Hostname: page-component-78c5997874-s2hrs Total loading time: 0 Render date: 2024-11-10T06:26:58.813Z Has data issue: false hasContentIssue false
  • English
  • Français

Middle and Late Holocene Sea-Level Changes in Eastern Maine Reconstructed from Foraminiferal Saltmarsh Stratigraphy and AMS 14C Dates on Basal Peat

Published online by Cambridge University Press:  20 January 2017

W.Roland Gehrels
W.Roland Gehrels*
Affiliation:
Department of Geographical Sciences, University of Plymouth, Plymouth, PL4 8AA, United Kingdom. E-mail: wrgehrels@plymouth.ac.uk
Get access Rights & Permissions [Opens in a new window]

Abstract

A relative sea-level history is reconstructed for Machiasport, Maine, spanning the past 6000 calendar year and combining two different methods. The first method establishes the long-term (103 yr) trend of sea-level rise by dating the base of the Holocene saltmarsh peat overlying a Pleistocene substrate. The second method uses detailed analyses of the foraminiferal stratigraphy of two saltmarsh peat cores to quantify fluctuations superimposed on the long-term trend. The indicative meaning of the peat (the height at which the peat was deposited relative to mean tide level) is calculated by a transfer function based on vertical distributions of modern foraminiferal assemblages. The chronology is determined from AMS 14C dates on saltmarsh plant fragments embedded in the peat. The combination of the two different approaches produces a high-resolution, replicable sea-level record, which takes into account the autocompaction of the peat sequence. Long-term mean rates of sea-level rise, corrected for changes in tidal range, are 0.75 mm/yr between 6000 and 1500 cal yr B.P. and 0.43 mm/yr during the past 1500 year. The foraminiferal stratigraphy reveals several low-amplitude fluctuations during a relatively stable period between 1100 and 400 cal yr B.P., and a sea-level rise of 0.5 m during the past 300 year.

Keywords

sea levelsaltmarshforaminiferaautocompactionAMS 14Ctransfer functionHoloceneLittle Ice AgeMedieval Warm Period
Type
Research Article
Information
Quaternary Research , Volume 52 , Issue 3 , November 1999 , pp. 350 - 359
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

Allen, J.R.L. (1999). Geological impacts on coastal wetland landscapes: Some general effects of sediment autocompaction in the Holocene of northwest Europe. The Holocene. 9, 112.CrossRefGoogle Scholar
Anderson, W.A., Kelley, J.T., Thompson, W.B., Borns, H.W. Jr., Sanger, D., Smith, D.C., Tyler, D.A., Anderson, R.S., Bridges, A.E., Crossen, K.J., Ladd, J.W., Anderson, B.G., Lee, F.T. (1984). Crustal warping in coastal Maine. Geology. 12, 677680.2.0.CO;2>CrossRefGoogle Scholar
Belknap, D. F., Shipp, R. C., Stuckenrath, R., Kelley, J. T. and Borns, H. W. Jr.(1989). Holocene sea-level change in coastal Maine. InNeotectonics of Maine. ( Anderson, W. A., Borns, H. W., Jr. Eds.), Maine Geological Survey Bulletin40,85105.Google Scholar
Belknap, D.F., Kraft, J.C. (1977). Holocene relative sea-level changes and coastal stratigraphic units on the northwest flank of the Baltimore Canyon Trough geosyncline. Journal of Sedimentary Petrology. 47, 610629.Google Scholar
Bloom, A.L. (1964). Peat accumulation and compaction in a Connecticut coastal marsh. Journal of Sedimentary Petrology. 34, 599603.Google Scholar
Colquhoun, D.J., Brooks, M.J. (1986). New evidence from the southeastern U.S. for eustatic components in the late Holocene sea levels. Geoarchaeology. 1, 275291.Google Scholar
Fairbridge, R.W. (1961). Eustatic changes in sea level. Ahrens, L.H., Press, F., Rankama, K., Runcorn, S.K. Physics and Chemistry of the Earth. Pergamon, New York., 99185.CrossRefGoogle Scholar
Gehrels, W.R. (1994). Determining relative sea-level change from salt-marsh foraminifera and plant zones on the coast of Maine, U.S.A. Journal of Coastal Research. 10, 9901009.Google Scholar
Gehrels, W.R. (1994). Holocene Sea-Level Changes in the Northern Gulf of Maine: Regional Trends and Local Fluctuations Determined from Foraminiferal Analyses and Paleotidal Modeling. University of Maine, .Google Scholar
Gehrels, W. R. in press, Using foraminiferal transfer functions to produce high resolution sea-level records from saltmarsh deposits. The Holocene, 10, 3, .Google Scholar
Gehrels, W.R., Belknap, D.F. (1993). Neotectonic history of eastern Maine evaluated from historic sea-level data and 14C dates on salt-marsh peats. Geology. 21, 615618.Google Scholar
Gehrels, W.R., Belknap, D.F., Pearce, B.R., Gong, B. (1995). Modeling the contribution of M2 tidal amplification to the Holocene rise of mean high water in the Gulf of Maine and the Bay of Fundy. Marine Geology. 124, 7185.Google Scholar
Gehrels, W.R., Belknap, D.F., Kelley, J.T. (1996). Integrated high-precision analyses of Holocene sea-level changes: Lessons from the coast of Maine. Geological Society of America Bulletin. 108, 10731088.2.3.CO;2>CrossRefGoogle Scholar
Gehrels, W.R., Van de Plassche, O. (1999). The use of Jadammina macrescens (Brady) and Balticammina pseudomacrescens Brönnimann, Lutze and Whittaker (Protozoa: Foraminiferida) as sea-level indicators. Palaeogeography, Palaeoclimatology, Palaeoecology. 149, 93105.CrossRefGoogle Scholar
Grimm, E.C. (1991). TILIA and TILIAGRAPH. Illinois State Museum, Springfield.Google Scholar
Jelgersma, S. (1961). Holocene sea level changes in the Netherlands. Mededelingen van de Geologische Stichting, Serie C, VI. 7, 1100.Google Scholar
Juggins, S and Ter Braak, C. J. F.(1998). CALIBRATE Version 0.82. A Computer Program for the Graphical Display and Analysis of Species/Environment Relationships by Weighted Averaging. [Weighted Averaging] Partial Least Squares and Principal Components Analysis, Department of Geography, University of Newcastle, .Google Scholar
Kaye, C.A., Barghoorn, E.S. (1964). Late Quaternary sea-level change and crustal rise at Boston, Massachusetts, with notes on the autocompaction of peat. Geological Society of America Bulletin. 75, 6380.CrossRefGoogle Scholar
Keigwin, L.D. (1996). The Little Ice Age and Medieval Warm Period in the Sargasso Sea. Science. 274, 15041508.CrossRefGoogle ScholarPubMed
Kelley, J.T., Gehrels, W.R., Belknap, D.F. (1995). Late Holocene relative sea-level rise and the geological development of tidal marshes at Wells, Maine, U.S.A. Journal of Coastal Research. 11, 136153.Google Scholar
Korsman, T., Birks, H.J.B. (1996). Diatom-based water chemistry reconstructions from northern Sweden: a comparison of reconstruction techniques. Journal of Paleolimnology. 15, 6577.CrossRefGoogle Scholar
Mörner, N.-A. (1969). The late Quaternary history of the Kattegatt Sea and the Swedish west coast. Sveriges Geologiska Undersökning Serie C. 640, 1487.Google Scholar
Nydick, K.R., Bidwell, A., Thomas, E., Varekamp, J.C. (1995). A sea-level rise curve from Guilford, Connecticut, USA. Marine Geology. 124, 137159.Google Scholar
Peltier, W.R. (1996). Mantle viscosity and ice-age ice sheet topography. Science. 273, 13591364.CrossRefGoogle Scholar
Pirazzoli, P.A. (1991). World Atlas of Holocene Sea-Level Changes. Elsevier, Amsterdam.Google Scholar
Pizzuto, J.E., Schwendt, A.E. (1997). Mathematical modeling of autocompaction of a Holocene transgressive valley-fill deposit, Wolfe Glade, Delaware. Geology. 25, 5760.2.3.CO;2>CrossRefGoogle Scholar
Redfield, A.C., Rubin, M. (1962). The age of salt marsh peat and its relations to recent change in sea level at Barnstable, Massachusetts. Proceedings of the National Academy of Sciences. 48, 17281735.Google Scholar
Scott, D.B., Brown, K., Collins, E.S., Medioli, F.S. (1995). A new sea-level curve from Nova Scotia: Evidence for a rapid acceleration of sea-level rise in the late mid-Holocene. Canadian Journal of Earth Sciences. 32, 20172080.CrossRefGoogle Scholar
Scott, D.B., Schnack, E.J., Ferrero, L., Espinosa, M., Barbosa, C.F. (1990). Recent marsh foraminifera from the east coast of South America: Comparison to the northern hemisphere. Hemleben, C., Kaminski, M.A., Kuhnt, W., Scott, D.B. Paleoecology, Biostratigraphy, Paleoceanography and Taxonomy of Aggltinated Foraminifera. Kluwer, Dordrecht., 717737.CrossRefGoogle Scholar
Scott, D.B., Williamson, M.A., Duffett, T.E. (1981). Marsh foraminifera of Prince Edward Island: Their recent distribution and application for former sea level studies. Maritime Sediments and Atlantic Geology. 17, 98129.Google Scholar
Scott, D.B., Medioli, F.S. (1978). Vertical zonations of marsh foraminifera as accurate indicators of former sea-levels. Nature. 272, 528531.CrossRefGoogle Scholar
Scott, D. B. and Medioli, F. S.(1980). Quantitative Studies of Marsh Foraminiferal Distributions in Nova Scotia: Implications for Sea-Level Studies. Cushman Foundation for Foraminiferal Research Special Publication 17. pp. 157.Google Scholar
Shennan, I. (1986). Flandrian sea-level changes in the Fenland II: Tendencies of sea-level movement, altitudinal changes, and local and regional factors. Journal of Quaternary Science. 1, 155179.Google Scholar
Shepard, F.P. (1963). Thirty-five thousand year of sea level. Clements, T., Stevenson, R.E., Halmos, D.M. Essays in Marine Geology in Honor of K. O. Emery. University of Southern California Press, Los Angeles., 110.Google Scholar
Stuiver, M., Reimer, P.J. (1993). Extended 14C database and revised CALIB 3.0 radiocarbon calibration program. Radiocarbon. 35, 215230.Google Scholar
Ters, M. (1973). Les variations du niveau marin depuis 10,000 ans, le long du littoral Atlantique Français. Bulletin de l'Association Française du Quaternaire. 36, 114135.Google Scholar
Thomas, E., Varekamp, J.C. (1991). Paleo-environmental analyses of marsh sequences (Clinton, Conn.): Evidence for punctuated sea-level rise during the latest Holocene. Journal of Coastal Research Special Issue. 11, 125158.Google Scholar
Tooley, M.J. (1992). Recent sea-level changes. Allen, J.R.L., Pye, K. Saltmarshes. Morphodynamics, Conservation and Engineering Significance. Cambridge University Press, Cambridge., 1940.Google Scholar
Tooley, M.J. (1978). Sea-Level Changes in Northwest England. Clarendon Press, Oxford.Google Scholar
Törnquist, T.E., Van Ree, M.H.M., Van't Veer, R., Van Geel, B. (1998). Improving methodology for high-resolution reconstruction of sea-level rise and neotectonics by palaeoecological analysis and AMS 14C dating of basal peats. Quaternary Research. 49, 7285.Google Scholar
Varekamp, J.C., Thomas, E. (1998). Climate change and the rise and fall of sea level over the millennium. Eos, Transactions of the American Geophysical Union. 79, 6975.Google Scholar
Varekamp, J.C., Thomas, E., Van de Plassche, O. (1992). Relative sea-level rise and climate change over the last 1500 year. Terra Nova. 4, 293304.CrossRefGoogle Scholar
Van de Plassche, O. (1982). Sea-level change and water-level movements in the Netherlands during the Holocene. Mededelingen van de Rijks Geologische Dienst. 36-1, 193.Google Scholar
Van de Plassche, O. (1991). Late Holocene sea-level fluctuations on the shore of Connecticut inferred from transgressive and regressive overlap boundaries in salt-marsh deposits. Journal of Coastal Research Special Issue. 11, 159179.Google Scholar
Van de Plassche, O., Van der Borg, K., De Jong, A.F.M. (1998). Sea level-climate correlation during the past 1400 yr. Geology. 26, 319322.2.3.CO;2>CrossRefGoogle Scholar