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Growth response of Great Basin limber pine populations to climate variability over the past 4002 years

Published online by Cambridge University Press:  15 March 2021

Constance I. Millar*
Affiliation:
Pacific Southwest Research Station, USDA Forest Service, 800 Buchanan St., Albany, CA94710, USA
Diane L. Delany
Affiliation:
Pacific Southwest Research Station, USDA Forest Service, 800 Buchanan St., Albany, CA94710, USA
John C. King
Affiliation:
Lone Pine Research, 2604 Westridge Drive, Bozeman, MT59715, USA
Robert D. Westfall
Affiliation:
Pacific Southwest Research Station, USDA Forest Service, 800 Buchanan St., Albany, CA94710, USA
*
*Corresponding author: Constance I. Millar Email: connie.millar@usda.gov

Abstract

Tree-rings representing annual dates from live and deadwood Pinus flexilis at ten sites across the central Great Basin (~38°N) yielded a cumulative record across 4002 years (1983 BC–AD 2019). Individual site chronologies ranged in length from 861–4002 years; all were continuous over their sample depths. Correlations of growth with climate were positive for water relations and mostly negative for summer temperatures. Growth was generally correlated across sites, with the central Nevada stands most distinct. Although growth was low during the Late Holocene Dry Period, variability marked this interval, suggesting that it was not pervasively dry. All sites had low growth during the first half of the Medieval Climate Anomaly, high growth during the mid-interval pluvial, and low growth subsequently. Little synchrony occurred across sites for the early Little Ice Age. After AD 1650, growth was depressed until the early twentieth century. Growth at all sites declined markedly ca. AD 1985, was similar to the lowest growth period of the full records, and indicative of recent severe droughts. A small rebound in growth occurred after ca. AD 2010. A strong signal for Atlantic Multidecadal Oscillation (AMO) occurred in growth response at most sites. The persistence of all stands despite climate variability indicates high resilience of this species.

Type
Research Article
Copyright
Copyright © University of Washington. Published by Cambridge University Press, 2021

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References

REFERENCES

Adams, K.D., 2007. Late Holocene sedimentary environments and lake-level fluctuations at Walker Lake, Nevada, USA. GSA Bulletin 119, 126139.CrossRefGoogle Scholar
Bacon, S.N., Lancaster, N., Stine, S., Rhodes, E.J., Holder, G.A.M., 2018. A continuous 4000-year lake-level record of Owens Lake, south-central Sierra Nevada, California, USA. Quaternary Research 90, 276302.CrossRefGoogle Scholar
Benson, L.V., Thompson, R.S., 1987, Lake-level variation in the Lahontan basin for the last 50,000 years. Quaternary Research 28, 6985.CrossRefGoogle Scholar
Bentz, B.J., Régnière, J., Fettig, C.J., Hansen, E.M., Hayes, J., Hicke, J.A., Kelsey, R.G., Negrón, J.F., Seybold, S.J., 2010. Climate change and bark beetles of the western United States and Canada: direct and indirect effects. Bioscience 60, 602613.CrossRefGoogle Scholar
Biondi, F., Jamieson, L.P., Strachan, S., Sibold, J., 2011. Dendroecological testing of the pyroclimatic hypothesis in the central Great Basin, Nevada, USA. Ecosphere 2, 120.CrossRefGoogle Scholar
Bowerman, N.D., Clark, D.H., 2011. Holocene glaciation of the central Sierra Nevada, California. Quaternary Science Reviews 30, 10671085.CrossRefGoogle Scholar
Box, G.E.P., Draper, N.R., 1987. Empirical Model-building and Response Surfaces. J. Wiley Sons, New York.Google Scholar
Bruening, J.M., Tran, T.J., Bunn, A.G., Weiss, S.B., Salzer, M.W., 2017. Fine-scale modeling of bristlecone pine treeline position in the Great Basin, USA. Environmental Research Letters 12, p.014008. https://doi.org/10.1088/1748-9326/aa5432.CrossRefGoogle Scholar
Bunn, A.G., Salzer, M.W., Anchukaitis, K.J., Bruening, J.M., Hughes, M.K., 2018. Spatiotemporal variability in the climate growth response of high elevation bristlecone pine in the White Mountains of California. Geophysical Research Letters 45, 13,31213,321.CrossRefGoogle Scholar
Burns, R.M., Honkala, B.H. [Technical coordinators], 1990. Silvics of North America: Volume 1. Conifers. United States Department of Agriculture (USDA), Forest Service, Agriculture Handbook 654. US Government Printing Office, Washington, D.C., 638 pp.Google Scholar
Charlet, D.A., 2020. Nevada Mountains: Landforms, Trees, and Vegetation. University of Utah Press, Salt Lake City, 432 pp.Google Scholar
Cook, B.I., Ault, T.R., Smerdon, J.E., 2015. Unprecedented 21st century drought risk in the American Southwest and Central Plains. Science Advances 1, e1400082. https://doi.org/10.1126/sciadv.1400082.CrossRefGoogle ScholarPubMed
Cook, B.I., Smerdon, J.E., Seager, R., Cook, E.R., 2014. Pan-continental droughts in North America over the last millennium. Journal of Climate 27, 383397.CrossRefGoogle Scholar
Cook, E., Krusic, P., 2014. ARSTAN v44h3. http://www.ldeo.columbia.edu/tree-ring-laboratory/resources/software. [accessed 15 July 2020]Google Scholar
Cook, E., Krusic, P., Melvin, T., 2014. RCSigFree v45 v2b. http://www.ldeo.columbia.edu/tree-ring-laboratory/resources/software. [accessed 15 July 2020]Google Scholar
Cook, E.R., Kairukstis, L.A. (Eds.), 1990. Methods of Dendrochronology. Kluwer, Dordrecht, The Netherlands, 394 pp.CrossRefGoogle Scholar
Daly, C.R., Neilson, R.P., Phillips, D.L., 1994. A statistical-topographic model for mapping climatological precipitation over mountainous terrain. Journal of Applied Meteorology 33, 140158.2.0.CO;2>CrossRefGoogle Scholar
Esper, J., Cook, E.R., Schweingruber, F.H., 2002. Low-frequency signals in long tree-ring chronologies for reconstructing past temperature variability. Science 295, 22502253.CrossRefGoogle ScholarPubMed
Feng, X., Epstein, S., 1994. Climatic implications of an 8000-year hydrogen isotope time series from bristlecone pine trees. Science 265, 10791081.CrossRefGoogle ScholarPubMed
Graumlich, L.J., 1993. A 1000-year record of temperature and precipitation in the Sierra Nevada. Quaternary Research 39, 249255.CrossRefGoogle Scholar
Graumlich, L.J., Brubaker, L.B., Grier, C.C., 1989. Long-term trends in forest net primary productivity: Cascade Mountains, Washington. Ecology 70, 405410.CrossRefGoogle Scholar
Grayson, D.K., 2011. The Great Basin: A Natural Prehistory. University of California Press, Berkeley, 418 pp.CrossRefGoogle Scholar
Griffin, J.R., Critchfield, W.B., 1976. The Distribution of Forest Trees in California. USDA Forest Service Research Paper PSW-82/1972 (Reprinted with Supplement 1976), U.S. Government Printing Office, Washington, D.C., 118 pp.Google Scholar
Grissino-Mayer, H.D., 2001. Evaluating crossdating accuracy: A manual and tutorial for the computer program COFECHA. Tree-Ring Research 57, 205221.Google Scholar
Hatchett, B.J., Boyle, D.P., Putnam, A.E., Bassett, S.D., 2015. Placing the 2012–2015 California–Nevada drought into a paleoclimatic context: insights from Walker Lake, California–Nevada, USA. Geophysical Research Letters 42, 86328640.CrossRefGoogle Scholar
Holmes, R.L., 1999. User's Manual for Program COFECHA. Laboratory of Tree-Ring Research, University of Arizona, Tucson. https://www.ltrr.arizona.edu/~sheppard/DISC2019/cofecha.txt.Google Scholar
Holmes, R.L., Adams, R.K., Fritts, H.C., 1986. Tree-ring Chronologies of Western North America: California, Eastern Oregon, and Northern Great Basin With Procedures Used in the Chronology Development Work Including User's Manuals For Computer Programs COFECHA and ARSTAN. Laboratory of Tree-Ring Research, University of Arizona, Tucson. https://repository.arizona.edu/handle/10150/304672.Google Scholar
Hughes, M.K., Funkhouser, G., 2003. Frequency-dependent climate signal in upper and lower forest border tree rings in the mountains of the Great Basin. Climatic Change 59, 233244.CrossRefGoogle Scholar
ITRDB (International Tree-Ring Data Bank), 2020. Tree Ring. NOAA National Centers for Environmental Information. https://www.ncdc.noaa.gov/data-access/paleoclimatology-data/datasets/tree-ring. [accessed 10 October 2020]Google Scholar
Kleppe, J.A., Brothers, D.S., Kent, G.M., Biondi, F., Jensen, S., Driscoll, N.W., 2011. Duration and severity of Medieval drought in the Lake Tahoe Basin. Quaternary Science Reviews 30, 32693279.CrossRefGoogle Scholar
LaMarche, V. Jr., 1973. Holocene climatic variations inferred from treeline fluctuations in the White Mountains, California. Quaternary Research 3, 632660.CrossRefGoogle Scholar
LaMarche, V.C. Jr., Mooney, H.A., 1972. Recent climatic change and development of the bristlecone pine (P. longaeva Bailey) krummholz zone, Mt. Washington, Nevada. Arctic and Alpine Research 4, 6172.CrossRefGoogle Scholar
LaMarche, V.C., 1974. Paleoclimatic inferences from long tree-ring records: Intersite comparison shows climatic anomalies that may be linked to features of the general circulation. Science 183, 10431048.CrossRefGoogle ScholarPubMed
LaMarche, V.C., Stockton, C.W., 1974. Chronologies from temperature-sensitive bristle cone pines at upper treeline in western United States. Tree-Ring Bulletin 34, 2145.Google Scholar
Lloyd, A.H., Graumlich, L.J., 1997. Holocene dynamics of treeline forests in the Sierra Nevada. Ecology 78, 11991210.CrossRefGoogle Scholar
Melvin, T.M., Briffa, K.R., 2008. A ’signal-free” approach to dendroclimatic standardization. Dendrochronologia 26, 7186.CrossRefGoogle Scholar
Mensing, S.A., Sharpe, S.E., Tunno, I., Sada, D.W., Thomas, J.M., Starratt, S., Smith, J., 2013. The Late Holocene Dry Period: multiproxy evidence for an extended drought between 2800 and 1850 cal yr BP across the central Great Basin, USA. Quaternary Science Reviews 78, 266282.CrossRefGoogle Scholar
Mensing, S.A., Smith, J., Norman, K.B., Allan, M., 2008. Extended drought in the Great Basin of western North America in the last two millennia reconstructed from pollen records. Quaternary International 188, 7989.CrossRefGoogle Scholar
Mensing, S., Benson, L.V., Kashgarian, M., Lund, S., 2004. A Holocene pollen record of persistent droughts from Pyramid Lake, Nevada, USA. Quaternary Research 62, 2938.CrossRefGoogle Scholar
Millar, C.I., Charlet, D.C., Delany, D.L., King, J.C., Westfall, R.D., 2019. Shifts of demography and growth in limber pine forests of the Great Basin, USA, across 4000 yr of climate variability. Quaternary Research 91, 691704.CrossRefGoogle Scholar
Millar, C.I., King, J.C., Westfall, R.D., Alden, H.A., Delany, D.L., 2006. Late Holocene forest dynamics, volcanism, and climate change at Whitewing Mountain and San Joaquin Ridge, Mono County, Sierra Nevada, CA, USA. Quaternary Research 66, 273287.CrossRefGoogle Scholar
Millar, C.I., Stephenson, N.L., 2015. Temperate forest health in an era of emerging megadisturbance. Science 349, 823826.CrossRefGoogle Scholar
Millar, C.I., Westfall, R.D., Delany, D.L., 2007. Response of high-elevation limber pine (Pinus flexilis) to multiyear droughts and 20th-century warming, Sierra Nevada, California, USA. Canadian Journal of Forest Research 37, 25082520.CrossRefGoogle Scholar
Millar, C.I., Westfall, R.D., Delany, D.L., Flint, A.L., Flint, L.E., 2015. Recruitment patterns and growth of high-elevation pines in response to climatic variability (1883–2013) in the western Great Basin, USA. Canadian Journal of Forest Research 45, 12991312.CrossRefGoogle Scholar
Noble, P.J., Ball, G.I., Zimmerman, S.H., Maloney, J., Smith, S.B., Kent, G., Adams, K.D., Karlin, R.E., Driscoll, N., 2016. Holocene paleoclimate history of Fallen Leaf Lake, CA., from geochemistry and sedimentology of well-dated sediment cores. Quaternary Science Reviews 131, 193210.CrossRefGoogle Scholar
Nowak, R.S., Nowak, C.L., Tausch, R.J., 2017. Vegetation dynamics during last 35,000 years at a cold desert locale: preferential loss of forbs with increased aridity. Ecosphere 8, e01873. https://doi.org/10.1002/ecs2.1873.CrossRefGoogle Scholar
NRCS (USDA, Natural Resource Conservation Services), 2020. Virginia Lakes Ridge SNOTEL Site 846. https://wcc.sc.egov.usda.gov/nwcc/site?sitenum=846. (accessed September 5, 2020)Google Scholar
Osborne, G., Bevis, K., 2001. Glaciation in the Great Basin of the western United States. Quaternary Science Reviews 20, 13771410.CrossRefGoogle Scholar
QGIS Development Team, 2020. QGIS Geographic Information System. Open Source Geospatial Foundation Project, Vs. 3.14 Pi. http://qgis.osgeo.org. (accessed June 22, 2020)Google Scholar
Reinemann, S.A., Porinchu, D.F., Bloom, A.M., Mark, B.G., Box, J.E., 2009. A multi-proxy paleolimnological reconstruction of Holocene climate conditions in the Great Basin, United States. Quaternary Research 72, 347358.CrossRefGoogle Scholar
Salzer, M., Baisan, C., 2013. Dendrochronology of the “Currey Tree.” Second American Dendrochronology Conference, 1317 May 2013. University of Arizona, Tucson, AZ. [abstract] https://ameridendro.ltrr.arizona.edu/contributionDisplay.py?contribId=59&sessionId=9&confId=0.Google Scholar
Salzer, M.W., Bunn, A.G., Graham, N.E., Hughes, M.K., 2014a. Five millennia of paleotemperature from tree-rings in the Great Basin, USA. Climate Dynamics 42, 15171526.CrossRefGoogle Scholar
Salzer, M.W., Larson, E.R., Bunn, A.G., Hughes, M.K., 2014b. Changing climate response in near-treeline bristlecone pine with elevation and aspect. Environmental Research Letters 9, 114007. https://doi.org/10.1088/1748-9326/9/11/114007.CrossRefGoogle Scholar
Salzer, M.W., Pearson, C.L., Baisan, C.H., 2019. Dating the Methuselah Walk bristlecone pine floating chronologies. Tree-Ring Research 75, 6166.CrossRefGoogle Scholar
SAS Institute Inc., 2015. SAS Online, version 12. JMP® Statistics and Graphics Guide, SAS Institute Inc., Cary, NC.Google Scholar
Schulmann, E., 1958. Bristlecone pine, oldest known living thing. National Geographic Magazine 113, 355372.Google Scholar
Scuderi, L.A., 1993. A 2000-year tree ring record of annual temperatures in the Sierra Nevada Mountains. Science 259, 14331436.CrossRefGoogle ScholarPubMed
Stine, S., 1990. Late Holocene fluctuations of Mono Lake, eastern California. Paleogeography, Palaeoclimatology, Palaeoecology 78, 333381.CrossRefGoogle Scholar
Stine, S., 1994. Extreme and persistent drought in California and Patagonia during Mediaeval time. Nature 369, 546549.CrossRefGoogle Scholar
Stokes, M.A., Smiley, T.L., 1968. An Introduction to Tree-Ring Dating. University of Chicago, Chicago (reprinted 1996). University of Arizona Press, Tucson.Google Scholar
Tausch, R., Nowak, C., Mensing, S., 2004. Climate change and associated vegetation dynamics during the Holocene: the paleoecological record. In: Chambers, J.C., Miller, J.R. (Eds.), Great Basin Riparian Ecosystems: Ecology, Management and Restoration. Island Press, Covelo, CA, pp. 2448.Google Scholar
Thompson, R.S., 1988. Western North America. In: Huntley, B., Webb, T. (Eds.), Vegetation History. Kluwer Academic Publishers, Boston, pp. 415458.CrossRefGoogle Scholar
Thompson, R.S., 1990. Late Quaternary vegetation and climate in the Great Basin. In: Betancourt, J.L, Van Devender, T.R., Martin, P.S. (Eds.), Packrat Middens: The Last 40,000 Years of Biotic Change. University of Arizona Press, Tucson, pp. 200239.Google Scholar
Thompson, R.S., Mead, J.I., 1982. Late Quaternary environments and biogeography in the Great Basin. Quaternary Research 17, 3955.CrossRefGoogle Scholar
Tran, T.J., Bruening, J.M., Bunn, A.G., Salzer, M.W., Weiss, S.B., 2017. Cluster analysis and topoclimate modeling to examine bristlecone pine tree-ring growth signals in the Great Basin, USA. Environmental Research Letters 12, 014007. https://doi.org/10.1088/1748-9326/aa5388.CrossRefGoogle Scholar
VoorTech Consulting, 2005. Measure J2X v3.2.1: the tree ring measurement program. VoorTech Consulting Project J2X, Holderness, NH.Google Scholar
Wahl, D., Starratt, S., Anderson, L., Kusler, J., Fuller, C., Addison, J., Wan, E., 2015. Holocene environmental changes inferred from biological and sedimentological proxies in a high elevation Great Basin lake in the northern Ruby Mountains, Nevada, USA. Quaternary International 387, 8798.CrossRefGoogle Scholar
Wells, P.V., 1983. Paleobiogeography of montane islands in the Great Basin since the Last Glaciopluvial. Ecological Monographs 53, 341382.CrossRefGoogle Scholar
Williams, A.P., Cook, E.R., Smerdon, J.E., Cook, B.I., Abatzoglou, J.T., Bolles, K., Baek, S.H., Badger, A.M., Livneh, B., 2020. Large contribution from anthropogenic warming to an emerging North American megadrought. Science 368, 314318.CrossRefGoogle Scholar
Wise, E.K., 2016. Five centuries of US West Coast drought: Occurrence, spatial distribution, and associated atmospheric circulation patterns. Geophysical Research Letters 43, 45394546.CrossRefGoogle Scholar
Wolfram Research, 2017. Mathematica version 11.1. Wolfram Research, Inc., Champaign, Illinois.Google Scholar
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