Guest Post by Willis Eschenbach
I grew up on a remote cattle ranch surrounded by miles of forest, far from street lights. The nights were large and silent and very dark when there was no moon. But when the moon was full, the forest at night was full of life. It was clear that the moon had a huge effect on the animal life. The farmers in the area often planted by the moon. Whether that did any good I don’t know. I do know that the moon rules the ocean, though. When I fished commercially for anchovies off of Cannery Row in California, we’d take a week off during each full moon. You couldn’t catch the anchovies during that time, they were too skittish. And the difference between night diving with and without the moon is startling.
When I was younger, I read in several places that the moonlight doesn’t influence the weather. What the sources said was that it was just too weak to affect the temperature. Heck, you can find people making that claim today. There was no scientific evidence for a detectable effect of moonlight on temperature until 1995, when an article in Science magazine called “Influence of Lunar Phase on Daily Global Temperatures” (paywalled, as usual) said that their comparison with lower tropospheric temperatures showed a temperature difference between full moon and new moon of 0.02°C.
What does that have to do with the moon wind? And what is a “moon wind” when it is at home, anyhow? Well, when I was younger, I once sailed across the Pacific as the first mate on a fifty foot (15m) gaff-rigged staysail schooner. The skipper and I split the navigation duties. This was well before GPS, so the navigation was all done with a sextant and a chronometer.
The skipper took the noon shots, the ones that firmly establish the latitude (north-south). I took the star shots at dawn and at dusk. The navigation wasn’t done while someone else ran the boat. In the morning watch, I was usually the only one awake. I’d set the sails to where the ship would self-steer, and then take the sextant shots. In the evening, the other three guys would usually all be up, but the drill was the same. Self-steer, and sextant.
Sailboats are sloooow, a typical day we would make maybe a hundred miles, less when there’s no wind, and the Pacific is very wide. As a result, I got to watch lots of sunrises and sunsets, plus taking in a lot of late-night skies sitting on deck talking story with the boys.
Including the obligatory breakdowns, we were four months at sea. As day followed day, I became more and more attuned to the cycles of the weather. One of the things that I noticed was what I later found out was called a “terminator wind”. Great name, it sounds ominous. I didn’t know that at the time, so I just called them the “dusk wind” and the “dawn wind”.
A “terminator wind” is a wind that blows across the “terminator”, the moving line on the earth that divides day from night. The sun heats the air on the day side of the terminator line. The heated air rises, and cold dense air from the night side of the terminator flows in to replace the rising heated air on the day side. As a result, the terminator wind always blows from night to day. This leads to a morning/night difference. In the morning the dawn breeze blows from the dark areas further to the west of my location, and towards the sunlit areas east of my location where the sun has already risen. In other words, the dawn breeze is always and forever a west wind.
In the evening, on the other hand, the sun has set in areas to the east of my location. So an east wind blows from the nighttime there, towards the west, where the sun still warms the earth. As a result, the dusk breeze is always and forever an east wind.
The opposite direction of these two winds leads to a curious phenomenon. This is that for relatively steady overall winds, the dawn and dusk winds will alternately oppose the underlying wind, or it will increase the underlying wind. This is most visible when there is a light constant east wind. At the dawn breeze is a west wind, so it opposes the light east wind and leads to a short period of calm around dawn. At dusk, on the other hand, the terminator wind blows from the east, so the dusk breeze reinforces the underlying east wind and leads to a brief gusty period around dusk … and if there is a light underlying west wind, the opposite is true.
Now, here is where the moon came in. After I’d spent enough nights at sea, watching the comings and goings of the moon, I noticed that the moon has a terminator wind just like the sun. I started calling it the “moon wind”, I didn’t know from terminators, I was on a boat in the middle of the sea, I made up a name. I first noticed the moon wind in the doldrums, where the air is often quite calm, with no wind of any kind. In those peaceful conditions, with the boat not moving at all, the terminator wind from the moon is quite apparent … at least it is to sailors hoping for any kind of wind in the doldrums. It obeys the same rule as the dusk and dawn wind in that it always blows from areas with no moon to areas with the moon. Of course, it is much weaker, and only detectable on calm nights. On a calm night it is a sliver of a breeze, just enough to send small wavelets shimmering in the emerging moonlight.
During the time before the full moon, when the moon is waxing, we have only moonsets at night. As a result, before the full moon, the moon wind is always an east wind. After full moon, we only have moonrises at night, so during that time the moon wind is a west wind.
Since that time, I’ve occasionally noted the moon wind on land as well. You need near full moon, preferably a large flat open area, and fairly calm conditions to be able to detect it. It helps to know what you are looking for. In light east wind conditions after the full moon, for example, the west wind at moonrise opposes the underlying east wind, and is seen as a brief period of calm around the time of moonrise. But if the underlying wind is from the west, the wind at moonrise will reinforce that west wind and lead to a brief gusty period around moonrise.
I bring all of this up for several reasons. One is to point out that the earth responds to a very slight change in conditions. We routinely overestimate the strength of the light coming from the moon. The light from the moon is about a million times weaker than the light from the sun (with a full-moon peak at about 0.006 W/m2). The infrared from the moon’s surface is stronger than that, it’s somewhere around 0.03 W/m2. The sum of the two is only a bit above 0.03 W/m2, that’s thirty milliwatts per square metre, a very tiny amount in terms of the global energy budget.
And yet despite that energy being so small, you can still feel the moon wind at the moon’s terminator line, a wind that arises from that tiny energetic addition. What an astounding system. It is so stable that the global temperature hasn’t varied more than ± 0.5% in the last millennium, and despite that amazing stability, it is also so delicately balanced that thirty milliwatts of energy are enough to make the moon wind come up and shiver the silvery ocean with its breeze …
I also bring this up to point out that there is still a whole lot that we don’t understand about how the weather and the climate work. Let me quote the conclusion of the 1995 Science article:
The existence of an identifiable relation between lunar phase and global temperature begs the question as to its fundamental cause. Presumably the causal factor is lunar, but, as pointed out by researchers examining the relation between precipitation and lunar phase (3, 4), this cannot be demonstrated by statistical analyses alone. Other scientists who have examined the lunar influence on various climatic variables have suggested several causative linkages.
For example, increased thunderstorm activity near the time of the full moon may be related to lunar distortions of Earth’s magnetic tail (5). Another hypothesis advanced to explain the precipitation-lunar phase relation involves the lunar modulation of meteoritic dust (2). Others have speculated that lunar tidal changes could influence Earth’s basic atmospheric circulation patterns, in particular,the position of the subtropical high- pressure belts(24).
Also, with respect to global temperature variations, a full moon results in an increased solar load due to the moon’s reflection as well as to an increase in infrared emission from the moon’s surface. The infrared flux to Earth is five orders of magnitude less than the direct flux from the sun, whereas the shortwave flux is six orders of magnitude less than the direct flux from the sun (10, 25); the 0.02 K modulation in temperature identified in this study is correspondingly five orders of magnitude less than the mean lower-tropospheric temperature. Feedback responses of global temperature to potentially lunar-related variations in other climatic parameters, such as precipitation, cloudiness, and thunderstorm activity, may also account for the lunar effect on global temperatures.
Our analyses show a significant empirical relation between lunar phase and daily planetary temperature over the past 15 years. The lunar phase appears to produce a modulation of approximately 0.03 K in the lower troposphere, with the warmest daily temperatures over a synodic month coincident with the occurrence of the full moon. The results not only confirm the suspicions of many past scientists but also suggest that the daily global temperature measurements are quite accurate. Most important, lunar influence is identified as another potential forcing mechanism to consider in the analysis of variability in the short-term, global temperature record.
Finally, I bring all of this up to remind myself of why it is that I took up the study of the weather and the climate—because I greatly enjoy being out in the weather, experiencing its multifold phenomena, and struggling to understand why it does what it does when it does it.
And so that is my wish for all of you— calm starry nights outdoors, good friends, and a glass of grog, with the moon a pirate’s silver coin rising out of the ocean, and the moon wind to blow your ship of life to the port of your dreams …
w.
NOTES:
I have calculated the strength of the moonlight by multiplying the moon’s albedo times the TSI times the cross-sectional area of the moon. This gives something approximating the total luminance of the daylight side of the moon, in watts. I then divide this by the area of a hemisphere whose radius is the earth-moon distance, in square metres. This gives 0.006 W/m2 as an estimate of the strength of the moonshine.
For the IR a similar procedure is followed. The illuminated side of the moon has an average temperature of around 60°C (this is calculated as the fourth root of the average of the temperature to the fourth power). I converted this to W/m2 using the Stefan-Boltzmann equation with an emissivity of 0.95, and multiplied it by the cross-sectional area of the moon to give something approximating the IR luminosity of the moon in watts. Then I followed the same procedure as with the sun, dividing the total IR luminosity by the area of the hemisphere with radius equal to the earth-moon distance. This give 0.028 as an estimate for the IR from the moon.
These figures are in agreement with the estimates that I have found in the literature for those two variables, moonlight and moon IR. Note that there are a variety of simplifying assumptions in the calculations, as I am only interested in a rough calculation. Here are the figures I have used:
Moon Polar radius, 1736, km Moon Bond albedo, 0.11, units Solar irradiance, 1367.6, W/m2 Moon Cross-section, 9,467,805, sq km Moon Cross-section, 9.46781E+12, sq m Moon's Shortwave Luminosity, 1.42472E+15, watts Earth-moon distance, 378000, km Earth-moon distance, 3.78E+08, m Hemispheric area with earth-moon radius, 2.24E+17, sq. m. Lunar reflections at earth's surface, 0.006, W/m2 Moon surface temp., 60, °C Moon emissivity, 0.95 Moon's day-side average radiation, 663.54, w/m2 Moon's longwave luminosity, 6.28225E+15, watts IR at earth's surface, 0.028, w/m2 Total energy (short + longwave), 0.034, w/m2
… from Willis’s upcoming autobiography, entitled “Retire Early … and Often” …
I wonder if there is another moon effect. Looking at temperature anomalies in the El Niño regions 1 – 4, there are waves rather than loops in the current. Similar-looking features occur in the Agulhas Current off Mozambique and South Africa. These waves seem to occur on a time frame of about 2 weeks. Is the lunar cycle affecting the wind pattern, and therefore the upwelling pattern, and hence the apparent waves in the temperature anomalies?
Dr. Svalgard
Actually, not. The earth-moon orbit the barycenter of the system consisting of the sun, earth-moon, mercury, venus, mars (and its moons), jupiter, et. al., etc.
Thanks Willis. My God, I can hardly believe it, but somebody has finally explained this to me!
As a young mineral exploration geologist in charge of a 170,000 sq km project looking for base metals in a vast West Australian Proterozoic sedimentary basin in the early 1980s, I spent two and a half years of three week-on/1week off stints, ‘fly camping’ in the bush: inching my way across a vast, empty landscape in a 4 wheel drive by day, and sleeping under the stars at night, whilst mapping and sampling the stratigraphy of a huge ancient marine basin.
At night I would usually pick some sort of vantage point to camp on, eg. one of the many flat-topped mesas, from which you could see the landscape below by moonlight and hear the dingos and feral donkeys down there in the creeks as youi went to sleep, and wake to the squarking of flocks of cockatoos if there was any water in them.
And the one strange phenomenon that I always noticed and could never explain was the way that, long after sunset, when the searing heat and incessant flies of the day had subsided to a cool, stillness and we where sitting beside a glowing campfire, whenever the moon started to rise, a cool breeze sprang up from nowhere and blew throught the world for ten or fifteen minutes, and then died just as suddenly as it appeared, once the moon was fully above the horizon.
I cannot remember now whether it came from or blew towards the direction of the rising moon, but it was so obviously a phenomenon of moonrise that I always thought of it as the moon wind myself. And now here you are, explaining it.
I can still see that full moon from the ragged edge of the flat sandstone mesa cap, and the silver-lit, ghostly landscape of creeks and gum trees down below me on the very first night that it happened.
Larry Kirk says:
December 25, 2012 at 7:00 pm
Glad to find another man who has experienced the moon-wind. It appears, from the quality of your prose, that the life lived far enough out on the edge to allow you to notice the moon-wind has ruined you, just as it has ruined me, for more mundane pursuits …
All the best,
w.
Interesting. I don’t know why I never noticed this before. Willis might know the place I spend alot of time at, its a medium size guitar shaped dry lake in Kumiva Valley, south of the Black Rock Desert, and just south of the Lava Beds. I like it there because generally there is no wind at night, in fact late night is almost always dead still. But, at sunset, the wind can roar at a pretty good clip until about an hour after dark at which point it stops dead. In the dawn, there is always a little breeze (but not nearly like sunset), before once again it stops dead..I assume the lesser wind is because the temperature difference is not as great between the light and dark in the morning…at sunset in the low humidity atmosphere you can literally feel the temperature drop). I have never noticed the moon breeze, though I have never thought to look. Next time I get out there, a couple nights after full moon, I will definitely check this out. The moon would have to rise later than the normal wind stop to be noticed.
mike g says:
December 25, 2012 at 5:37 pm
Actually, not. The earth-moon orbit the barycenter of the system consisting of the sun, earth-moon, mercury, venus, mars (and its moons), jupiter, et. al., etc.
Many people think so, but it is nevertheless wrong. These people cannot be convinced by the mathematics of the situation, but occasionally might understand measurements. The total solar irradiance measured at the Earth is a sensitive measure of the distance to the Sun, and that distance shows that the Eat-moon does not orbit the solar system barycenter [and why should it?]. To get a feeling for the physics, ask yourself if the space station orbits the center of the Earth, or the barycenter of the Earth-moon system. Or think of a binary star system [where the system barycenter is halfway between the two stars. Now add a planet in a tight orbit around one of the stars and convince your self that the planet orbits its star and not the system barycenter.
You one crazy sailin’ man, Willis, with the soul of a poet.
Possibly a way to determine if the lunar wind is radiation or tidally induced would be to see what happens when the moon is in its last quarter. Rising after midnight the crescent moon would be reflecting with less radiative intensity.
Another lunar anecdote, I love the way a full moon in winter mimics the sun’s summer path.
Really nice post, Willis. I’ve never heard of the terminator winds of sun or moon before. I have known two sailors who were Physics profs; if and when I see them again, I;ll have to bring this up with them.
Willis,
My goodness,
What a beautifully written romantic piece, and one that probably includes a wealth of scientific information.
I’ve never had the pleasure of sailing the Pacific, but you made me feel the solid heat of the doldrums as well as the relief of a gentle wind when the air movement returns.
What a life you have led!
Your observations about lunar wind (and the negative responses thereto) remind me of how the observations of ancient farmers regarding the circulatory systems of animals were received – and rejected – by the academics of their day.
I have no idea if you are correct or not about the lunar wind, but what an interesting avenue of study. It’s a shame that the academics of today are so close-minded.
By the way, I have a pet theory that the interaction of a large moon (like ours) with a somewhat larger planet (like ours) might be the catalyst for life, given that all the other necessary components for life on the larger sphere are present.
Do you think academics are ever going to look at that idea?
Take care – and keep writing. I find your ideas fascinating.
Willis, I think you have to be pre-ruined to go there in the first place, most pleasantly so! Best regards, Larry Kirk.
willis
i was lookig for poems about the moon wind a I am sure I have read some. Instead I came across this from a balloonists site; see item 6
http://windwisdom.net/
I will still look for a poem though as a moon wind deserves a non technical rsponse as well as a practical ne
tonyb
I wanted to read more so googled “terminator wind” – I get results for wind-up Terminator dolls!
Interesting reading, thanks Willis.
Page488 wrote, “By the way, I have a pet theory that the interaction of a large moon (like ours) with a somewhat larger planet (like ours) might be the catalyst for life, given that all the other necessary components for life on the larger sphere are present.
“Do you think academics are ever going to look at that idea?”
Some academics have argued that the moon helped life arise on earth, among other effects, through the enormous tides during the Archean Eon, when the moon was so much closer to our planet. It also helped stabilize conditions here & absorbed many bolides which otherwise would have hit earth, promoting the evolution of more complicated organisms.
But at this point, no one can be sure that life developed here or arrived on impactors. Ice has recently been shown to catalyze abiogenetic reactions essential for life as known on this planet. Some meteorites contain many complex organic compounds. Whether the tiny structures observed on the Martian meteorite found on Antarctica are fossils of living things or not remains debatable.
My guess is that simple lifeforms develop on many worlds, with or without moons, including on moons themselves. Earth however provides particularly salubrious habitats. Life may in fact be inevitable in certain energetic environments, given the rules of our universe.
Energy from moon light will spin a radiometer. So too will the light from the dense arms of the Milky Way. You can measure the change in energy level that accompanies the rise of the galactic center above the horizon. The energy increase is quite obvious. Why would something as big as the earth not be affected? All incoming energy is important to the climate when considered over time. Great story well told, Willis. Nature seen from a pitching deck is never what you see in a book or magazine.
Great post. You added another layer to my knowledge base. Like you, I am (was) a navigator back in the days where celestial observations where the navigational mainstay. However, while you were about as low and slow as it gets, I was high and fast. I crossed from Honolulu to Guam in about eight hours. I never knew such subtleties existed. Having made that crossing numerous time I noted an anomaly you may or may not have spotted. Between Honolulu and Guam there seems to be a magnetic distortion that causes magnetic compasses to deviate from the expected magnetic variation. I always kept a close eye on the heading of the aircraft by celestial means while making that crossing. Invariably, the mag compass would slowly deviate to as much as three or four degrees out there about half way through the crossing and then return to “normal” as we approached our destination.
Having said that, the layer of knowledge you gave made me think of the ancient Polynesian navigators who read their surroundings even more keenly than you. By the accounts I’ve read their navigation skills included sky conditions, sea conditions, and bird flight patterns that accompanied the more basic steering cues they received from the night sky. They surely were aware of the terminator winds.
I have always wondered what drove those stone age people to cross thousands of miles of open ocean and how did they know that there was some destination out there ahead. One theory I’ve read is that the Pacific Golden Plover gave them a hint that there were other lands out there someplace. The Golden Plover migrates from the various islands of Polynesia and Micronesia clear up to Alaska, where they nest each summer. Theory has it that the ancients followed the flight path of those birds and found what became known as the Hawaiian Islands. Having seen some of the indian cultures along the Pacific Northwest coastline, clear up to Alaska, I have been struck by the similarities in some of the customs and traditions of the two seemingly separate groups. Especially, those totem poles I’ve seen villages of those Pacific Northwest indians sure remind me of the Polynesian tikis both in appearance and style.
The irony would be delicious if it turns out that the alarmist’s got the moon wrong, after years of yelling that “its not the sun”.
Willis, very interesting and fun as well. Thanks and Merry Christmas.
This reminds me of many things told to me by an older friend from Oklahoma about the factors causing infiltration of rainwater into the soil. We all know of gravity and capillary forces terms. But he spoke of observations during rainstorms in OK, where cold fronts can move rapidly, of the influence of barometric pressure as well. I will have to think about it and see If I have any correspondence still existing from the 1980’s dealing with his observations.
Willis, yer blood’s worth bottlin’.
Apropos moon planting, consider the following:
Immediately prior to an earthquake, wildlife becomes noticeably agitated. A possible cause is the increase in radon released from the fracturing of crustal rocks. The moon induces a tide in the crust and this releases varying amounts of radon dependent on the phase of the moon. Radon is a short-lived radioactive gas that may well influence enzymatic processes in plant cells. This is one of those “dig here” thoughts as EM Smith calls them. Not original with me, but I cannot recall who presented the idea to me more than twenty years ago.
Hoping everyone enjoyed their festive season. It was a subdued one chez Git as Dr Del Weston and Prof Gavin Mooney who both moved to the Huon Valley this year were murdered a few days ago. They were a charming couple and seemed to fit in well with the other guests for a musical evening we had last winter.
LSvaalbard
Point taken. And, I could have been convinced by the mathematics. I should have said somehthing like, “Actually, Not.” They orbit the sun and earth-moon barycenter, as modified by the effect of the other solar system bodies.”
mike g says:
December 26, 2012 at 11:29 am
They orbit the sun and earth-moon barycenter, as modified by the effect of the other solar system bodies.
no, that is still incorrect. There is no measurable effect of the ‘other bodies’ on the distance between the Sun and the Earth-Moon [on time scales of interest]. The center of mass of the Sun, Earth, and Moon depends just on those three bodies.
Great posting. This reminds me of the accounts I’ve heard of in the past which describe the disappearing knowledge of Polynesian seamen. Apparently, they could tell the location of land many miles away just by looking at the shape and size of the waves (choppiness, I think) around their canoe. That probably required a lifetime or more of careful observation.
As for the moon wind itself, it reminds me of the puzzled descriptions of a wind that accompanies eclipses (same principle; somewhat
different cause despite involvement of the sun and moon). It seems clear that there would be such a wind as cooler air flows out of the umbra. After all, this same phenomenon can be experienced sitting in your garden on one of those May days when the sun is out and the sky is clear except for a few large fluffy clouds sailing across. If you are sunning yourself, eyes shut, you know when you are in their path simply from the noticeable cool breeze that precedes them by 20 seconds or so. I would never have noticed this without relaxed contemplative thought as I sat there apparently doing nothing. As a ‘towny’ I didn’t have the exposure to the cycles and patterns of nature that people formerly took for granted. It requires immersion and a clear, open mind to see them, as with the 4 months or so at sea that Willis describes.
As we all know, there are subtle patterns at play all around us waiting to be discovered, teased out from the background noise. And scientists often talk, correctly, of datasets being too small or short-lived or clinical studies needing more participants to reveal any statistical trend. As this post shows, the ‘dataset’ can consist of multiple casual observations over long periods before you even realise there is a new phenomenon to be measured at all. That is sometimes the way the first step in a new scientific discovery happens. It’s the Eureka moment. And it often comes from mining the data of everyday experience…but only if we care to experience nature in all its detail.
Hello Willis,
There’s a good example of the use of the “terminator wind” in a naval battle in about 430 BC, in Thucydides’ History of the Peloponnesian War. The battle happened at the mouth of the Gulf of Corinth, and the Athenian admiral Phormio waited for this dawn wind to come up so that it would disrupt the closely spaced formation that an enemy fleet had taken.
I hadn’t taken the trouble to understand the dawn wind phenomenon until this post of yours, so Thank You.
Andrew Farquharson.
Indeed; some “work” degenerates rapidly into heat, like the waving of a branch, but other work leaves a persistent alteration behind. Not until some hypothetical great averaging event, like the Big Crunch, will some of that be reduced to ‘raw entropy’. So there are ‘sinks’ in the energy equation, in real and present time, which may need accounting for.
The compliment to Willis from Christopher is well-deserved. And kudos to Lord Monckton for his graciousness and perspicuity in making it.
typo: kudos, not ‘kukos’. As usual, perceived instantly on pressing ‘Post’. How does that work?