The ties that bind

Michael K. Shepard

doi:10.1017/CBO9781107447899.008

7 - The ties that bind

Published online by Cambridge University Press: 05 May 2015

Michael K. Shepard

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Michael K. Shepard: Affiliation:
Bloomsburg University, Pennsylvania

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Summary

Gin a body meet a body

Flyin' through the air.

Gin a body hit a body,

Will it fly? And where?

James Clerk Maxwell, Rigid Body Sings (1882)

FALSE DAWN

In the deserts of Arabia, the air is dry and the sky is an inky black. It's a perfect environment for studying the sky, and modern astronomy owes much to the Arab sky watchers of millennia past. One need only listen to the names we give to the brighter stars to hear the debt; Algol (the ghoul), Deneb (tail), Fomalhaut (mouth of the fish), and Rigel (foot) are all derived from Arabic. The depth and clarity of their dark skies also made some phenomena, overlooked by others, obvious to them.

Islam requires prayers five times per day. In a world with no clocks, the appropriate times were set by the position of the Sun. The first of these prayer times, Fajr, begins at dawn. But the Arabian sky watchers had often experienced a misleading light well before then – a false dawn. In a true dawn, sunlight spreads across the horizon, growing in intensity as the Sun approaches sunrise. In a false dawn, a cone of light, sometimes referred to as a wolf's tail, points upward from the horizon, and can occur hours before true sunrise. It is said that the Prophet Muhammad instructed his followers on ways to avoid being fooled by it. There is no mention of it by European astronomers until the late seventeenth century when it is discussed by Cassini. Subsequently, Europeans referred to the phenomenon as the zodiacal light, a faint glow that lies along the ecliptic – the same plane as the constellations of the zodiac. Only in the late nineteenth century did European astronomers come to realize that the false dawn of the Muslims was the same as the zodiacal light.

We now know the zodiacal light is caused by a cloud of fine dust, the zodiacal cloud, that encircles the Sun in the plane of the ecliptic.

Type: Chapter
Information: Asteroids
Relics of Ancient Time
, pp. 191 - 218

DOI: https://doi.org/10.1017/CBO9781107447899.008 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2015

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References

http://www.nasa.gov/home/hqnews/2010/feb/HQ_10–029_Hubble_asteroid.html

G., Beekman. I. O., Yarkovskyand the discovery of ‘his’ effect. J. Hist. Sci., 37 (2006) 71–86.Google Scholar

E., Opik. The densities of visual binary stars. Astrophys. J., 44 (1916) 292–302.Google Scholar

E., Opik. An estimate of the distance of the Andromeda Nebula. Astrophys. J., 55 (1922) 406–410.Google Scholar

J. H., Poynting. Radiation in the Solar System: Its effect on temperature and its pressure on small bodies. Phil. Trans. Roy. Soc. London A, 202 (1904) 525–552.Google Scholar

J. W., Redhouse. Identification of the “False Dawn” of the Muslims with the “Zodiacal Light” of Europeans. J. Roy. Asiatic Soc. Great Britain & Ireland, 12 (1880) 327–334.Google Scholar

I. O., Yarkovsky. Kinetic Theory of Universal Gravitation in Relation to the Formation of the Chemical Elements (Moscow, 1888) (see Beekman for discussion).Google Scholar

W. F., Bottke, D., Vokrouhlicky, D. P., Rubincam, D., Nesvorny. The Yarkovsky and YORP Effects: Implications for asteroid dynamics. Annu. Rev. Earth Planet. Sci., 34 (2006) 157–191.Google Scholar

M. B., Cita, W. B. F., Ryan, R. B., Kidd. Sedimentation rates in Neogene deep-sea sediments from the Mediterranean and geodynamic implications of their changes. Deep Sea Drilling Project Report, 42 Pt. 1, 52 (1978). doi:10.2973/ dsdp.proc.42–1.152.1978. http://www.deepseadrilling.org/i_reports.htm.Google Scholar

K. A., Farley, D., Vokrouhlicky, W. F. Bottke, D. Nesvorny. A late Miocene dust shower from the break-up of an asteroid in the main belt. Nature, 439 (2006) 295–297.

K., Hirayama. Groups of asteroids probably of common origin. Astron. J., 31 (1918) 185–188.Google Scholar

D., Jewitt et al. A recent disruption of the main-belt asteroid P/2010 A2. Nature, 467 (2010) 817–819.Google Scholar

A., Milani, P., Farinella. The age of the Veritas asteroid family deduced by chaotic chronology. Nature, 370 (1994) 40–42.Google Scholar

D., Nesvorny, W. F., Bottke, Jr., L., Dones, H. F., Levison. The recent breakup of an asteroid in the main-belt region. Nature, 417 (2002) 720–722.Google Scholar

D., Nesvorny, W. F., Bottke, H. F., Levison, L., Dones. Recent origin of the solar system bands. Astrophys. J., 591 (2003) 486–497.Google Scholar

D., Nesvorny et al. Origin of the near-ecliptic circumsolar dust band. Astrophys. J., 679 (2008) L143–L146.Google Scholar

D., Nesvorny et al. Cometary origin of the zodiacal cloud and carbonaceous micrometeorites: Implications for hot debris disks. Astrophys. J., 713 (2010) 816–836.Google Scholar

C. R., Nugent, J. L., Margot, S. R., Chesley, D., Vokrouhlicky. Detection of semimajor axis drifts in 54 near-Earth asteroids: New measurements of the Yarkovsky Effect. Astron. J., 144 (2012) 60–73. doi 10.1088/0004–6256/144/2/60.Google Scholar

D. P., Rubincam. Radiative spin-up and spin-down of small asteroids. Icarus, 148 (2000) 2–11.Google Scholar

C., Snodgrass et al. A collision in 2009 as the origin of the debris trail of asteroid P/2010 A2. Nature, 467 (2010) 814–816.Google Scholar

F. L., Whipple. A review of cometary sciences, Phil. Trans. Roy. Soc. London A., 323 (1987) 339–347.Google Scholar

V., Zappala, A., Cellino, P., Farinella, A., Milani. Asteroid families II. Extension to unnumbered multiopposition asteroids. Astron. J., 107 (1994) 772–801.Google Scholar