Journal of Geographical Sciences >
Abrupt changes in an 8000-year precipitation reconstruction for Nevada, the Western USA
Received date: 2004-12-03
Revised date: 2005-03-29
Online published: 2005-09-25
Supported by
National Natural Science Foundation of China, No.40175027; the University of Hawaii pursuant to National Oceanic and Atmospheric Administration Award, No.NA67RJ0154
A scanning t-test algorithm for detecting multiple time-scale abrupt changes in the level of a time-series was used to analyze an 8000 year time series of annual precipitation which was reconstructed from tree rings for the Nevada Climate Division 3 in the western USA. The tree ring samples were gathered from eight states in the southwestern USA. Twenty-two change-points were identified by the algorithm and these were used to partition the tree-ring series into twenty-three relatively Wet/Normal/Dry episodes. These twenty-three episodes were collaborated by a coherency analysis of abrupt changes between the precipitation reconstruction series and the TIC/δ18O records from cored sediments of Pyramid Lake in Nevada, and by comparison with published results from related studies. These episodes were also compared with studies of the global climate change and with records of climate change in China during the same periods. The results suggest that the precipitation reconstruction series is quite valuable for climate-change research on multi-centurial time-scales in the western USA, and that the scanning t-test and coherency detection algorithms may have a wide use for detecting multiple time-scale abrupt changes in a long time series.As the TIC and δ18O record series are high resolution with unequal sampling intervals ranging between 3 and 14 years, a new algorithm was developed to deal with the unequal time intervals in the series.
Key words: abrupt change; 8000 years; precipitation reconstruction; tree ring; Western USA
GU Xiangqian, JIANG Jianmin, Franklin SCHWING, Roy MENDELSSOHN . Abrupt changes in an 8000-year precipitation reconstruction for Nevada, the Western USA[J]. Journal of Geographical Sciences, 2005 , 15(3) : 259 -272 . DOI: 10.1360/gs050301
[1] Asakura, 1991. The Climatic Abnormality and the Environmental Destruction. Beijing: China Meteorological Press.
[2] Benson L, Burdett J, Lund S et al., 1997. Nearly synchronous climate change in the Northern Hemisphere during the last glacial termination. Nature, 388: 263-265.
[3] Benson L, Kashgarian M, Rye R et al., 2002. Holocene multidecadal and multicentennial droughts affecting Northern California and Nevada. Quaternary Science Reviews, 21: 659-682.
[4] Eddy J A, 1976. The Maunder Minimum. Science, 192: 1189-1202.
[5] Feng X, Epstein S, 1994. Climatic implications of an 8000-year hydrogen isotope time series from Bristlecone Pine trees. Science, 265, 1079-1081.
[6] Goodess C M, Palutikof J P, Davies T D, 1992. The Nature and Causes of Climate Change. London: Belhaven Press.
[7] Grayson D K, 1993. The Deserts Past, a Natural Prehistory of the Great Basin. Washington Smithsonian Institution Press.
[8] Grayson D K, 2000. Mammalian responses to Middle Holocene climatic change in the Great Basin of the western United States. Journal of Biogeography, 27: 181-192.
[9] Harper K T, Alder G M, 1970. The macroscopic plant remains of the deposits of Hogup Cave, Utah, and their paleoclimatic implications. In: Aikens C M (ed.), Hogup Cave. University of Utah Anthopological Papers 93, Salt Lake City, 215-240.
[10] Harper K T, Alder G M, 1972. Paleoclimatic inferences concerning the last 10,000 years from a resampling of Danger Cave, Utah. In: Fowler D D (ed.), Great Basin Cultural Ecology: a Symposium. Desert Research Institute Publications in the Social Sciences, 8, Reno, 13-23.
[11] Hattori E M, 1982. The archaeology of Falcon Hill, Winnemucca Lake, Washoe County, Nevada, Nevada State Museum. Anthropological Papers, No.18.
[12] Hood L L, Jirikowic J L, 1990. Recurring variations of probable solar origin in the atmospheric △14C time record. Geophys. Res. Lett., 17(1): 85-88.
[13] Hughes M K, Graumlich L J, 1996. Climatic variations and forcing mechanisms of the last 2000 years, Vol.141. Multi-millennial dendroclimatic studies from the western United States. NATO ASI Series, 109-124.
[14] Hughes M K, Funkhouser G, 1998. Extremes of moisture availability reconstructed from tree rings for recent millennia in the Great Basin of Western North America. In: M Beniston, J Innes (eds.), The Impacts of Climate Variability of Forests. Berlin: Springer-Verlag, 99-107.
[15] Jiang J, Mendelssohn R, Schwing F et al., 2002. Coherency detection of multiscale abrupt changes in historic Nile flood levels. Geophys. Res. Lett., 29(8): 112-1-112-4.
[16] Jiang J, F B Schwing, R Mendelssohn. Multiscale abrupt changes of wetness in the western USA for 8000 years. In: Proceedings of the International Symposium on Climate Change (ISCC), Beijing, China, March 31-April 3, 2003. 190-193.
[17] Long A, Rippeteau B, 1974. Testing contemporaneity and averaging radiocarbon dates. American Antiquity, 39: 205-215.
[18] Madsen D B, 1985. Two Holocene pollen records for the central Great Basin. Late Quaternary vegetation and climates of the American Southwest. In: Jacobs B F, Fall P L, Davis O K (eds.), Am. Assoc, Stratigr. Palynol. Contrib, 16: 113-126.
[19] Madsen D B, Currey D R, 1979. Late Quaternary glacial and vegetation changes, Little Cottonwood Canyon area, Wasatch Mountains, Utah. Quat. Res., 12: 254-270.
[20] Madsen D B, Rhode D, Grayson D K et al., 2001. Late Quaternary environmental change in the Bonneville basin, western USA. Palaeogeography, Palaeoclimatology, Palaeoecology, 167: 243-271.
[21] Madsen D B, Simms S R, 1998. The Fremont complex: a behavioral perspective. J. Word Prehist., 12: 255-336.
[22] Murchison S B, 1989. Fluctuation history of Great Salt Lake, Utah, during the last 13000 years. PhD thesis, University of Utah, Salt Lake City.
[23] Murchison S B, Mulvey W E, 2000. Late Pleistocene and Holocene shoreline stratigraphy on Antelope Island. In: King J (ed.), Geology of Antelope Island. Utah Geo. Surv. Misc., Publ. 00-1 pp.77-83.
[24] Rhode D, Madsen D B, 1998. Pine nut use in the early Holocene and beyond: the Danger Cave archaeobotanical record. J. Arch. Sci., 25: 1199-1210.
[25] Stine S, 1990. Past climate at Mono Lake. Nature, 345: 391.
[26] Stine S, 1994. Extreme and persistent drought in California and Patagonia during mediaeval Time. Nature, 369: 546- 549.
[27] Storch H V, Zwiers F, 1999. Statistical Analysis in Climate Research. Cambridge: Cambridge University Press, 116.
[28] Wigand P E, 1987. Diamond pond, Harney county, Oregon: vegetation history and water table in the Eastern Oregon desert. Great Basin Naturalist, 1987, 47(3): 427-458.
[29] Wigand P E, Mehringer P J, 1985. Pollen and seed analyses. In: Thomas D H (ed.), The Archaeology of Hidden Cave, Nevada. Anthrological Papers of the American Museum of Natural History, 61.
[30] Ye Duzheng, Chen Panqin (eds.), 1992. A Pre-study of the Global Changes in China. Beijing: Seismological Press, 31-53. (in Chinese)
[31] Zhu Kezhen, 1979. A primary study of climate changes in China for the past 5000 years. Science in China, 1979, (2): 291-296. (in Chinese)
/
| 〈 |
|
〉 |