The Earth's palaeorotation, postglacial rebound and lower mantle viscosity from analysis of ancient Chinese eclipse records

Details The Earth's palaeorotation, postglacial rebound and lower mantle viscosity from analysis of ancient Chinese eclipse records The Earth's palaeorotation, postglacial rebound and lower mantle viscosity from analysis of ancient Chinese eclipse records

Sep 1995

adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=1995papge.145..459p&link_type=abstract

Pure and Applied Geophysics PAGEOPH, Volume 145, Issue 3-4, pp. 459-485

Physics

Geophysics

2

Earth Rotation, Postglacial Rebound, Mantle Rheology, China, Eclipses, Chronology, History

Scientific paper

Of the forces changing the Earth's rotation, tidal braking and postglacial rebound predominate at a timescale≥102 yr ( Hide and Dickey, 1991; Dickey, 1992). Analysis of ancient eclipse records has given values for the clock error Δ T and the time derivative of the Earth's dynamic oblatenessdot J_2 for the past 3,300 yr. Since Δ T=AT-UT=ct 2 , where AT is Atomic (cesium clock) Time, UT is Universal (Earth rotation) Time, and t is the number of centuries before 1800, the oldest data have the most weight. Sunrise and sunset eclipses are especially valuable, as they can be retrospectively timed. The Bamboo Annals, entombed in 299 B.C. and unearthed in A.D. 281, states that “in the first year of King Yi of the Western Zhou dynasty the day dawned twice at Zheng (34.5°N, 109.8°E)”. Kaiyuan zhanjing (Siddhartha, A.D. 724) cites this passage and adds that “in the 2nd (actually 12th) year of Sheng Ping reign period of King Shang (actually King Xi) the day began twice at Zheng”. Matching these records with the April 21, 899 B.C. and April 4, A.D. 368 sunrise eclipses (Oppolzer eclipse Nos. 732 and 3747) gave Δ T values of 5.8±0.15 and 1.7±0.1 hr, respectively. The recurrence of a central solar eclipse at the same site under almost identical circumstances accurately links up an ancient Δ T value with a more precise medieval one, and makes the statistics of such early data more robust. The brightness changes for the magnitudes 0.95 0.97 and 0.991 0.998 eclipses were greater than those for the January 4, 1992 “double sunset” over Southern California, U.S.A. (magnitude 0.91 0.92). David H. Levy noted that “... as annularity ended. Sunset had come and gone, but the sky began to brighten not darken. For almost 15 minutes it continued to brighten until the onrushing shadow of Earth took over and darkness fell again ...” (Sky Telesc. 83, 694). We have analyzed even earlier records from the Shang dynasty. Six solar eclipse records have been identified among 160,000 oracle bones unearthed from the Shang dynasty capital Anyang (36.1°N, 114.3°E). Four of the 12th-century-B.C. inscriptions have cyclic days of 18, 42, 17 and 25. The chinese 60-day cycle is like our week in design, and has been in continuous use from time immemorial. These records have been uniquely matched to the sunrise eclipses of June 7, 1172 B.C. and October 31, 1161 B.C., and sunset eclipses of October 21, 1198 B.C. and June 27, 1163 B.C., respectively. Using visibility constraints on the rising and setting eclipsed Sun from Anyang we have derived upper or lower limits on Δ T. Three of them cluster around 7 hr 10 min, consistent with a Δ T of 7 hr 20 min, from the analysis of a record of the June 5, 1302 B.C. total solar eclipse, which states that “three flames ate the Sun, big stars were seen”. Analysis of our data gave an equation of best-fit of Δ T=(30±2.5) t 2, for the secular lunar acceleration ratedot n_{moon} = - 26''/cen^2 ( Williams et al., 1992). From this we derived andot ω /ω of -(19±1.6)×10-11/yr, where ω is the angular velocity of the Earth's rotation. Subtracting a tidaldot ω /ω of -27.8×10-11/yr ( Lambeck, 1980) gave a nontidaldot ω /ω of (9±1.6)×10-11/yr, which is equivalent to adot J_2 of -(4.5±0.8)×10-11/yr. The averagedot J_2 for the past 3,300 yr is larger than the presentdot J_2 from satellite laser ranging, -3×10-11/yr ( Cheng et al., 1989), as expected. Bothdot J_2 values are consistent with postglacial rebound from an upper mantle of viscosity 1021 Pa s, and a lower mantle of viscosity (2 4)×1021 Pa s, deformed by Pleistocene ice sheet loading ( Peltier, 1985). Our mantle viscosity values are consistent with those from the analyses of free air gravity anomalies and relative sea-level variations ( Mitrovica and Peltier, 1991, 1992). Accurate values of the mantle viscosity are critical to our understanding of thermal convection patterns, that are responsible for plate tectonics ( Peltier, 1986). Finally, the bounceback to its less oblate interglacial shape makes the Earth spin faster, overcoming a third of the tidal braking by the Moon and Sun. The net effect has been lengthening the day by 1.64±0.14 msec/cen.

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