This arrived in my email tonight from Bill Livingston. It is hot off the press, date June 11th. I believe WUWT readers will be some of the first to see this. – Anthony
Guest Essay by:
W. Livingston, National Solar Observatory, 950 N. Cherry Ave, Tucson AZ 85718;
M. Penn, National Solar Observatory, Tucson AZ
Physical conditions in the infrared at 1.5 microns, including maximum magnetic field strength and temperature, have been observed spectroscopically in 1391 sunspots 1990 to 2009 (1). We emphasize the quantitative difference between our IR sunspot measurements and the visible light results from most solar magnetographs employed world-wide. The latter are compromised by scattered light and measure flux, not field strength. A lower limit of ~1800 Gauss is required to form spot umbra. The umbral maximum field strength has declined over the above interval, perhaps because spots have on average diminished in size. The present condition of solar activity minimum has more spotless days than since the 1910s (2). The Cheshire Cat behavior is related to magnetic surface fields often appearing without accompanying dark spots.
Sunspots recently are behaving like a Cheshire Cat: the smile is there (magnetic fields) but the body is missing (no dark markings). We are unsure about past cycles but at present sunspots, with their usual umbrae and penumbrae, are failing to materialize. For hundreds of years the Sun has shown an approximately periodic 11-year alteration in its activity where the number of sunspots increases and then decreases. Sunspots are dark regions on the solar disk with magnetic field strengths greater than 1500-1800 Gauss. The last sunspot maximum occurred in 2001. Magnetically active sunspots at that time (Figure 1A) produced powerful flares, caused large geomagnetic disturbances, and disrupted some space-based technology.
At present, presumably leaving a deep solar minimum, nothing more than tiny spots, or “pores”, have been seen for some time (again
Figure 1B).
In the current solar minimum the number of spotless days has not been equaled since 1914 (2), see Figure 2. Some look at this figure and feel reassured; this has
happened before. Others sense abnormality.
Why is a lack of sunspot activity interesting? During a period from 1645 to 1715 the Sun entered an extended period of low activity known as the Maunder Minimum. For a time equivalent to several sunspot cycles the Sun displayed few sunspots. Models of the Sun’s irradiance suggest that the solar energy input to the Earth decreased during that epoch, and that this lull in solar activity may explain the low temperatures recorded in Europe during the Little Ice Age (3).
In 1990, working with S. Solanki, we began exploratory measurements at the McMath- Pierce telescope of the infrared magnetic field strength, temperature, and brightness in dark sunspot umbrae. These observations use the most sensitive probe of sunspot magnetic fields: Zeeman splitting of the infrared spectral line of Fe I at 1565 nm. This splitting yields total field strength not flux (see below). Because the splitting is always complete in sunspot umbrae the measurement is independent of atmospheric blurring, or seeing (providing the line is visible). Temperature was deduced from the depth of nearby molecular OH lines. Higher temperature meant brighter continuum intensity and weaker OH. Starting in 2000 this work became systematic, where each spot was measured only once at the darkest position in its umbra. The resulting data set of 1391 observations represents the longest time-sequence of total field strengths in sunspots. Figure 3 is a plot of these observations.
We believe most of the scatter is real; the errors are likely to be in intensity and not field strength. Sky transparency and image quality, or seeing, are of course somewhat variable and this affects intensity. Data with obvious clouds were discarded. Two conclusions: 1) there is not a unique relation between sunspot brightness and magnetic field and 2) the lower limit to the magnetic field to produce a dark marking is around 1500-1800 Gauss. This lower limit is uncertain because of noise in intensity (brightness) signals.
It was also found that the magnetic field strengths in umbrae were on average decreasing with time independent of the sunspot cycle. Or it may be that spots are simply getting smaller (4). OH has practically disappeared today. A simple linear extrapolation of our magnetic data suggests that sunspots might largely vanish by 2015, assuming the 1800 Gauss lower limit, see Figure 4.
The brightness and magnetic fields of large sunspots had earlier been discovered to change in-sync with the solar cycle as seen by ground-based telescopes (5). Automated solar magnetographs (e.g. Mt Wilson, Kitt Peak, SOHO) measure surface magnetic flux using spectral polarization signals from the Zeeman effect. Flux measurements are subject to scattered light; the fields they deduce in sunspot umbrae are much less, often by a factor of two, than the field strength given by the Fe 1564 nm splitting (6). The latter does not involve polarization sensing. Magnetograph instruments, however, are in wide use both in space and ground-based –with a time span going back over 50 years. They do record non-sunspot magnetic flux (which the simple non-polarized Fe 1564 nm splitting cannot do) and have detected the onset of the next solar cycle active regions. This deduction is based on the expected high solar latitude hemispheric magnetic polarity reversal, the “Hale cycle”. Yet all new cycle number 24 spots that we have observed have been tiny “pores” without penumbrae (e.g. Figure 1). Nearly all of these features are seen only on magnetograms and are difficult or impossible to see on white-light images. Thus the analogy to the Cheshire Cat [Roberts, 2009].
Physical explanations of this deep minimum are at present speculative. Modelers invoke flux transport, meridional flows, and other subsurface mechanisms. Whether this diminished vigor in sunspots is indicative of another Maunder Minimum, remains to be seen. We should mention, too, that the solar wind is reported to be in a lower energy state than found since space measurements began nearly 40 years ago (7). Will the Cheshire Cat Effect persist?
References:
1. Penn, M.J. and Livingston, W., Temporal Changes in Sunspot Umbral Magnetic
Fields and Temperatures, Astrophys. Jour., 649, L45-L48, (2006).
2. Janssens, J., Spotless days website, (2009)
http://users.telenet.be/j.janssens/Spotless/Spotless.html
3. Lean, J., A. Skumanich, and O. White, Estimating the Sun’s Radiative Output
During the Maunder Minimum, Geophys. Res. Lett., 19(15), 1591–1594 (1992).
4. Schad, T.A., and Penn, M.J. (2008), Solar Cycle Dependence of Umbral
Magneto-Induced Line Broadening, EOS Trans. AGU 89(23), Jt. Assem. Suppl. Abstract
SP41B-06 (2008).
5. Albregtsen, F. and Maltby, P., Solar Cycle Variation of Sunspot Intensity, Solar
Physics, 71, 269-283 (1981).
6. Private communication from J. Harvey, (2009).
7. Fisk, L.A., and Zhao, L., The Heliospheric Magnetic Field and the Solar Wind
During the Solar Cycle, in Universal Heliophysical Processes, Proceedings of the
International Astronomical Union, IAU Symposium, Volume 257, pp 109-120 (2009).
Acknowledgement:
Roberts, Harry, Sydney Observatory, private communication re. Cheshire Cat (2009).
A PDF version of this essay is available here: Livingston-Penn_sunspots4
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C Colenaty (04:43:08) :
Is there information available as to how the sunspot size at the start of cycle 23 compares to that of 24. More specifically, did 23 also start out with a series of tiny sunspots?
Don’t know about 23/24, but 14/15 ended and started with whoppers of sunspots. In the deepest (and also the briefest) part of SC14/15 transition, there were tiny tims, but they also appeared in swarms.
Look very, very closely at the two top graphs here:
http://www.robertb.darkhorizons.org/DeepSolarMin3.htm
See all the indications of the Tiny Tim faculae?? Half the average size in SC23/24 as in SC14/15?
From a quick scan of data from 1996/97, both the spots and the faculae (white sunspots) were larger than those of today.
“Kevin Rudd is the other way. He thinks he is a God and can stop the Earth Warming. He is yet to be humbled….. Perhaps this is the beginning;-)”
Perhaps he is more like Nebuchadnezzar II than King Canute.
Basil (05:44:52) :
[…]
I would say they are measuring, not extrapolating, except in a very cautious way, and within limits of some physical boundaries. In particular, look at FIgure 4, and please point out where the extrapolation occurs.
The extrapolation occurs in the text immediately preceding Figure 4:
“A simple linear extrapolation of our magnetic data suggests that sunspots might largely vanish by 2015, assuming the 1800 Gauss lower limit, see Figure 4.”
Hey Anthony,
Are any of these changes in the sun related to the step-change in part of the radiation spectrum that you noted in October 2005?
REPLY: Some of them are, Lief Svalgaard mentions that the solar wind pressure is related. – Anthony
jeroen (03:58:24):
http://newsbusters.org/node/10773
and recent changes to sunspot observation can only effect a relative increase in the number observed, not the other way around.
My God. A correct use of the word “effect” to mean “bring about”.
Perhaps a first on this blog?
(Must be one of them there BritAusCanZealanders or something . . . )
cktheman,
Please explain to us unlightened many about how a solid iron solar surface has managed to stay hidden these many years from literally thousands of spectroscopic studies?
The last thing AGW skeptics need, imho, is for fringe pseudo science highjacking anything.
AGW highjacked climate science. We do not need distractions on our side.
evanmjones
The sunspot effect can affect us!
Jennyinoz (05:34:27) :
There were rallies on Saturday but the photographic evidence is limited and no wide angle shots of the masses are available.
Your link to the Sydney Morning Herald estimates a crowd of 6000 nationwide.
With a reported population of over 21 million people, this means that this mass movement of concerned Aussies was able to turn out about 0.03% of the population to save the word from 0.03% CO2.
Turning Points?
RoyFOMR (06:37:28) : RE: Christopher Booker — “I posted a response as feedback but it’s not getting through, ”
While I composed a response I seemed to have gotten timed out and had to re-connect. I did the original as a word.doc so it was not a problem.
I suggest you give it another try. John
evanmjones (09:35:17) :
“The Gore effect”
The phenomenon that leads to unseasonably cold temperatures, driving rain, hail, or snow whenever Al Gore visits an area to discuss global warming. Hence, the Gore Effect.
The sunspot effect can affect us!
Can it effect such an affectation?
Through fire and water I run
borrowed time Under the Dying Sun
In the fields of green
Under the dying sun
I cry out
In grief for my beloved one
Beware The Future Misery
Read The Shadows As They Pass
A Freezing Wind A Promise Bring
The Dawn Of The Dying Sun
In the valley of the dying sun
I walk a crooked path alone
Stephen Brown (08:26:30) :
Bill Maguire, Professor of Geophysical Hazards at University College London,
“When they see how their little patch of land is affected they will realise how their own lives will be affected and the lives of their children. It will hammer it home.”
The ugly face of propaganda masquerading as a science.
OT
http://www.physorg.com/news163823639.html
Red giant star Betelgeuse is mysteriously shrinking
June 10th, 2009 Red giant star Betelgeuse is mysteriously shrinking
UC Berkeley physicist Charles Townes, who won the 1964 Nobel Prize in Physics for invention of the laser, cleans one of the large mirrors of the Infrared Spatial Interferometer. The ISI is on the top of Mt. Wilson in Southern California. Credit: Cristina Ryan (2008)
The red supergiant star Betelgeuse, the bright reddish star in the constellation Orion, has steadily shrunk over the past 15 years, according to University of California, Berkeley, researchers.
Long-term monitoring by UC Berkeley’s Infrared Spatial Interferometer (ISI) on the top of Mt. Wilson in Southern California shows that Betelgeuse (bet’ el juz), which is so big that in our solar system it would reach to the orbit of Jupiter, has shrunk in diameter by more than 15 percent since 1993.
Since Betelgeuse’s radius is about five astronomical units, or five times the radius of Earth’s orbit, that means the star’s radius has shrunk by a distance equal to the orbit of Venus.
“To see this change is very striking,” said Charles Townes, a UC Berkeley professor emeritus of physics who won the 1964 Nobel Prize in Physics for inventing the laser and the maser, a microwave laser. “We will be watching it carefully over the next few years to see if it will keep contracting or will go back up in size.”
Townes and his colleague, Edward Wishnow, a research physicist at UC Berkeley’s Space Sciences Laboratory, will discuss their findings at a 12:40 p.m. PDT press conference on Tuesday, June 9, during the Pasadena meeting of the American Astronomical Society (AAS). The results were published June 1 in The Astrophysical Journal Letters.
Despite Betelgeuse’s diminished size, Wishnow pointed out that its visible brightness, or magnitude, which is monitored regularly by members of the American Association of Variable Star Observers, has shown no significant dimming over the past 15 years.
The ISI has been focusing on Betelgeuse for more than 15 years in an attempt to learn more about these giant massive stars and to discern features on the star’s surface, Wishnow said. He speculated that the measurements may be affected by giant convection cells on the star’s surface that are like convection granules on the sun, but so large that they bulge out of the surface. Townes and former graduate student Ken Tatebe observed a bright spot on the surface of Betelgeuse in recent years, although at the moment, the star appears spherically symmetrical.
“But we do not know why the star is shrinking,” Wishnow said. “Considering all that we know about galaxies and the distant universe, there are still lots of things we don’t know about stars, including what happens as red giants near the ends of their lives.”
Betelgeuse was the first star ever to have its size measured, and even today is one of only a handful of stars that appears through the Hubble Space Telescope as a disk rather than a point of light. In1921, Francis G. Pease and Albert Michelson used optical interferometry to estimate its diameter was equivalent to the orbit of Mars. Last year, new measurements of the distance to Betelgeuse raised it from 430 light years to 640, which increased the star’s diameter from about 3.7 to about 5.5 AU.
“Since the 1921 measurement, its size has been re-measured by many different interferometer systems over a range of wavelengths where the diameter measured varies by about 30 percent,” Wishnow said. “At a given wavelength, however, the star has not varied in size much beyond the measurement uncertainties.”
The measurements cannot be compared anyway, because the star’s size depends on the wavelength of light used to measure it, Townes said. This is because the tenuous gas in the outer regions of the star emits light as well as absorbs it, which makes it difficult to determine the edge of the star.
The ISI that Townes and his colleagues first built in the early 1990s sidesteps these confounding emission and absorption lines by observing in the mid-infrared with a narrow bandwidth that can be tuned between spectral lines. The ISI consists of three 5.4-foot (1.65-meter) diameter mirrors separated by distances that vary from 12 to 230 feet (4-70 meters), said Townes. Using a laser as a common frequency standard, the ISI interferometer combines signals from telescope pairs in order to determine path length differences between light that originates at the star’s center and light that originates at the star’s edge. The technique of stellar interferometry is highlighted in the June 2009 issue of Physics Today magazine.
“We observe around 11 microns, the mid-infrared, where this long wavelength penetrates the dust and the narrow bandwidth avoids any spectral lines, and so we see the star relatively undistorted,” said Townes. “We have also had the good fortune to have an instrument that has operated in a very similar manner for some 15 years, providing a long and consistent series of measurements that no one else has. The first measurements showed a size quite close to Michelson’s result, but over 15 years, it has decreased in size about 15 percent, changing smoothly, but faster as the years progressed.”
Townes, who turns 94 in July, plans to continue monitoring Betelgeuse in hopes of finding a pattern in the changing diameter, and to improve the ISI’s capabilities by adding a spectrometer to the interferometer.
“Whenever you look at things with more precision, you are going to find some surprises and uncover very fundamental and important new things,” he said.
Source: University of California – Berkeley (news : web)
Via http://www.seablogger.com Fresh Bilge
Salty ocean currents create the Earth’s magnetic field? Interesting, but could it be the other way round?
/Mr Lynn
I am always interested to see what Livingston and Penn (and Leif) have to say here. As said by many before, these are interesting times.
wayne findley (02:51:02) :
I offer “Inconveniently Cooling Earth” or… “ICE.”
RoyFOMR (06:37:28) : RE: Christopher Booker — “I posted a response as feedback but it’s not getting through, ”
Your post was there.
Perhaps it can affect an effection. Wait, clearly that last part isn’t even a word…
Leif,
You indicated that data on small cosmic ray intensities during Maunder miinimum exist:
the Beer et al Be-10 data shown in their Nature 348, 520 (1990) paper seem to follow quiet well the sunspot activities from 1700 to present. I have only the figure of the Solanki et al Nature 408, 445 (2000) at hand., which show big cosmic ray activity around 1700.
Are there other data, which indicate small cosmic ray activity through the Maunder minimum?
Werner Weber-actually, sense cosmic rays and sunspots tend to be inversely related, I think you mean high intensity during the Maunder.
“LilacWine (05:06:33) :
Sharon Grierson MP (Labor)… who recently shrieked across the floor of federal parliament during a debate on the ETS “We don’t care about the science!”… I’m still looking for a link to the video of that moment…”
If you find it let me know. I will make a YouTube video out of it.