Bottom line: To protect a raised garden bed from frost, use a space blanket. Or, better yet, use a piece of construction radiant barrier. Same idea, but much tougher material. Alternatively, use glass jars to cover individual plants.
I tested these methods, using temperature data loggers, and you can get anything from 5 to 10F of frost protection from them. And all of them work the same way, by trapping the heat energy from the (relatively) warm underlying soil, that would otherwise be radiated away into the air.
By contrast, a lot of advice you’ll get on the internet — and a lot of frost-protection products offered for sale — don’t do much. In this post, I get around to testing (and flunking) the use of a sheet of polyethylene plastic as frost protection.
Free advice is worth what you pay for it. If you’re lucky.
The internet offers plenty of advice on protecting your vegetable plants from frost.
Some of that is useful, but much of it is wrong. Or, if you wish to be more charitable, much of it is almost, but not quite, completely ineffective. It’s folklore that somebody read somewhere, and passed it along without testing it to see how well it works.
Is anyone surprised?
That includes the commonly-cited advice to cover your tender plants with floating row cover, or to cover them with a frame draped with plastic sheeting (e.g., polyethylene sheet) when there is threat of frost.
Neither of which works worth a damn, by the way. Better than nothing, but not by much. Which I will show, below, using temperature data loggers to test that empirically.
In this post, I’m going to finish what I started last year, regarding the use of radiant barrier material for frost protection. Unlike a house (say), on a cold, clear, still night, a garden bed loses far more energy from radiation that from conduction. Once you’ve established a pocket of still air over your bed (and so, stopped losses via convection), you get far more bang-for-the-buck by preventing heat losses via radiation than you would by focusing solely on preventing losses to the atmosphere via conduction. Hence the use of radiant barrier material.
For those of us whose understanding of heat losses comes from insulating our homes, this may seem counterintuitive. Just keep re-reading the “Unlike a house” line above, until it sinks in. For a garden bed, the relative importance of energy loss via radiation and conduction is flip-flopped, compared to a house.
The practical upshot of that is that if all that stands between your plants and a frosty death is a sheet of plastic, consider tossing a space blanket over that. That thin layer of radiant barrier material will substantially add to the minimal frost protection offered by a plastic sheet alone.
To be clear, I didn’t think up that advice. I got the idea from a document that ultimately comes from the Colorado State University extension service (.pdf). That’s seriously useful advice from people in a seriously cold climate.
Edit: Separately, a mason jar (or any glass jar) also provides excellent frost protection for individual plants. For the same reason — it blocks long-wave infrared radiation. I tested this in Post #G22-006.
This weekend’s problem
Given how quickly the weather can turn hot in this area, I decided to get the earliest start possible on some cool-weather crops. Soil temperatures in my raised beds were at or near 50F a few weeks ago, plenty warm enough for some cold-weather crops. So I planted some peas, beets, turnips, and potatoes, even though we were more than a month away from our “last frost date”.
These have now produced nice green shoots. And, of course, now we’re going to get a frost. And yet, I’m not worried.
It’s not like I didn’t have plenty of warning. Two weeks back, the long-term weather forecast for my area gave a warning of likely frost this weekend. True to the forecast, the National Weather Service is now calling for successive nighttime lows of 27F and 26F in Northern Virginia, before returning to above-freezing temperatures.
I’m not worried, because I have my frost protection already worked out. Tested as to performance (Post G21-018). I should get adequate protection for this freeze event just by covering my raised beds with cheap, sturdy radiant barrier material. (It’s the same concept as a space blanket, but a lot tougher.) But if I’m feeling particularly paranoid, I might throw a few tens of watts worth of electric night lights under that cover, just for insurance, left over from a prior experiment (Post #1412, heated faucet cover). An idea which I also stole from the U. Colorado extension service document cited above.
In this the rest of this post, I’m going to recap the radiant barrier method of frost protection, and then push a bit beyond that. At some point, I’ll come up with a raised bed cover that provides both insulation (against loss of heat energy via conduction) and radiant barrier (against loss of heat energy by radiation). For now, though, I’m mostly going to walk through why radiant barrier is far better than either plastic sheeting or floating row cover, for providing frost protection to your sensitive plants.
Part 1: The tin-foil-hat gardener.
Above, you see one of my raised garden beds with pieces of woven polyethylene radiant barrier clipped to the top.
I went through the some of the science and math behind the use of a radiant barrier for garden beds in Post G21-015. Briefly:
While a traditional tin-foil hat serves to block alien mind control rays and other forms of incoming radiation, garden radiant barrier seeks to block outgoing radiation. In particular, it serves to prevent heat energy in the garden bed from radiating away into space. On a cold, clear night, those radiant heat losses would be large, and preventing them from occurring keeps the bed warmer than it would be, without the tin-foil-hat. So let me start this off by telling you all that you really need to know about radiant barrier.
Radiant barrier greatly reduces heat losses through radiation IF AND ONLY IF at least one clean side of the barrier faces an air gap of at least an inch.
(Or if it faces a vacuum, if you happen to be NASA. Hence the origin of the term “space blanket” for one commonly-available radiant barrier material.)
In particular, it works just as well if either side faces an air gap. Either the one facing the warm object, or the one facing the cold exterior. Which means that your intuition that this works “like a mirror for heat” is only partly right. That’s OK. Just follow the rule and it doesn’t matter if your intuition fails you. This is physics, and nothing changes just because you can’t quite get your mind around it. That’s just the way it is.
For you who need a more practical example, consider Reflectix water heater wrap, sold as “radiant barrier insulation”. The shiny outside serves as a barrier to the emission of infrared energy. Touch it and you’ll feel that it’s warm. And yet, it’s doing its job. It’s warm precisely because it’s difficult for heat energy to radiate away from that shiny, “low-emissivity” surface.
For those of you whose bent is more historical than scientific, look up pre-technology ice making in India and Iran. Under the right circumstances, upward radiative losses from a pan of water can result in the production of (some) ice even when the ambient air temperature is above freezing.
Note that the rule is very specific: This shiny material must face an air gap on at least one side.
Get it dirty, and performance degrades. Why? Because dirt is perfectly capable of radiating heat away. Transfer the heat from the aluminum to the dirt via conduction, and off it goes.
Sandwich it between two other layers and it does nothing. Why? The other materials don’t prevent radiation. They are perfectly capable of radiating heat. Conduct heat through this material, radiate it away using some other material, and the heat is gone.
Use it as a ground sheet for your sleeping bag, ditto. No air gap. Lay it on the ground and cover it with snow, likewise (I think it would be no better than having a simple plastic sheet under the snow.)
You get the drift. One clean side must be open to at least an inch of air, NASA excepted.
Choice of material
Now that I have that out of the way — one clean side must face some sort of air gap — let’s proceed.
What you see in use above is a tough woven polyethelene material, with an aluminized coating on both sides. It’s used in building construction. Here’s an example from Amazon, 62 feet of 4′ wide material, for $40 (reference). At 20 linear feet to cover a 4’x16′ bed, that works out to be about $13 to cover one 4’x16′ bed.
This stuff is very tough and reasonably cheap. Given that I use it just a few days a year, I am sure it will last decades.
There are plenty of easily-obtained alternatives for covering your beds with radiant barrier material. Really, all you need is a thin sheet of something that’s extremely shiny. Think “space blanket”.
But I think they all have significant cost or performance drawbacks relative to woven-polyethelene radiant barrier sold for building construction.
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- Space blankets work fine (I tested that), but they tear incredibly easily, particularly when clamped in place on a windy day. In the long run, they’ll cost more than woven poly radiant barrier. A typical thickness for space blankets is 12 microns, or about 0.5 mils (thousandths of an inch) thick.
- You can buy large sheets of aluminized mylar, anything from “space blankets in bulk” to sturdier, thicker material. Here’s some that’s 2 mils thick, and costs somewhat more than half what the woven radiant barrier costs (reference). The thicker material is tough, but my experience is that it doesn’t like to make the sharp-radius curves required to clamp it to a flat surface. I suspect (but don’t know) that this wouldn’t last as woven radiant barrier.
- Reflectix or equivalent should work well, but looks like it’s almost 10 times as expensive as woven poly radiant barrier. Reflectix is a tough bubble-wrap type material, shiny on both sides. Presumably that would give both radiant barrier and some modest insulation against conductive losses through the top of the bed.
Performance
Last year I did a series of experiments to show that this works. I had two cheap temperature loggers — digital recording thermometers. I left half the raised bed uncovered, and logged the overnight temperature of the uncovered and covered portions of the bed.
Here are the results:
A layer of floating row cover does nothing whatsoever. This was thin row cover, but this is also just about exactly what I expected.
A covering of literal space blanket (alone) raised the overnight temperature by about 5 degrees F:
Putting some gallon jugs to warm up during the day, and then covering with space blankets at night, raised the overnight temperatures by 10 degrees F. This had about one gallon per 8 square feet, and the gallons were warmed to about 70F by the end of the day. The results below were completely consistent with the thermal energy stored in the water, relative to the energy storage (and poor conductivity) of the underlying soil bed alone.
Doing the same, but using that heavy-duty woven polyethylene radiant barrier instead of flimsy space blankets raised the beds an estimated 12 degrees F overnight. (Estimated because the battery on the control temperature logger died overnight.)
And now, a new test. You’ll often get advice to protect your plants from freezing with some sort of frame (e.g., “hoop house”) covered by a piece of plastic sheeting. So let’s now test that.
(And, to be honest, maybe the good results above were purely from covering the bed with some type of plastic sheet. Maybe the radiant barrier property of that sheet is just a red herring. My earlier calculations say that can’t plausibly be true, but that still ought to be tested empirically.)
It’s not entirely implausible that a plastic sheet would provide some protection. A single layer of polyethylene sheet should add a roughly R 0.85 (U.S. units, not comparable to S.I. R-values). But that plastic sheet is essentially transparent to infrared, and so provides no radiant barrier whatsoever.
I addressed this question, in theory, in Post #G21-015. At that time, all things considered, I figured I would need something like 60 gallon jugs of 70 F water, to keep the garden bed 10 degrees F warmer than ambient, on a cool night, with plastic sheet alone.. Roughly speaking, a gallon jug every square foot.
Here’s a picture of the setup. I have one data logger under that tightly-tucked plastic sheet. Most of the sheet sits well away from the bed. And a second data logger in the uncovered portion of the bed.
And below you see the results. The side of the bed tightly covered in plastic sheet was less than 1 degree F warmer than the un-covered side.
Summary and further reflection in the performance of unheated plastic greenhouses.
The upshot of this is that at least two common bits of internet advice for cheap frost protection seem to be more-or-less worthless when actually put to controlled trial. Neither floating row cover nor a sealed air space covered with polyethylene plastic was able to achieve even 1 degree F of warming, on average, of the course of a night.
So, despite all the customer testimonials, I remain skeptical of the idea that you’ll be able to save your plants from a hard frost something like this:
Source: Amazon.
Or something like this:
Source: Amazon.
On the latter, real growers understand that. Go on YouTube, and you can find plenty of seemingly reputable gardeners who have measured the impact of their unheated greenhouses and will tell you that the nighttime air temperature in the greenhouse is essentially no different from that of the outside air. (e.g., just over four minutes into this episode of Gardener Scott):
If you have enough thermal mass inside the greenhouse, and the area of the walls is small enough relative to the enclosed volume (i.e., the greenhouse is large), and you have (say) a double-walled greenhouse with two layers of plastic and so much higher insulating value for the walls, then you might get several degrees of nighttime warming.
But a two-foot-tall hoop house covered by a single layer of plastic isn’t going to do much. At least, that’s what my experiment suggests.
There may be some anti-frost advantage to the hoop house, in that the higher daytime temperatures — when the solar energy does drive the interior temperature well above ambient — might heat the soil enough to provide additional energy release from that warmer soil at night. So maybe a tiny hoop house, in place day and night, might serve as enough of a solar energy storehouse that there is some material frost protection.
That said, I doubt it. My soil temperatures right now in that bed are around 50 F, but the air above the bed was essentially no different from the ambient air temperature. I can’t believe that another 10F or so in soil temperature would turn that situation around.
That said, I haven’t tested that, and probably never will. I don’t use cold frames or hoop houses because, in my experience, as an inattentive gardener, I always end up cooking my plants, one way or the other. All it takes is one unseasonably sunny and warm day, and a lack of attention, and the season’s growth can be baked to death in an afternoon.
Finally, one way in which a small single-wall hoop house can provide significant protection is in snow. If it gets covered in snow, the snow layer acts as insulation. This is no different from unprotected plants, who are more likely to survive cold temperatures if buried in snow than if exposed to the air above the snow.
I don’t deny that plastic-covered hoop houses have value. They speed growth by raising daytime temperatures well above those of the ambient air. Within reason, higher temperatures mean faster growth, all other things equal.
But if you’re going to spend $40 on a small plastic hoop house, spend an extra $2 for a space blanket to cover it in case of unexpected frost. The single wall of plastic, by itself, seems to be good for maybe 1 degree F of frost protection. Add a space blanket radiant barrier should boost that to at least 5 degrees F of protection.
Extras for experts: Wall of water and glass cloche
There are at least two other commonly-suggested ways to protect plants from freezing (other than literally heating the space the plants are in).
One of those — the Wall O’ Water (r), has physics that are completely obvious.
But the most time-honored of all – the glass cloche — is a little harder to figure out.
First, it’s no secret how a “wall of water” device can protect plants from freezing. These provide a large thermal mass in the form of 2″ wide plastic tubes filled with water, forming a deep, narrow chamber that protects the plant from excessive heat losses from convection. That mass heats during the day, radiates at night, and keeps the interior of the structure above freezing even in the face of a hard freeze.
Source: Wall-o-water.com. Accept no substitutes
Figuring out why a cloche works is a little harder. Glass choches have been in use for so long — and would have been so incredibly expensive in the past — that I have no doubt that they work to some degree. It’s just not clear why they work.
A traditional cloche is a heavy piece of glass, roughly in the shape of a bell. And yet, I’m pretty sure that unlike the Wall O’ Water (r), these don’t work by thermal mass. Near as I can tell, a mid-sized garden cloche only weighs about 6 pounds. Moreover, the specific heat of common window class is only about 0.2 (reference). As a result, a typical garden cloche would only retain as much heat as roughly 1.2 lbs (or a little over one pint) of water.
N.B. specific heat is the amount of heat energy required to raise a given weight of a substance by a given temperature. In the U.S., God help is, that’s expressed as British Thermal Units required to raise one pound of a substance by one degree F (whilst proceeding at a speed no greater than 10 knots per fortnight). Under that system, water always has specific heat of 1.0, as that is precisely how the BTU is defined.
By contrast, the specification for the genuine Wall O’ Water (r) say that it takes more than 20 pounds of water to fill it (reference).
So, what appears me to be a typical glass cloche has only about 5 percent of the thermal mass of a Wall O’ Water. Moreover, people claim that you can use a mason jar as a cloche — just place it atop your plants if a nighttime frost is predicted. Surely a thin-walled mason jar has next-to-no thermal mass. A thin-walled mason jar surely has too little thermal mass to matter.
Instead, I wonder if the effectiveness of the glass choche is due to the spectral properties of ordinary glass. Glass is transparent to near-infrared — what you’d perceive as the warmth from a glowing filament, say. But glass is opaque to medium and far infrared — the type of heat radiation that would dominate the spectrum of infrared given off by soil.
Among other things, this is why infrared cameras (e.g., a FLIR camera) do not have glass lenses (reference). In the temperature ranges where a FLIR camera might be used — such as thermal imaging of a house to look for heat losses — glass is more-or-less completely opaque. In fact, FLIR cameras cannot see through ordinary window glass for the same reason, and by report, window glass appears both opaque and reflective when viewed by a FLIR camera (reference).
And so, in the end, I suspect that my sheets of radiant barrier and a glass cloche work by the same principal — they both reflect the long-wave IR radiation that is given off by warm ground. By keeping this energy from escaping, and maintaining a still air pocket, they keep everything inside that air pocket materially warmer than the outside air.
I guess, as I put the tin-foil hat on my beds for tonight’s freeze, that’ll be another thing to test. Two temperature data loggers side-by-side, one under a mason jar, one not. I’ll report that out tomorrow.
