UPDATE: The SWPC press conference audio is now available, hear it here
Shortly after SWPC dropped on their website their still invisible “press conference” ( I have yet to get the link to audio, even though requested twice from Doug Biesecker) Leif Svalgaard remarked that the 10.7 cm radio flux graph produced by SWPC in that announcement on their web page was “just wrong”.
After spending months as a regular supporting commenter, Leif asked if he could write a guest post about it. After several microseconds of uncertainty, I said “yes”. So for the first time ever on WUWT, I present Dr. Leif Svalgaard as guest author, rather than commenter. – Anthony
The Solar Radio Microwave Flux
Guest Post by Leif Svalgaard, May 2009
(A PDF of this essay is available here)
Since 1947 we have routinely measured the flux of microwaves from the Sun at wavelengths between 3 and 30 cm [frequencies between 10 and 1 GHz]. This emission comes from high in the Chromosphere and low in the Corona and has two different sources [although there is debate about their relative importance]: thermal bremsstrahlung [due to electrons radiating when changing direction by being deflected by other charged particles] and ‘gyro’-radiation [due to electrons radiating when changing direction by gyrating around magnetic field lines]. These mechanisms give rise to enhanced radiation when the temperature, density, and magnetic field are enhanced, so the microwave radiation is a good ‘measure’ of ‘general’ solar activity. As strong magnetic fields are located in specific regions that can live for weeks and often reoccur at or near the same location for months [perhaps even years], there is a strong rotational signal in the emission superposed on a solar cycle variation of a ‘background’ activity level. At solar minimum, especially a ‘deep’ one as we now experiencing, the effect of active regions largely disappears and we observe a sort of solar ‘ground state’.
As the radio flux measurements [as opposed to the sunspot number] are unaffected by changes of [human] observers and their observing techniques and instrumental and atmospheric differences they may be a ‘truer’ and more objective measure of solar activity [to the extent that we can reduce this complex concept to a single number per day] and the many decades-long flux record could throw light on the important issue of the long-term variation of solar activity. The solar microwave flux is nominally an absolute flux, one solar flux unit defined as [the very small amount of] 10-22 Watt per square meter per Hertz. Making an absolute measurement is always difficult and considerable uncertainty and debate surrounded these measurements early on, before being settled by international cooperative work in the late 1960s [Tanaka et al., Solar Phys. 29 (1973) p. 243-262; http://www.leif.org/research/Tanaka-Calibration-F107.pdf]. By observing the radio flux from supernova remnants [Cassiopeia-A, Cygnus-A, and Virgo-A] one can verify the constancy of the calibration.
The longest running series of observations is that of the 10.7 cm [2800 MHz] flux [often simply referred to as ‘F10.7’] started by Covington in Ottawa, Canada in April 1947 and maintained to this day[and hopefully much longer] at Penticton site in British Columbia [http://www.hia-iha.nrc-cnrc.gc.ca/drao/solar_e.html]. The data is available from several sources, e.g. from the NGDC at http://www.ngdc.noaa.gov/stp/SOLAR/FLUX/flux.html, more timely at ftp://ftp.geolab.nrcan.gc.ca/data/solar_flux/daily_flux_values/current.txt. There are three measurements per day with small systematic [and poorly understood] differences. One can either average all three, or as in this work only use the noon value [for Penticton at 20:00 UT, since 1991].
As with all solar indices, there is the issue of the varying distance between the Earth and the Sun. For describing the effect on the Earth’s atmosphere and environment the proper values of the indices to use should, of course, be the ones observed at the Earth, but for studying the Sun, those values must be adjusted to the mean distance [at 1 astronomical unit]. This is not always appreciated and one sees endless discussions about F10.7 changes or flat-lining without the 7% change caused by the varying distance being taken into account. Needless to say, here we use the ‘adjusted flux’.
So, what does the record look like? Figure 1 shows the entire record up to date of writing [14 May, 2009], plotting the ~23,000 daily noon values [pink curve] and a running 27-day mean [black curve]:
The solar cycle variation is obvious, but so is another fact: [highlighted by the green box] that the flux at every minimum is very nearly the same. There has been no clear systematic variation or trend in the ‘ground state’. Figure 2 shows the 1954 minimum overlaid the current minimum, and is a rather dramatic demonstration of the constancy of the ground state (also shows nicely the 27-day recurrence tendency):
Other observatories have long and continuing series of measurements of the microwave flux. Of note is the long series from Japan (Toyokawa 1951 Nov – 1994 Apr; Nobeyama 1994 May – present) at several wavelengths around the 10.7 cm (e.g. 3.75 GHz = 8 cm; 2 GHz = 15 cm; and 1 GHz = 30 cm). The fluxes at these wavelengths are highly correlated with each other. Figure 3 shows the correlation of 3.75 GHz versus 2 GHz:
This means that we can use the regression equations to put all the measurements on the same scale, scaling [marked with an asterisk] them to 3.75 GHz (Figure 4):
This looks very much like Figure 1 [the coefficient of determination of the correlation with F10.7 is as high as R2 = 0.987, which is a welcome finding as one observatory series then supports the other, at least to the accuracy of the scatter plot]. Scaling the average of the Japanese [scaled] observations to F10.7 we obtain (Figure 5):
If you look very closely, you might see that the red curve (Japanese stations) lies a little bit below the green curve (Canadian stations) before 1991 and a little bit above the green curve thereafter. Here is a plot of the ratio of the flux values of the two series (Figure 6) with different colored symbol for the Ottawa and Penticton data:
. Figure 7, above. In any event, the change is but small.”]
Adding 3% to the Ottawa flux before 1991, rescaling the Japanese measurements to the thus corrected Canadian series, and computing the average flux from the two series gives us the composite series shown in Figure 8 below. All of these adjustments are very small, though, and do not substantially alter any conclusions drawn from the measurements. Although the microwave flux measurements are said to be absolute, a further correction [multiplication by the ‘URSI’-factor of 0.9] is required to get the ‘real flux’. We shall ignore that constant factor as only the relative variation is of interest here.
The red and green curves in the composite graph show the Canadian and [scaled] Japanese series going into the composite. On the whole, there is substantial agreement and the microwave flux seems well-determined.
One can now ask how this measure of solar activity compares to other measures, in particular the sunspot number [the Wolf Number]. Anticipating a finding described later, we correlate the sunspot number against the F10.7 flux (Figure 9) for the interval 1951-1988, and obtain a purely formal polynomial fit [as the relationship is not quite linear]:
The fit is good (R2 = 0.977) up until ~1989.0 after which time the observed sunspot number falls progressively below the fitted number (Figure 10):
To quantify the drift we divide the observed sunspot number by the fitted one. When the sunspot number is very low [near minimum, marked by m; worst case, zero] that quotient becomes very noisy or meaningless, so we plot only cases where the sunspot number was above 5 (Figure 11):
The progressive drift is much larger than the 3% correction and is therefore not due to the correction. It seems inescapable that the relation between the sunspot number and the microwave flux has changed significantly in recent years. Another way of showing this is Figure 12:
Ken Tapping has come to a similar conclusion (from the 2009 Space Weather Workshop: http://www.fin.ucar.edu/UCARVSP/spaceweather/abstract_view.php?recid=995):
“The Changing Relationship between Sunspot Number and F10.7”: Sunspot Number and the 10.7cm solar radio flux are the most widely-used indices of solar activity. Despite their differing nature and origins at different places in the Sun, these two indices are highly-correlated to the point where one can be used as a proxy for the other. However, during Solar Activity Cycle 23 we started to see a small but definite change in this relationship…”
So far we have been on the [relatively] firm ground of data analysis, but when it comes to an explanation of the changed relationship, we enter the realm of pure speculation [for now]. Three obvious hypotheses present themselves:
1) The sunspot counting procedure or observers have changed with resulting artificial changes of the sunspot number as they have in the past.
2) Changes in the Corona or Chromosphere accounting for additional F10.7 emission.
3) Livingston & Penn’s observations [http://www.iop.org/EJ/article/1538-4357/649/1/L45/20946.web.pdf?request-id=e22b7626-e93b-4ce3-b6f1-a999655b8888] that the sunspots are getting warmer during the last decade, leading to a decreased contrast with the surrounding photosphere and hence lessened visibility, possibly resulting in an undercount of sunspots.
There has been some criticism of SIDC and SWPC recently related to counting small pores, changing the count inexplicably, and various mistakes, but it seems to this writer that these problems would not be serious enough to account for the continuous and progressive drift shown in Figure 11. The near constancy of the flux at minima since 1954 argues against a change of the physical conditions at the source locations, leaving the exciting possibility that Livingston & Penn may be correct.
Lucy Skywalker (14:06:27) : Really important Scafetta´s slides and conference.
His slide #15, here:
http://www.giurfa.com/1989.jpg
shows that something happened in september 29, 1989. The same year where, as shown above, the discrepancy between f10.7 and SSN began.
anna v (21:34:44) I was fascinated by fire in my youth, much to the chagrin of my parents. It took a lot of ‘conditioning’ to keep me from causing a major confligration in their opinion. It was replaced by my first forays into chemistry with sodium nitrate, sulpher and carbon… If I recall correctly, coyote stole fire and brought it to earth in the Native American mythology.
Nasif Nahle (23:47:32) “Although we humans have a set of genes which induces us to think about something supernatural governing our lives, no one of those genes specifies the objects of worshiping.”
Actually, literal genes and physical cells have nothing to do with my reference. My use of “cellular memory” was an allusion to the subconcious mind, which also controls the plecebo effect. Humans hold many faiths and belief systems of which we are not consciously aware. This allows for the spectrum of preference and desire that we engage in. My own perception is that it is our subconcious projected onto our external environment that suggests an object worth worshipping, identifying it as not-self.
anna v (04:57:46) :
Nasif Nahle (23:47:32):
I was expecting a comment from you 🙂
Heh! You know more a biologist than the biologist himself. As you can see, I’m almost a predictable deterministic biosystem… 🙂
From the link you posted:
By researching with his colleagues, Goldberger was able to discover that heart rates show fractal patterns. This is not because of physical reasons, as many might believe, but because of physiological reasons.
Nevertheless, those physiological reasons are determined by physicochemical processes; thus, the apparent chaos of heartbeats is deterministic.
Chaos refers to two analogous systems which are originated in two points and exhibit a very small margin of difference of their initial conditions; after a long enough period of time, the systems will evolve toward two completely different final states. Nevertheless, in a healthy human biosystem each heartbeat ends on the same expected result, that is, the emission of an electrochemical impulse, the systole and the expulsion of blood towards arteries or veins, although they would differ every so often. From the biophysics point of view, heartbeats would be chaotic if the electrochemical impulse was generated and the result was absolutely different to a beat.
Divergences on time intervals don’t necessarily are chaos.
Regarding fractality, from the same link, it’s a children’s game. Fractality occurs in the subatomic and/or quantum levels, so it is logical that the macrostructures show some degree of fractality.
Steve Keohane (08:20:16):
Nasif Nahle (23:47:32) Actually, literal genes and physical cells have nothing to do with my reference. My use of “cellular memory” was an allusion to the subconcious mind, which also controls the placebo effect. Humans hold many faiths and belief systems of which we are not consciously aware. This allows for the spectrum of preference and desire that we engage in. My own perception is that it is our subconcious projected onto our external environment that suggests an object worth worshipping, identifying it as not-self.
It’s seems I misinterpreted your assertion. I apologize.
Which cycle does this one belong to?
“Space shuttle masquerades as sunspot in new image”
http://www.newscientist.com/article/dn17149-space-shuttle-masquerades-as-sunspot-in-new-image.html
Nasif Nahle (09:13:02) Apology accepted, none really needed, but thank you. Considering the nationalities and spectrum of opinions presented here, I am impressed by how well we do communicate.
Today, I projected a small sunspot with a penumbra. It also had a trailing Tiny Tim.
The penumbra was very difficult, as was finding the spot itself.
The umbra was a grey, halfway between black & white.
Still, the first spot I have seen since January.
And the 1st SC24 spot I have projected with a penumbra.
11:00 am PDT and 12:30 pm PDT.
Seeing 4-5.
70mm F/10 26mm Plossl.
Steve and Nasif, you must read Candace Pert’s “Molecules of Emotion”. She has a theory about whole body molecular emotional memory for learned behavior, trauma, beliefs, and pleasure, that over time, could be the seeds for genetic brainbased reflexes and instincts. Fascinating read. I tackled it in one day simply because I could not put it down. It is both technical and autobiographical. And she has the chops to say what she says (though she may go a bit too far for me).
Pamela, thanks for the reference. Timewise she was a contemporary of Brugh Joy who wrote ‘Joy’s Way’. I don’t know how I missed Ms. Pert’s work. I generally tend toward Jung’s theories.
Leif,
we appreciate you for presenting the data accurately and with little or no bias.
Unfortunately you keep presenting the current minimum as almost typical. For example, the graph you show of the F10.7 comparing current to 1954 you claim shows similarity. It does not. The current F10.7 has little amplitude excursion from the base, yet, the 1954 data, even during its quietest, has substantially larger excursions than current. ???????
A question. I am still unclear as to the data to allow comparison between the Maunder Minimum and now. That is, the assumption that the lack of sunspots then was caused by the same conditions as now. Is it possible for the magnetic field to have been more quiescent or smooth or for some other causation???
kuhnkat (23:02:18) :
Unfortunately you keep presenting the current minimum as almost typical. For example, the graph you show of the F10.7 comparing current to 1954 you claim shows similarity. It does not. The current F10.7 has little amplitude excursion from the base, yet, the 1954 data, even during its quietest, has substantially larger excursions than current. ???????
The F10.7 flux is the sum of two components: one is the emission from spots and that is clearly smaller if there are fewer spots. In that sense 2008/2009 is more quiet than 1954, but not by much [2008: 2.9 vs. 1954: 4.4]. The other component [the base level] depends on the density and temperature of the corona which in turn are caused by the overall magnetic field. and that baseline is the same at all minima, and we surmise even during the Maunder Minimum.
A question. I am still unclear as to the data to allow comparison between the Maunder Minimum and now. That is, the assumption that the lack of sunspots then was caused by the same conditions as now. Is it possible for the magnetic field to have been more quiescent or smooth or for some other causation???
As per Al Gore, everything is possible if you on’t know what is going on 🙂
On the other hand we do know that the modulation of cosmic rays during the Maunder was almost as strong as it is now, so there is evidence that solar conditions were not that different.
Some spectral lines are VERY sensitive to even minute changes in temperature. Livingston et al. has very carefully measured the line depth of such temperature-sensitive lines over more than 30 years spanning three solar cycles [Sun-as-a-Star Spectrum Variations 1974-2006, W. Livingston, L. Wallace, O. R. White, M. S. Giampapa, The Astrophysical Journal, Volume 657, Issue 2, pp. 1137-1149, 2007, DOI; 10.1086/511127]. They report “that both Ca II K and C I 5380A intensities are constant, indicating that the basal quiet atmosphere is unaffected by cycle magnetism within our observational error. A lower limit to the Ca II K central intensity atmosphere is 0.040. This possibly represents conditions as they were during the Maunder Minimum [their words, remember]. Within our capability to measure it using the C I 5380A line the global (Full Disk) and basal (Center Disk) photospheric temperature is constant over the activity cycles 21, 22, and 23”. I have known Bill Livingston [and White] for over 36 years and he is a very careful and competent observer.
Since the 1960 we have known that the sun’s surface oscillates up and down [with typical periods of ~5 minutes]. These oscillations are waves very much like seismic waves in the Earth [caused by earthquakes] and just as earthquake seismic waves can be used to probe the interior of the Earth, they can be used to probe the solar interior. There are millions of such solar waves at any given time and there are different kinds (called ‘modes’) of waves. The solar p-modes are acoustic [sound waves] normal modes. You one can imagine a frequency increase with an increasing magnetic field, due to the increase in magnetic pressure raising the local speed of sound near the surface where it is cooler and where the p-modes spend most of their time. Of course one can also imagine higher frequencies may result from an induced shrinking of the sound cavity and/or an isobaric warming of the cavity. Another kind is the solar f-modes that are the eigenmodes of the sun having no radial null points [i.e. asymptotically surface waves; II apologize for the technical mumbo-jumbo]. From the solar cycle variations of p- and f-modes [and we have now enough data from the SOHO spacecraft to make such a study] we now have an internally consistent picture of the origin of these frequency changes that implies a sun that is coolest at activity maximum when it is most irradiant. Goode and Dziembowski (Sunshine, Earthshine and Climate Change I. Origin of, and Limits on Solar Variability, by Goode, Philip R. & Dziembowski, W. A., Journal of the Korean Astronomical Society, vol. 36, S1, pp. S75-S81, 2003) used the helioseismic data to determine the shape changes in the Sun with rising activity. They calculated the so-called shape asymmetries from the seismic data and found each coefficient was essentially zero at activity minimum and rose in precise spatial correlation with rising surface activity, as measured using Ca II K data from Big Bear Solar Observatory. From this one can conclude that there is a rising corrugation of the solar surface due to rising activity, implying a sun, whose increased irradiance is totally due to activity induced corrugation. This interpretation has been recently observationally verified by Berger et al. (Berger, T.E., van der Voort, L., Rouppe, Loefdahl, M., Contrast analysis of Solar faculae and magnetic bright points. Astrophysical Journal, vol. 661, p.1272, 2007) using the new Swedish Solar Telescope. They have directly observed these corrugations. Goode & Dziembowski conclude that the Sun cannot have been any dimmer than it is now at activity minimum.
So, there is other independent evidence. But, of course, we are still just speculating. My own feeling is that solar activity was not much lower during the Maunder Minimum, we just couldn’t see the invisible sunspots.
I have come to the conclusion it took Leif probably more time to reply to all the posting than it took him to write the article.
And I would like to thank him for both.
Excellent work and an interesting read.
I am looking forward to the next publication.
Sorry to come to this discussion many months after it has been posted, but aren’t you missing something really obvious here? Microwaves excite water molecules, hence the Microwave Oven. Doesn’t the practical application of microwaves for cooking lend itself to a straight forward conclusion that as the sun increases it’s Microwave output (F10.7 flux), that increase is going to directly affect the water vapor in the earth’s upper atmosphere by heating it? Occam’s Razor would suggest that any increase in microwaves coming from the sun must in some measure heat (add energy) water that it strikes. There are many forms of energy the sun generates, each form or wavelength heats a molecule in a specific manner unique to that compound. Microwaves don’t heat O2, N2 or CO2 to a significant degree, but it does heat H20 very well, that’s why microwave ovens heat food and minimally the air surrounding it.
If global warmers are so enamored by the radiative effect of CO2, then by the same reasoning water vapor in the upper atmosphere would radiate heat as well but on a much larger scale when heated by microwaves.