Hostname: page-component-cd9895bd7-jkksz Total loading time: 0 Render date: 2024-12-23T14:39:15.582Z Has data issue: false hasContentIssue false

A Late Holocene Paleoecological Record from Torrey Pines State Reserve, California

Published online by Cambridge University Press:  20 January 2017

Kenneth L. Cole
Affiliation:
USGS Forest and Rangeland Ecosystem Science Center, Colorado Plateau Field Station, Northern Arizona University, P.O. Box 5614, Building 24, Flagstaff, Arizona 86011-5614
Eugene Wahl
Affiliation:
Department of Ecology, Evolution, and Behavior, University of Minnesota, St. Paul, Minnesota 55108

Abstract

Paleoenvironments of the Torrey Pines State Reserve were reconstructed from a 3600-yr core from Los Peñasquitos Lagoon using fossil pollen, spores, charcoal, chemical stratigraphy, particle size, and magnetic susceptibility. Late Holocene sediments were radiocarbon dated, while the historical sediments were dated using sediment chemistry, fossil pollen, and historical records. At 3600 yr B.P., the estuary was a brackish-water lagoon. By 2800 yr B.P., Poaceae (grass) pollen increased to high levels, suggesting that the rising level of the core site led to its colonization by Spartina foliosa (cord-grass), the lowest-elevation plant type within regional estuaries. An increase in pollen and spores of moisture-dependent species suggests a climate with more available moisture after 2600 yr B.P. This change is similar to that found 280 km to the north at 3250 yr B.P., implying that regional climate changes were time-transgressive from north to south. Increased postsettlement sediment input resulted from nineteenth-century land disturbances caused by grazing and fire. Sedimentation rates increased further in the twentieth century due to closure of the estuarine mouth. The endemic Pinus torreyana (Torrey pine) was present at the site throughout this 3600-yr interval but was less numerous prior to 2100 yr B.P. This history may have contributed to the low genetic diversity of this species.

Type
Research Article
Copyright
University of Washington

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Anderson, R.S, Byrd, B.F, (1998). Late-Holocene vegetation changes from the Las Flores Creek Coastal Lowlands, San Diego County, California. Madrono 45, 171182.Google Scholar
Bean, L.J, Lawton, H.W, (1973). Some Explanations of the Rise of Cultural Complexity in Native California with Comments on Proto-agriculture and Agriculture. Ballena Press, Menlo Park.Google Scholar
Beauchamp, R.M, (1986). A Flora of San Diego County, California.Google Scholar
Christenson, L.E, (1990). The Late Prehistoric Human People of San Diego County, California: Their Settlement and Subsistence System.Google Scholar
Cole, K.L, Liu, G, (1994). Holocene paleoecology of an estuary on Santa Rosa Island, California. Quaternary Research 41, 326335.Google Scholar
Cole, K. L, Wahl, E., (1997). The Late Holocene Vegetation and Fire History of Torrey Pines State Reserve. Unpublished Technical Report to Torrey Pines State Reserve.Google Scholar
Cole, K.L, Engstrom, D, Futyma, R, Stottlemyer, R, (1990). Atmospheric deposition of metals in northern Indiana measured using a peat core from Cowles Bog. Environmental Science and Technology 24, 543548.Google Scholar
Davis, M.B, (1983). Holocene vegetational history of the eastern United States. Wright, H, Late Quaternary Environments of the United States University of Minnesota Press, Minneapolis.166180.Google Scholar
Davis, O.K, (1992). Rapid climatic change in coastal southern California inferred from pollen analysis of San Joaquin Marsh. Quaternary Research 37, 89100.CrossRefGoogle Scholar
Emery, K.O, (1950). Ironstone concretions and beach ridges of San Diego County, California. California Journal of Mines and Geology 46, 213221.Google Scholar
Evarts, B, (1994). Torrey Pines: Landscape and Legacy. Torrey Pines Association, La Jolla.Google Scholar
Faegri, K, Iversen, J, (1989). Textbook of Pollen Analysis. Wiley, New York.Google Scholar
Fairbanks, R.G, (1989). A 17,000-year glacio-eustatic sea level record: Influence of glacial melting rates on Younger Dryas event and deep-ocean circulation. Nature 342, 637642.CrossRefGoogle Scholar
Griffin, J. R, Critchfield, W. B., (1972). The Distribution of Forest Trees of California. USDA Forest Service Research Paper PSW-82/1972.Google Scholar
Haller, J.R, (1967). A comparison of the mainland and island populations of Torrey pine. Philbrick, R, Proceedings of the Symposium on the Biology of the California Islands Santa Barbara Botanic Garden, Santa Barbara.7988.Google Scholar
Haller, J.R, (1986). Taxonomy and relationships of the mainland and island populations of Pinus torreyana (Pinaceae). Systematic Botany 11, 3950.CrossRefGoogle Scholar
Inman, D.L, (1983). Application of coastal dynamics to the reconstruction of paleocoastlines in the vicinity of La Jolla, California. Masters, P.M, Flemming, N.C, Quaternary Coastlines and Marine Archaeology Academic Press, London.149.Google Scholar
Kapp, R.O, (1969). How to Know Pollen and Spores. W. C. Brown, Dubuque.Google Scholar
Kerr Collection, (1951). Collection of California Land Title Notes received by San Diego Historical Society in 1951.Google Scholar
Lease, K, (1998). Paleoecology of Some Plant Taxa Uncommon on the Anoka Sand Plain.Google Scholar
Ledig, F.T, Conkle, M.T, (1983). Gene diversity and genetic structure in a narrow endemic, Torrey pine (Pinus torreyana Parry ex. Carr.). Evolution 37, 7985.CrossRefGoogle Scholar
Macdonald, K.B, (1977). Coastal salt marsh. Barbour, M, Major, J, Terrestrial Vegetation of California Wiley, New York.263294.Google Scholar
McMaster, G.S, (1980). Patterns of Reproduction in Torrey Pine (Pinus torreyana).Google Scholar
Masters, P.M, Gallegos, D.R, (1997). Environmental change and coastal adaptations in San Diego County during the middle Holocene. Archaeology of the California Coast during the Middle Holocene, Volume 4 University of California, Los Angeles.p. 11–21.Google Scholar
Mensing, S, Byrne, R, (1998). Pre-mission invasion of Erodium cicutarium in California. Journal of Biogeography 25, 757762.Google Scholar
Mudie, P.J, Browning, B, Speth, J, (1974). The Natural Resources of Los Peñasquitos Lagoon and Recommendations for Use and Development. California Department of Fish and Game, Sacramento.Google Scholar
Mudie, P.J, Byrne, R, (1980). Pollen evidence for historic sedimentation rates in California coastal marshes. Estuarine and Coastal Marsh Science. 10, 305316.Google Scholar
Munz, P.A, (1974). A Flora of Southern California. University of California Press, Berkeley.Google Scholar
Purer, E.A, (1942). Plant ecology of the coastal salt marshlands of San Diego County. Ecological Monographs 12, 82111.Google Scholar
Stuiver, M, Reimer, P.J, (1993). A radiocarbon calibration program. Radiocarbon 35, 215230.Google Scholar
Scott, David B, Mudie, P, Bradshaw, J, (1976). Bethonic foraminifera of three southern California lagoons: Ecology and recent stratigraphy. Journal of Foraminiferal Research 6, 5975.Google Scholar
Sugita, S, MacDonald, G.M, Larsen, C.P.S, (1997). Reconstruction of fire disturbance and forest succession from fossil pollen in lake sediments: Potential and limitations. Clark, J, Cachier, H, Goldammer, J, Stocks, B, Sediment Records of Biomass Burning and Global Change Springer-Verlag, Berlin/New York.387411.Google Scholar
Thompson, R.S, (1988). Vegetational dynamics in the western United States: Modes of response to climatic fluctuations. Huntley, B, Webb, T III, Vegetation History Kluwer Academic, Dordrecht/Norwell.415454.Google Scholar
Timbrook, J, Johnson, J.R, Earle, D.D, (1982). Vegetation burning by the Chumash. Journal of California and Great Basin Anthropology 4, 163186.Google Scholar
Waters, E, Schaal, B.A, (1991). No variation is detected in the chloroplast genome of Pinus torreyana . Canadian Journal of Forest Research 21, 18321835.Google Scholar
West, G.J, (1989). Early historic vegetation change in Alta California—The fossil evidence. Thomas, D.H, Columbian Consequences: Archaeological and Historic Perspectives on the Spanish Borderlands West Smithsonian Press, Washington.333348.Google Scholar
U.S. Environmental Protection Agency(1987). Test Methods for Evaluating Solid Waste: Physical/Chemical Methods. 3rd ed. USEPA, Washington, DC.Google Scholar
Zedler, P.H, (1995). Fire frequency in Southern California shrublands: Biological effects and management options. Keeley, J.E, Scott, T, Brushfires in California Wildlands International Association of Wildland Fire, Fairfield.102112.Google Scholar