Guest Post by Willis Eschenbach
I wanted to bring you up to date on my current meanderings in the TAO buoy data that I investigated previously in a post called “Cloud Radiation Forcing in the TAO Dataset“. In my peripatetic inquiries into all things that are ooh, shiny, I ran across a curiosity. First, a very small bit of backstory.
Figure 1. Location of the buoy (red square) which recorded the data used in this study. Solid blue squares show which of all the buoys have the two-minute data. DATA SOURCE
The TAO buoys are strung out across the tropical Pacific, recording a variety of surface and subsurface data. The data I’m looking at now include the solar radiation. From the radiation, it’s possible to tell when the skies are clear and when they are overcast. I wanted to understand the effects of the clouds. So I needed to be able to identify the clear-sky observations, and reliably separate them from the observations made when the sky was overcast. I thought folks might be interested in how I went about doing that.
First, as usual, I eyeballed the data. Figure 2 shows a time slice of the entire dataset for downwelling solar radiation, which covers over 2,000 days at two-minute intervals, or about a million and a half observations. This particular time slice shows the downwelling radiation at local noon for each day of record. I looked at a bunch of the slices, from morning and evening, all times of day, so I could understand what’s going on.
Figure 2. Data taken at local noon over the period. The data exists in five separate chunks. However, this does not matter since I am analyzing daily averages.
The dark wavy line at the top of the data is the record of all of the clear days. The up and down wave reflects the variation in the strength of the sun at the equator. This variation is about 150 W m-2 in amplitude, and has two maxima and two minima per year. So the observations near and above that wavy black line are clear sky observations, while the rest of the observations below that dark wavy line are overcast observations. The question was, how to reliably separate them mathematically.
I started by establishing a breakline. To do that, I took the median of the upper quartile (top 25% of the data). I set the break line at 80% of that median, as shown in Figure 3.
Figure 3. As in Figure 2, and including the breakline.
This left few enough data points in the upper section that I could use a gaussian average to reliably estimate the location of the center of the wavy black line. I used a 73-point gaussian filter, which gives the result shown in Figure 4
Figure 4. As in Figure 3, and including the Gaussian filter.
As you can see, the gaussian average does a very good job of determining the center of the black wavy line demarcating the clear day observations. (Note the differences in the two annual minima of the clear-sky line, due to the earth being closest to the sun in January and furthest away in August.) Finally, I created a new line at 92% of that gaussian average. This line, shown in Figure 5, was the line that I actually used to divide clear-sky observations from overcast observations.
Figure 5. As in Figure 4, and including the final line used to separate clear-sky observations from overcast sky observation.
OK, so that procedure let me reliably distinguish between the clear-sky and the overcast situations. (Note that I didn’t really have to go to that extent, because results don’t change much by just using my first breakline alone to make the cut … but I didn’t know that until I did the gaussian average, did I?. End of digression on methods …)
Now that I had collected and averaged my data, as a first cut in investigating the situation, I took the minute-by-minute average of all of the clear-sky observation, and of all of the overcast-sky observations. I also took the “All Sky” observations, which means the average of all of the observations for that minute of the day.
The results of these are graphed up in Figure 6.
Figure 6. Downwelling solar radiation during daylight hours at the TAO buoy at 0N, 165E. Blue circles are clear sky, green are all sky, and gold are overcast sky. The light red circles show the percentage of sunlight making it through the clouds during just the overcast observations (not all observations). Values following the names are the 24-hour average for each variable.
Now, here is the oddity that I mentioned in the title of this post. The light red circles show, solely for overcast observations, the average amount of sunlight making it through the clouds, as a percentage of the total sunlight available at that time. The oddity is that it is nearly the same all day. That is to say that no matter what time of day the clouds form, on average they intercept about the 45% of the available sunlight, and that’s how it is.
I didn’t expect that. I kind of understand it, in that in my post called The Thermostat Hypothesis I used the point of view of the sun to show that on average it takes less than an hour for the tropical cirrus clouds to set in. Once that happened, there was little change in cloud density for the rest of the day. It appears that a fully developed bank of cirrus/cumulonimbus clouds intercepts about 45% of the sunlight, no matter what time of day it occurs.
Anyhow, that’s the oddity. Like I say, I ascribe it in part to “on/off” nature of the cirrus regime. Seems that either they are there or not there. Still, it doesn’t really explain why the same amount of sunlight would be intercepted on average during overcast periods at any time of day. I would have thought that merely the different angles of the sun hitting the clouds would cause a fairly large variation. The sun angle may be responsible for the slight decline in the afternoon around 4 PM, when the tall towers of the thunderstorms would intercept a larger amount of the slanting afternoon sunlight. Also, it may reflect the increasing thickness of the afternoon clouds.
Let me show one last result of my investigation. This is the average amount of solar energy reflected by the clouds, minute by minute. It is shown by the red circles in Figure 7.
Figure 7. As in Figure 6, and including the amount of energy reflected (on average) by the clouds (red line). This is calculated as the clear sky insolation, minus the all sky insolation (i.e. potential insolation minus actual insolation). This difference is the amount reflected back to space by the clouds.
This result is further evidence supporting my thunderstorm thermostat hypothesis. It does so in two ways. The first way is that the forcing is inversely proportional to the temperature. More sunlight makes it through in the morning (when it is cooler) and less makes it through in the afternoon when it is warmer. The average energy lost to cloud reflection in the morning is 22 W m-2 less than in the afternoon. This warms the mornings, when it is naturally cool, and cools the afternoons, when it is naturally warm.
The second way that it supports my hypothesis is that the morning to afternoon difference in this analysis (22 W m-2) is of the same order of magnitude as that of my previous analysis done in the post “The Thermostat Hypothesis”. That data indicated a morning to afternoon difference (across the Pacific) of just over 40 W m-2. Since they are not measuring exactly the same thing, and my previous data was proxy-based and much cruder, I find that amount of agreement encouraging. Here is the figure showing the previous data:
Figure 8. Average of one year of GOES-West weather satellite images taken at satellite local noon. The Intertropical Convergence Zone is the bright band in the yellow rectangle. Local time on earth is shown by black lines on the image. Time values are shown at the bottom of the attached graph. Red line on graph is solar forcing anomaly (in watts per square meter) in the area outlined in yellow. Black line is albedo value in the area outlined in yellow.
I have no big conclusions out of this, other than to note that once again we see a strong thermostatic temperature governing mechanism in action. It is not simple feedback. It adds more energy to the surface in the morning when it is cool, and it reflects more energy to space in the afternoon when it is warm … just one of the many homeostatic mechanisms that keep the planet from overheating. It is a fairly powerful mechanism. As a measuring stick, 22 W m-2 is the expected change in forcing from CO2 increasing from its present value (~390 ppmv) to about 24,000 ppmv … just providing a sense of scale here …
In any case, that’s the news from my latest investigations. I was marveling today that I have that rare opportunity, with both the freedom to look into whatever might interest me at the moment, plus a host of wicked-smart folks to discuss my findings with. What more could a man want … except longer days. Somehow, it’s slipped past midnight again.
In between paroxysms of writing I frequently walk out to take the measure of the night. It’s crisp and cold this evening. The moon is up in the sky about 30°. I know because using a trick I learned doing celestial navigation with a sextant, I measured it using my hand at arm’s length with my thumb like this:
I know from experiment that from the top of my thumb knuckle to the bottom of my fist is 15° (for me, YMMV), which is a useful measurement because it is the distance that the sun or moon travels in the sky in one hour. I can measure up from the horizon and estimate how long it will be until sunset, one hand per hour. So I know the moon is about two hours above the horizon. That means it rose about 10:30.
Sunset these days is at 5:30. At full moon, the moon rises just as the sun sets, that’s why it is full, because it is exactly opposite the sun. (In fact, the full moon traces out the same path in the sky that the sun will take in six months … again because it is about directly opposite the sun. But I digress from my digression…)
Now, every day after the full moon, the moon rises after dark, and just under an hour later. So if it rose at 10:30 tonight that’s about five hours after dark, so we’re about five days past full … I check the moon tables to see how well I’ve done. Moonrise was 10:35 but that’s just luck to hit it that close, and we’re just starting the sixth day past full. Works for me …
The moon can also be used to determine the position of the sun. If you look at a half moon and you imagine it as a drawn bow, you’ll see it shoots its arrow directly at the sun … why do I bring this arcana up? Mostly to remind myself why I do this—because I love observing the oddities and iniquities of this most mysterious and enigmatic universe.
Tonight, Jupiter and Sirius the Dog Star frame the constellation of the hunter Orion in the southern sky. Jupiter’s a planet so it doesn’t twinkle, it’s a serene peaceful white, like a ship’s anchor light. Sirius is a star so it flashes and flickers, in shades of crimson. I take it as a channel marker for the course out of the harbor. Because it is red and I’m leaving harbor for the open sea, I’ll take it on the left, following of the “Red Right Returning” rule for channel markers …
… and in the distance, from my house I can see a tiny triangle of ocean glistening under the moon. And like the poet I long to go down to the sea again, but not to this cold green Northern sea that lies moon-bound in my night vision. The ebbing tide calls me much further afield, it’s angling on a long glance off of the horizon and out to a proper warm tropical sea of viridian and azure, with the sunlight far-reaching across the sparkling surface and lighting the color-drenched reef below, and my friends and I laughing and chaffing on our surfboards waiting for the next set … like the man said;
... The long day wanes:
the slow moon climbs:
the deep
Moans round with many voices.
Come, my friends,
'Tis not too late to seek a newer world.
Push off, and sitting well in order smite
The sounding furrows;
for my purpose holds
To sail beyond the sunset, and the baths
Of all the western stars,
until I die. ...
I wish the best of that wildering road for all of you, the finest of that side-winding path half seen through that hidden door you occasionally redismember in your wainscoting. You know the one, that unacknowledged door into summer that beckons and tickles at your mind in the gloaming, calling for you to slip once more through that fugitive crack like when you were only three but you forgot, daring you to slide unseen through that opening into whatmight, beckoning you to make a spectacular of yourself and go a-yondering far and away beyond that boringly flat event horizon you resignedly contemplate through your quotidian expectacles …
I know that road calls for me, but I’m at anchor here for a while, as I am bound at this time by family obligation to stay where I am, and I will honor that obligation fully and joyously until it ends, but hey, let’s get real here. Someone should be taking my place in the ocean, investigating the mysteries of the thermal stratification and overturn of the warm tropical waters and their relationship with climate, suntans, and bikinis … so why not you now? I mean … who better, and what better time?
Hele on …
w.
I really enjoy your posts Willis, I live south of you in Marin county. If you are every down this way, i would enjoying buying you a glass or beer or wine or cup of coffee.
Wow! Citizen scientist at work!
TSI TOA 341.5 W/m2, clear skys all year average 316.0 W/m2 = refracting + clear air absorption = 25.5 W/m2 at near equator, or 7.5%. Less than the 25% I’ve read about before ( 5 + 20).
All sky 244 W/m2, or 98 W/m2 or 29%, more than I thought, though “all sky” confuses me. Partial clouds absorption and reflection, absorption above and below, refraction above, average?
Overcast 177 W/m2: total lost 165 W/m2,, refraction, absorbed by clear air below and above, absorbed and reflected by clouds: 48% TOA TSI.
Refraction, absorption clear air above and below, absorption and reflection clouds 100% and partial. 4 variables, 3 values. If we had the partial cloud number, (4th value) could we solve for all variables?
How do these numbers work with what the IPCC/Trenberth total energy budget of the Earth? And what about +/- estimates, both by themselves and wrt to the IPCC/Trenberth calculations?
This raw data should set the certainty of input for estimates of how much cloud cover could provide the 3.5 W/m2 equivalent of IPCC-doubling of CO2.
The TAO bouys are moored. Quite how they manage this over the deep ocean I don’t know. But it seems people have realized that having the Argo floats free-floating wasn’t such a great idea.
W,
Your observations bring tears to my eyes and goose bumps down my back.
Thanks,
BC
Willis Eschenbach says:
February 2, 2013 at 4:07 am
But I’m still waiting for a picture from either of you that shows the phenomenon. I’ve looked and can’t find one. This has nothing to do with anonymity or calling out, it is that neither of you have provided a photograph that shows an actual example of what you are talking about …
w.
Obviously, it is a photography nightmare capturing an illuminated moon and the sun in the same photograph. I have had considerable difficulty in finding even a phrase for this, but this illustration captures the crux of the issue (admittedly, it took several hours to find):
http://www.astropix.com/HTML/L_STORY/MOONILL.HTM
Obviously, it is an illusion, but with 15 degrees of error, it could be an issue with naked-eyeball navigation.
So, anyhow, on February 17 we will have a 1st quarter phase with daylight conditions. Sometime in the afternoon (~12:31pm), check out your moon-bow shot and see if it hits the Sun…
Willis, I’m not pushing any thesis, just trying to get a better understanding of things, that oddity you mention has me curious.
A bit of research has revealed that there is a diurnal fluctuation in tropical convection over the ocean. Clouds < 208K (high clouds) dissipate during daylight hours, while clouds 208 – 235K increase (lower clouds). http://eos.atmos.washington.edu/tropconv.html
I am yet to be convinced on what overall affect this may have on light reaching the ocean.
Regardless of whether I agree or disagree with you, I thank you for providing thought provoking posts.
garymount says:
February 2, 2013 at 6:21 am
Very good stuff, I’ll check out Wolfram Alpha on that, it’s one of my go-to sources. Doesn’t cover everything, but what it does say you can bank on …
w.
gymnosperm says:
February 2, 2013 at 7:28 am
Why? All the words are indicating is the direction of the radiation, not the origin.
Regards,
w.
buck smith says:
February 2, 2013 at 8:58 am
Sounds good, Buck. I’m a bit of a hermit here in my house in the redwood forest, but I’ll drop you an email.
w.
Doug Proctor says:
February 2, 2013 at 11:06 am
And has been for some time … some earlier writings.
Doug, welcome to the fray, glad someone wants to move the conversation forwards.
One comment to start. The numbers from Trenberth and other authors are global averages. As such they are not directly applicable to a mid-Pacific buoy. For example, which would likely have clearer air, TAO Buoy 0N165E, or the mid-USA?
So the relevant question to ask is not “does this agree with Trenberth”, but “does this differ from Trenberth in the way I’d predict”. In this case you’d predict the air would be clearer, and the data agrees.
All-sky is a “term of art” which in climate science means the average of the variable over all the different sky conditions. In other words it is the average of all observations, not just clear sky or overcast observations.
Indeed. This is the oddball one that doesn’t vary much. Remember it is only observations when there are clouds over the buoy.
This is unclear. What are the variables, what are the values? The missing variables in the TAO dataset from my perspective are upwelling long- and shortwave figures, that is to say, surface reflections and surface longwave radiation. Having said that, you won’t be far wrong to convert surface temperature to radiation using Stefan-Boltzmann with emissivity set to 0.95 …
One calculated variable we do have is cloud albedo, which is
( 1 – all-sky/clear-sky )
or 1 – 244/316 = 0.227. Trenberth gives this value as 79 W m-2 / 341 W m-2 = 0.231 … dang, I didn’t expect that. I hadn’t looked at my results in light of Trenberth. Of course the agreement isn’t really that good, other buoys would vary. But it is in the ballpark. I don’t know which way I’d expect tropical Pacific cloud albedo to vary from the global average, because I don’t know how the global average varies … hmmm … I do have the CERES data that I could use to calculate that, I think, although it’s only five years of monthly data which is skinny. Interesting … always more good ideas than time to pursue them.
Good questions all. Since N, the number of observations, is about 2200, the errors in these observations are relatively small. Trenberth gives his error estimates in his papers. Other than that, just keep digging …
Do you use Excel, or R? Do you program?
Best regards,
w.
Philip Bradley says:
February 2, 2013 at 12:35 pm
As a long-time seaman, my bible for this and related questions is Oceanography and Seamanship“, in which Van Dorn covers this exact question. The key is the concept of “elastic mooring”, which requires a fairly light nylon (stretchy) mooring line of a very specific diameter based on the weight of what’s being moored, combined with a certain specific amount of chain. This combination provides enough stretch and spring to keep the buoy in place even in extreme conditions.
Oh, not true at all. The Argo floats are invaluable for what they do, the TAO buoys are the same for what they do. They just do different things.
w.
Bacullen says: February 2, 2013 at 1:00 pm
“….Obviously, it is a photography nightmare capturing an illuminated moon and the sun in the same photograph. I have had considerable difficulty in finding even a phrase for this, but this illustration captures the crux of the issue (admittedly, it took several hours to find):
http://www.astropix.com/HTML/L_STORY/MOONILL.HTM…
Obviously, it is an illusion, but with 15 degrees of error, it could be an issue with naked-eyeball navigation….”
A beautiful illustration, and showing something I’d never contemplated before… (but 23 degrees ‘error’ is shown, correct?)
But the trick is, in the illustration shown, that the sun is not really sitting the just to the right of the moon… it is really almost directly in front of it about 150 million kilometers or 93 million miles away.
The way to visualize it perhaps is that if you were standing on the moon looking at the sun at that time, you would be looking in almost the same direction as you are looking on earth, so the part of the moon which would be (and is) illuminated can then be visualized.
Wonderful post. Thanks.
Years on the original graph are from a “0.0” baseline to “20” ..
Is the newest date (newest data) on the right at 20.0, or the left at 0.0 – as if you were to read the graph as “years ago” ?
Seems there’s a yearly trend going on as well over the past 20 years of the buoy data for “radiation received on the surface”. How does that compare to the years since the satellite era of 1979 ?
I confirm the concept by personal experience.
By far the best time to take celestial sights is morning stars. Going from the Galapagos to Tahiti, over a period of 24 days in 1973 I found that the “trade wind clouds” began to accumulate right after the sun came up and by noon it might be hard to get a meridian passage sight. I would still have the sun for a 10:oclock fairly good chance of meridian passage and then less of a chance but still Ok for a 2PM sight. Evening stars were much less satisfactory with a good deal of breeze developed trade wind clouds and poor horizons. If you looked to the East at sunset the trade wind clouds were regularly spaced nimbus and cumulonimbus (occasional rain) looked like the audience at a movie with the light of the setting sun illuminating the clouds….so many faces. We would have a change in the wind direction in the morning just around sunrise the wind would pick up all day clocking and then a puff as the sun set and drop in the evening after sunset and backing. We were on the same tack for the entire trip and just trimmed sails.
The clouds over the islands are very different than the procession of trade wind clouds. They are anvil shaped cumulonimbus with rain and trail off down wind and don’t move. They “swim” against the trade wind clouds. Anvil Shaped clouds are a dead giveaway for a high Island like Tahiti. You know something is there perhaps 80 miles out. The low atolls have large expanses of relatively warm water in the lagoons and thermals form larger than and more emphatically than the generic trade wind clouds over the warm water. They tend to have more rain, move with the trade wind but new ones pop up with more frequency. Sometimes you can almost see the blue reflecting up. Paying attention to the clouds and birds and feeling for reflected or refracted waves is important because a palm tree is visible for only 8 miles and mangroves 3-4 Miles. It is possible to be on a reef before there is any actual sighting of land. The intertropical convergence zones have much more instability and sights are often difficult. The cloud formation during the day more persistent tending to stratus and cumulonimbus and is much more rapid and by noon entirely obscure the sun.
“Long White Cloud ” is a New Zealand description. “Morgan’s Cloud” is Bermuda. There will often be clouds there when the sky is clear everywhere else as well as when the conditions are unstable.
RACookPE1978 says:
February 2, 2013 at 8:21 pm (Edit)
Thank, RA, newest data is on the right, but as discussed upthread, it should read from 0 to 10 rather than zero to 20.
w.
Pastor W now preaches from the redwood pulpit, telling his congregation this egotistically smart-assed sermon:
“jae, I understand where you are coming from, and truly, I was going to mention the Boss, but then a funny thing happened—She told me not to mention Her name under any circumstances.
I was kinda surprised, but She said that talking about Her always leads to fights, so She recommends against discussing Her actions on blogs for any reason. According to Her it never goes anywhere. She said if people had questions they should consider this:
Matthew 6:5
“And when you pray, do not be like the hypocrites, for they love to pray standing in the synagogues and on the street corners to be seen by men. I tell you the truth, they have received their reward in full.
ETC.”
Weird. I don’t think Willis has a clue about where I’m coming from, although he thinks he does. I don’t think he digs Matthew 6:5, either, since there is no obvious connection between that verse and my comment that I can see. Let’s call him “Straw-boy Willis!!!”
I noticed that the big W still DID NOT credit SHE with anything, which again shows his Progressive (Democrat) leanings.
W-boy, do YOU think YOU are talking directly to The SHE in the sky now, eh? What are you smoking down there in the redwoods, eh? YOU must think you are really, really be special, eh? And SHE recommends TO YOU not talking about the most important subjects on the Planet? Because somehow SHE told you to say so??? I just don’t get it, Willis. Maybe you can explain your special connection to the BOSS (SHE??) ???
WEIRD, TO SAY THE LEAST!f
You got your problems, too, buddy.
.
jae says:February 2, 2013 at 10:12 pm
[…. a whole lotta odd things… “…problems…” … ]
Jae, the fact that it worries you that others may not share your beliefs, or that they do not pay sufficient homage to your ‘god’, to me says more about your problems than it does anyone else’s.
jae says:
February 2, 2013 at 10:12 pm
jae, it was an obviously failed attempt to humorously dissuade you from being a jerkwagon and introducing religion into a scientific discussion. I tried to parody people like yourself who believe that they talk to God, and that God talks to them … ah, well, I guess satire isn’t your thing, huh?
However, you have managed to snatch defeat from the jaws of victory, here you are again wanting to engage me about religion.
Let me repeat something I said before, since you were obviously off praying or something and you didn’t seem to get the message. I said:
This isn’t it. There’s a whole lot of folks here on the web who would be overjoyed to discuss religion with you, jae. I’m not, and I’ve told you so … but instead of having the common decency to keep your divisive beliefs to yourself, once again here you are jamming your damn ideas in where they are unwanted. What part of STFU is unclear here? All you’ve managed to do is to vividly limn and portray for us the worst stereotype of the religious subspecies os-spirandi Deus-obturbor, the mouth-breathing God-botherer …
Let me say it real slow, since you seem to have comprehension problems.
Take. Your. Religion. Elsewhere, It. Is. Not. Welcome. On. My. Threads.
Or as someone said, religion has its place. This isn’t it. Oh, wait, that was me … Seriously, I have no beef with your religion. Your choice is yours, although I must say I find most religious beliefs … well … unlikely. However, if you want to believe that you have an invisible companion listening to your every word, an all-powerful being who (if asked properly) will suspend the laws of physics just for you … well, that’s your business, every man has to believe what gets him through the night.
But this is not the place to irritate people about your invisible companion, jae. This is a site about something completely different, and your insistence on discussing religion is about as appropriate as … well, I was gonna say as welcome as a prick in a nunnery, to use an very relevant metaphor, but I probably should pass on that one.
On reflection, it’s not a bad metaphor, though. The nunnery is no place for that, it is a divisive intrusion there—and in exactly the same way, this is no place for your religious claims. They are not bad or wrong, every man has his beliefs, they’re just wildly inappropriate and divisive for this location.
If you have problems with that … so what? Take it someplace else. You are more than welcome here, jae. Your religious beliefs … not so much.
w.
The radiation figures that Trenberth claims are nothing like those calculated or measured. His TOA figure is 240W/m2 when we can measure 1370W/m2 but his figure is that used to justify the GHG theory. Total rubbish.
1370W/m2 gives a temperature of 121C which is what is measured on the moon’s surface in the zenith position. Calculated earth surface radiation is 960W/m2, taking into account albedo and atmospheric adsorption. Your measured data was around 1000W/m2 on cloudless days so correlates well with that calculated and this gives a surface temperature of 88C though atmospheric and surface heating will help to reduce this as will convection. Desert surface temperatures can get close to 60C. So we are not short of heat and in no need of a theory that violates the laws of thermodynamics.
Willis, thanks for your interesting post. In your introduction you define “clear sky” by the statement : “So the observations near and above that wavy black line are clear sky observations,..”. However, although this may be a good operational approximation to the common definition of clear sky global radiation (i.e. downwelling solar), clouds may still be present under this condition. In particular, a few scattered clouds are likely to increase the short-term global solar radiation relative to values under similar cloud free conditions because of scattering and reflection.Therefore, clouds may both decrease and increase global solar radiation. I wonder how that may impact on the analysis.
John Marshall says:
February 3, 2013 at 2:47 am
John, I fear you are just revealing that you have not done your homework. The Trenberth figures are global 24/7 averages. Since (as you say) about 1370 w/m2 is the sunlight at the top of the atmosphere, this means the global average over the entire surface of a sphere is a quarter of that, or about 342 W m-2. (This is because the intercepted area [the cross-sectional area of the earth], is pi R2, while the surface area is four times that).
From that 342 W m-2, of course, we need to subtract the approximately 30% of that incoming solar radiation which is reflected by the earth. This leaves the figure you give above of about 240 W m-2.
Your protests just prove beyond doubt that you need to study up on the question, at present you’re just embarrassing yourself. I’m sure you can understand it … but right now, you don’t. Which is only a problem, of course, because you are obviously convinced you do understand it … but unfortunately, you don’t. I’m happy to assist you with that if you wish, but you need to do the work.
w.
Jens Raunsø Jensen says:
February 3, 2013 at 4:53 am
Thanks, Jens. You are correct, but I suspect it is a difference that doesn’t make a difference. In part, this is because we have a fairly large dataset (N=2,200) so the inclusion or exclusion of a few of the data points doesn’t change the answer a lot.
All the best,
w.
WOW, at least I know how to light a fire here!
BUT, IMHO, God should not be blocked from ANY discussion, W. AND, if I am, “more than welcome here,” as you state, then I get to put my $0.02 in, eh? And I thank you for that!
Rant and insult away again, if you wish. It speaks volumes to me. Maybe you will get some of the bad things out of your system. Willis, you cannot shame me, as hard as you may try…
jae says:
February 3, 2013 at 5:51 pm
Indeed, a conspicuous lack of shame is one of the necessary skills for those who think God should be an issue in every conversation. You folks couldn’t possibly be that unpleasantly intrusive if you had a decent sense of shame, so I agree, I cannot shame you.
jae, let me try an example. What you are doing would be like me going to say a blog where they are discussing knitting, and insisting on bringing climate change into the discussion. When they objected to me insisting on derailing the topic (who wouldn’t?) and asked me not to bother them with climate science because they wanted to discuss knitting, I would loftily say “IMHO, science should not be blocked from ANY discussion” and inform them they couldn’t shame me if they tried … me, if I were foolish enough to attempt that, I’d expect my epitaph to record that I fell under a human wave of enraged ladies wielding knitting needles …
There is a place for climate change discussions. It’s not on knitting blogs.
There is a place for discussions of God. While you are welcome here, as I said, this ain’t the place for that discussion.
All the best,
w.