronger than a light breeze. A strong breeze or wind may force radioactive dust in. Keep in mind that any fallout caught in the filter will stay there and be radioactive, so you should not be occupying that room and be at least ten feet away, preferably behind a wall.
In short
- Keep the fallout outside and get as far away from it inside as you can. Churches and warehouses with very high ceilings would be excellent group shelters.
- Seal off the places that air and dust (hence fallout) can enter your home. Seal only broken and poor-quality windows that let dust in.
- Plastic sheeting should be about 6 mils for the best balance between weight, durability, and flexibility, although 4-10 mils is permissible. Measure the area of all the windows and doors you may need to cover and purchase triple that amount of sheeting.
- Keep plywood or cardboard on hand to board up windows.
- Buy thick, expensive filters with the highest Minimum Efficiency Reporting Values (MERV) rating possible. Your life will depend upon it; don’t cheap out. Purchase several changes of filters to discard ones filled with contaminants. Size them for the opening you want to filter.
- Buy lots of duct tape; more than you think you will need. I’d start with a dozen rolls. Don’t buy painters tape or masking tape, buy real silver duct tape and don’t worry about ripping off paint.
- Keep a manual staple gun or two on hand with lots of staples.
- Pre-measure the most interior spaces of your house. Think of what material you have on hand to increase shielding.
- Use the Nuke Map to estimate your potential fallout exposure, blast damage risk, and an online calculator to figure out the radiation level in your interior space.
About the author: Don Shift is a veteran of the Ventura County (CA) Sheriff’s Office and is a FEMA certified student of emergency response, disasters, and history. He is the author of several post-apocalyptic survival novels about nuclear war, EMP (Hard Favored Rage and Blood Dimmed Tide), and the non-fiction Suburban Defense guide.
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Thank you Don.
Great specific tips, and very timely. Every should also secure and review Cresson Kearny’s ” Nuclear War Survival Skills”.
Not to be a negative Nelly, but the inverse square law only applies to a point, or nearly point, source. Fallout will blanket your entire roof. Distance, while good, will be reduced to shielding by air.
The good news is, fallout will only be a serious problem for those downwind of ground bursts, that is 5 – 50 miles (or so) downwind of silos or other hardened military structures. Airburst, used to burn cities and soft military, agricultural, and industrial targets, do not produce much fallout, but a much bigger shockwave moving through the air.
Your information is otherwise good stuff. But, if at all possible, don’t spend time/money trying to harden your suburban home. You can’t harden it enough to withstand a 10psi overpressure shockwave. You can stack up enough sandbags/packed earth/cinderblocks (filled with sand or concrete) to save yourself, but how much does that cost? We need to get out of the cities, and don’t move downwind of military targets.
Great advice!
My farm is rural and about 35 miles from the state capital, pop 20,000, and about the same distance from a major builder for the Navy. A decommissioned Navy P3 base is a further 5 miles beyond the shipyard. There is a larger port city, pop 75k at 75 miles that also has a large airport. Much of my selection criteria on this location was based upon many advantages in likely situations short of nuclear attack. Even so, despite being downwind in normal weather from all of these targets, my location should still be quite survivable with an expedient basement shelter, some emp protection for critical electronics, and a survey meter. Although most of these strikes are likely to be airbursts, I anticipate in terms of the worst case of ground bursts and and the heavier fallout. I keep the barn full of heavy timber and such to fashion the hasty basement shelter. It is probably a good idea to actually start setting it up.
Can you expound more on point source vs. massive contamination outside? The way I understand it is that you have essentially infinite point sources outside so that say the exterior wall would be a linear source, and of course you’d have overhead and danger from the other three sides.
I wouldn’t worry about your airport; not enough nukes to go around. We don’t disperse bombers like that anymore. I grew up very near a former ADC base and within the blast radius. They wouldn’t bother with it now and I had to stretch in my fiction to get the two local Navy bases nuked. Most people away from major military bases or 10 miles or so outside big city centers should be okay from blast damage.
Good info.
I live in a convert pole barn that has a hall way running down the middle. All outside walls are, from inside to outside, are wood, drywall, insulation, metal pole barn siding and a wood facade. Almost a foot thick.
All the outside doors are typical pole barn models. Poorly made hollow metal. Will stack furniture against them.
Going to bunker in the hallway which is about 12 feet to the roof peek. I will be stacking up all my can food, ammo cans,water barrels and anything else along the inside rooms against the hallway walls. Appliances will be stacked at the end of the hallways for mass.
One thing, if you have a ridge vent, make sure it has a extra filter for keeping out dust. Some don’t have this. And a 50foot ridge vent would be a hell of a thing to have to cover.
And get a pdf of “Nuclear War Survival Skills” and ki4u.com-The Good News About Nuclear Destruction.
Hopefully, fallout here in Northern Lower Michigan will be light.
There is always that, but can you imagine an enemy of the U.S. does this to a few of the more strategic cities and then watches a place like say Minneapolis just go into a psycho and pyromaniac protest like they did a couple years ago. An enemy of the U.S. would likely just sit back and laugh as a city like that destroys itself.
Does anyone know if lead based paint operates as a decent shield for outer walls?
http://www.ki4u.com/guide.htm
“The thickness in inches needed to cut the radiation down to only 1/10th of its initial intensity for different common materials is: Steel 3.3″, concrete 11″, earth 16″, water 24″, wood 38″. The thickness required to stop 99% of the radiation is: 5″ of steel, 16″ of solid brick or hollow concrete blocks filled with mortar or sand, 2 feet of packed earth or 3 feet if loose, 3 feet of water. (BTW, lead is nothing special, same as anything else pound for pound.)”
I saw that Simpsons episode too. It works only in Springfield. the amount of lead in the paint shielding wise is non-existant.