Radiocarbon and Uranium-Series Dating of the Plitvice Lakes Travertines

Radiocarbon and uranium-series ages of the calcareous deposits of the Plitvice Lakes show that travertines were deposited during three warm, humid, interglacial oxygen isotope stages. According to our measurements, only calcite crystals or crystal aggregates represent reliable material for both 230Th/234U and 234U/238/U dating. Compact old travertine in the form of sandstone is less reliable; it can be dated by both methods provided that its detrital contamination is not significant, demonstrated by very low 14C activity (< 1.5–2.0 pMC) and a high 230Th/232Th ratio. Old porous travertine contaminated with recent carbonates and Th-bearing clay (pMC > 5, 230Th/232Th < 5) gives erroneous results by both methods. Stage 1 (Holocene) deposition is shown primarily by 14C dating corroborated by sedimentological and palynologic studies as well as by both 230Th/234U and 234U/238U disequilibrium methods. The intensive growth of travertine barriers coincided with significant climate warming in the Holocene. Stage 5 deposition is confirmed by the 230Th/234U dating of crystalline calcite aggregates embedded in the travertine matrix and by concordant 230Th/234U and 234U/238U ages, assuming that the 234U/238U activity ratio of 1.88 observed in modern streams and in Holocene deposits can be extended to past epochs. The travertine deposition period was very short, peaking ca. 120 ± 10 ka bp. Stage 11 deposition is indicated by 234U/238U dating only, the period being within the 234U decay range, but not that of 230Th. Stage 11 travertine was deposited ca. 420 ± 50 ka bp. We did not find travertine samples with U-series ages indicating a growth period during relatively warm Stages 7 and 9; due to the scarcity of old travertine outcrops, these and possibly other stages cannot be excluded on the basis of presented data. All of these isotopic dating results concur with the field relation of the travertine complex of the Plitvice Lakes.

[1]  J. Barešić,et al.  Rudjer Bošković Institute Radiocarbon Measurements XIII , 2022, Radiocarbon.

[2]  L. Burckle Late quaternary interglacial stages warmer than present , 1993 .

[3]  D. Rousseau,et al.  West-European terrestrial molluscs assemblages of isotopic stage 11 (Middle Pleistocene): climatic implications , 1992 .

[4]  B. Obelić,et al.  Rudjer Bošković Institute Radiocarbon Measurements XII , 1992, Radiocarbon.

[5]  G. Burr,et al.  Mass Spectrometric 14C and U-Th Measurements in Coral , 1992, Radiocarbon.

[6]  J. Fontes,et al.  A Comparison of Radiocarbon and U/Th Ages on Continental Carbonates , 1992, Radiocarbon.

[7]  W. Giger,et al.  Anthropogenic Influence on the 14C Activity and Other Constituents of Recent Lake Sediments: A Case Study1 , 1992, Radiocarbon.

[8]  I. Bronić,et al.  Experimental Determination of the 14C Initial Activity of Calcareous Deposits , 1992, Radiocarbon.

[9]  J. Mas-Pla,et al.  Radiocarbon Dating of Travertines Precipitated from Freshwater , 1992, Radiocarbon.

[10]  J. Bischoff,et al.  U-series dating of impure carbonates: An isochron technique using total-sample dissolution , 1991 .

[11]  B. Szabo Ages of Travertine Deposits in Eastern Grand Canyon National Park, Arizona , 1990, Quaternary Research.

[12]  A. Gordon,et al.  Late Pleistocene Southern Ocean δ13C variability , 1990 .

[13]  M. Geyh,et al.  Absolute Age Determination , 1990 .

[14]  G. Brook,et al.  Desert paleoenvironmental data from cave speleothems with examples from the Chihuahuan, Somali-Chalbi, and Kalahari deserts , 1990 .

[15]  D. Harkness,et al.  Some Radiocarbon Dates for Tufas of the Craven District of Yorkshire , 1990, Radiocarbon.

[16]  H. Schwarcz,et al.  Dirty calcites 1. Uranium-series dating of contaminated calcite using leachates alone , 1989 .

[17]  Jan Backman,et al.  Pleistocene evolution: Northern hemisphere ice sheets and North Atlantic Ocean , 1989 .

[18]  M. Baskaran,et al.  230Th 234U and 14C dating of the Quaternary carbonate deposits of Saurashtra, India , 1989 .

[19]  H. Chafetz,et al.  Radiocarbon Dating of Travertine Deposits, Arbuckle Mountains, Oklahoma , 1989, Radiocarbon.

[20]  D. Srdoč,et al.  Comparison of the 14C activity of groundwater and recent Tufa from Karst areas in Yugoslavia and Czechoslovakia , 1989, Radiocarbon.

[21]  S. Golubić,et al.  Carbon Uptake in Aquatic Plants Deduced From Their Natural 13C and 14C Content , 1989, Radiocarbon.

[22]  J. Vogel,et al.  Age and Paleoclimatic Implications of the Bet Shean Travertines , 1988, Quaternary Research.

[23]  J. Szulc,et al.  Radiocarbon Dating of Holocene Calcareous Tufa in Southern Poland , 1988, Radiocarbon.

[24]  A. Pazdur The Relations Between Carbon Isotope Composition and Apparent Age of Freshwater Tufaceous Sediments , 1988, Radiocarbon.

[25]  J. Duplessy,et al.  Retreat velocity of the North Atlantic polar front during the last deglaciation determined by 14C accelerator mass spectrometry , 1987, Nature.

[26]  B. Obelić,et al.  Rudjer Bošković Institute Radiocarbon Measurements X , 1987, Radiocarbon.

[27]  B. Obelić,et al.  Rudjer Bošković Institute Radiocarbon Measurements IX , 1987, Radiocarbon.

[28]  D. Srdoč The response of hydrological systems to the variations of the 14C activity of the atmosphere , 1986 .

[29]  H. Schwarcz,et al.  U-Series Analyses of the Lower Travertine at Ehringsdorf, DDR , 1986, Quaternary Research.

[30]  B. Obelić,et al.  On the Initial 14C Activity of Karst Aquifers with Short Mean Residence Time , 1986, Radiocarbon.

[31]  H. Wong,et al.  Radiocarbon Dating of Lake Sediment from Two Karst Lakes in Yugoslavia , 1986, Radiocarbon.

[32]  B. Obelić,et al.  The Effects of Contamination of Calcareous Sediments on their Radiocarbon Ages , 1986, Radiocarbon.

[33]  M. Geyh,et al.  Multiple Dating of a Long Flowstone Profile , 1986, Radiocarbon.

[34]  B. Obelić,et al.  Increase of 14C Activity of Dissolved Inorganic Carbon Along a River Course , 1986, Radiocarbon.

[35]  Bogomil Obelić,et al.  Radiokarbonsko datiranje i polenske analize dvaju tresetišta u Nacionalnom parku »Plitvička jezera« , 1985 .

[36]  R. Folk,et al.  Travertines: Depositional Morphology and the Bacterially Constructed Constituents , 1984 .

[37]  W. Mahaney Quaternary dating methods , 1984 .

[38]  M. Gascoyne,et al.  Growth Mechanisms of Recent Speleothems from Castleguard Cave, Columbia Icefields, Alberta, Canada, Inferred from a Comparison of Uranium-Series and Carbon-14 Age Data , 1983 .

[39]  R. Grün,et al.  Speleothems, Travertines, and Paleoclimates , 1983, Quaternary Research.

[40]  J. Beget Radiocarbon-dated evidence of worldwide early Holocene climate change , 1983 .

[41]  B. Obelić,et al.  Rudjer Bošković Institute Radiocarbon Measurements VII , 1982, Radiocarbon.

[42]  R. Harmon,et al.  230Th/234U dating of travertine from the Bilzingsleben archaeological site , 1980, Nature.

[43]  H. Schwarcz ABSOLUTE AGE DETERMINATION OF ARCHAEOLOGICAL SITES BY URANIUM SERIES DATING OF TRAVERTINES , 1980 .

[44]  B. Obelić,et al.  Radiocarbon Dating of Calcareous Tufa: How Reliable Data can we Expect? , 1980, Radiocarbon.

[45]  M. Sweeting,et al.  Hydrological Implications from 14C Profiling of UK Tufa , 1980, Radiocarbon.

[46]  P. Goldberg,et al.  Uranium series dating of travertine from archaeological sites, Nahal Zin, Israel , 1979, Nature.

[47]  H. Schwarcz,et al.  Stable Isotope Geochemistry of Speleothems and Cave Waters from the Flint Ridge-Mammoth Cave System, Kentucky: Implications for Terrestrial Climate Change during the Period 230,000 to 100,000 Years B.P. , 1978, The Journal of Geology.

[48]  P. J. Thompson,et al.  Critical comment on ‘Uranium series dating of stalagmites from Blanchard Springs Caverns, Arkansas, U.S.A.’ , 1978 .

[49]  R. Harmon,et al.  Palaeoclimatic and geomorphic implications of 230Th/234U dates on speleothems from Britain , 1978, Nature.

[50]  H. Schwarcz,et al.  Interglacial chronology of the Rocky and Mackenzie Mountains based upon 230Th–234U dating of calcite speleothems , 1977 .

[51]  B. Obelić,et al.  Rudjer BošKović Institute Radiocarbon Measurements IV , 1977, Radiocarbon.

[52]  T. Ku The Uranium-Series Methods of Age Determination , 1976 .

[53]  J. A. Carter,et al.  Uranium series dating of stalagmites from Blanchard Springs Caverns, U.S.A. , 1975 .

[54]  H. Schwarcz,et al.  U234U238 Ratios in limestone cave seepage waters and speleothem from West Virginia , 1975 .

[55]  J. Planinić,et al.  Rudjer Bošković Institute Radiocarbon Measurements II , 1973, Radiocarbon: An International Journal of Cosmogenic Isotope Research.

[56]  D. Srdoč,et al.  Rudjer Bošković Institute Radiocarbon Measurements I , 1971, Radiocarbon.

[57]  H. Barker,et al.  Radiocarbon Dating , 1971, Nature.

[58]  M. Tamers SURFACE-WATER INFILTRATION AND GROUNDWATER MOVEMENT IN ARID ZONES OF VENEZUELA. , 1968 .