Other Discoveries from Carrington's Flare

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Nugget
Number: 94
1st Author: Hugh Hudson
2nd Author:
Published: 2 February 2009
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Contents

Introduction

This year is the sesquicentennial of Richard Carrington's solar flare of 1859. He observed it in visible light ("white light") as he was measuring sunspots, and the sketch he made (Figure 1) is often displayed. The idea that small parts of the very bright Sun could double in intensity in a such a short time must have astonished the observers: not only Carrington himself but also his assistant, plus an entirely independent observer named Richard Hodgson. Detailed research has shown that this latter observer was not a weakish speller who might have been related to the author of this RHESSI Science Nugget. In Figure 1, at the state of the art of scientific graphics in 1859, the letters A, B, C, and D point to the flare brightenings. The spot umbrae and penumbrae appear somewhat stylized, but Carrington was notoriously correct in his observational work and analyses of it.

This Nugget is not about the flare in (or near) the photosphere itself, but about its effects on Earth. It was not really Carrington's work (see below) but he nevertheless thought it important to report the association between the flare and its terrestrial effects. It was in fact a phenomenally important association which he described in the best British style of understatement "While the contemporary occurrence may deserve noting, he would not have it supposed that he even leans towards hastily connecting them." "One swallow does not make a summer."

Figure 1: The Carrington white-light sketch. The emissions were very bright, of a color resembling Alpha Lyrae, and rapidly variable ("mortifying" in his description). These properties have been confirmed by subsequent observations of similar events.

The other 1859 observation

When the flare happened, the recording magnetograph at Kew Gardens observatory was in operation. It was known that a sensitive compass (magnetometer) could see all manner of variations at a low levels. In fact, Balfour Stewart, the director at Kew Observatory, independently noted many flare-induced disturbances during the disk passage of the sunspot group responsible for the Carrington flare (about two weeks). The polymath Gauss had already established that these variations were external perturbations of the geomagnetic field, which in the bulk had its origins (we know now) deep in the iron-nickel core of the Earth. The Carrington flare now strongly suggested that some of these variations could ultimately be traced to the Sun, rather than to near-Earth space, and the Kew observation shown below (Figure 2) shows that these could be prompt. It was correctly argued by Kelvin that these perturbations could not result directly from changes of solar magnetism, but nobody at the time had the imagination to anticipate X rays or the ionosphere, both key ingredients to an explanation of Figure 2.

Figure 2: The compass records from Kew Gardens.

One of the main purposes of this Nugget is to circulate Figure 2, which is not as well known as Carrington's sketch though it contains a lot of discovery. We now know there is an ionosphere. Solar soft X-radiation increases the ionization level, and naturally occurring EMF's drive enhanced currents, which in turn deflect compass needles. This is an example of a Sudden Ionospheric Disturbance, or SID. There are many other different ionospheric effects resulting from different solar emissions and ionospheric properties, and prior to the era of space research these ionospheric effects provided many clues to flare physics.

Carrington's tentative association is the beginning of "space weather". The initial compass perturbation is due to ionization at the top of Earth's atmosphere produced by high-energy photons, which travel from the Sun at the speed of light - a few minutes' delay. The later magnetic storm is due to solar plasma ejected by the flare (a Coronal Mass Ejection). The plasma moves one A.U. in about 17 hours. This means a speed of some 2500 km/s, nearly 0.01 c, which is at the high end of speeds of solar ejecta. This high speed befits such a powerful flare event. The compass deflections during the main magnetic storm result from other current systems, driven not by the regular diurnal effects of the steady solar wind, but by the stresses of the CME itself.

Conclusion

The white-light flare phenomenon, of which Carrington's 1859 event was the first recorded, is something that RHESSI can study important aspects of, namely the hard X-ray emission that we have discussed in earlier Nuggets (11, 76, 92). There are still mysteries associated with these powerful phenomena, possibly involving gamma-rays from pion decay, sunquakes, or other exotica. Probably the ionosphere is too crude a detector to be of much use any longer, but we should not forget its great contributions over the fifteen decades since Carrington's time!

References

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