1. Review by B.C. Schreiber Why and how it is used in estimating stratigraphic position of carbonates and evaporites STRONTIUM ISOTOPES

2. ONE OF THE MOST USEFUL, CONSERVATIVE, AND STABLE ELEMENTS FOR ISOTOPIC STUDY IN SEDIMENTARY ROCKS (CARBONATES AND EVAPORITES) IT HAS BEEN TREATED AS A GEOLOGICAL “TRACER” ONE OF THE MOST USEFUL, CONSERVATIVE, AND STABLE ELEMENTS FOR ISOTOPIC STUDY IN SEDIMENTARY ROCKS (CARBONATES AND EVAPORITES) IT HAS BEEN TREATED AS A GEOLOGICAL “TRACER”

3. RESIDENCE TIME OF STRONTIUM IN THE OCEANS >2 M.Y. MIXING TIME OF STRONTIUM IN THE OCEANS ~103 YEARS

4. BACKGROUND During fractional crystallization, Sr tends to be come concentrated in the first minerals to crystallize, leaving Rb in the liquid phase. Hence, the Rb/Sr ratio in residual magma may increase over time, resulting in rocks with increasing Rb/Sr ratios with increasing differentiation. Highest ratios occur in pegmatites. Typically, Rb/Sr increases in the order plagioclase, hornblende, K-feldspar, biotite, muscovite. Therefore, given sufficient time for significant production (ingrowth) of radiogenic 87 Sr, measured 87 Sr/ 86 Sr values will be different in the minerals, increasing in the same order. The Rb-Sr dating method has been used extensively in dating rocks. If the initial amount of Sr is known or can be extrapolated, the age can be determined by measurement of the Rb and Sr concentrations and 87 Sr/ 86 Sr ratio. The dates indicate the true age of the minerals only if the rocks have not been subsequently altered.

5. 4 stable naturally occurring isotopes 84 Sr (0.56%), 86 Sr (9.86%), 81 Sr (7.0%) and 88 Sr (82.58%). 4 stable naturally occurring isotopes 84 Sr (0.56%), 86 Sr (9.86%), 87 Sr (7.0%) and 88 Sr (82.58%)

6. Strontium is present as a ubiquitous minor element in the crust of the Earth –

7. Present in many rock types. Strontium is present as a ubiquitous minor element in the crust of the Earth –

8. Typically found in concentrations of a few hundred parts per million Strontium is present as a ubiquitous minor element in the crust of the Earth – Present in many rock types.

9. 87 Sr 87 Rb half-life of 48,800,000 years

12. 4 stable naturally occurring isotopes 84 Sr (0.56%), 86 Sr (9.86%), 81 Sr (7.0%) and 88 Sr (82.58%). 4 stable naturally occurring isotopes 84 Sr (0.56%), 86 Sr (9.86%), 87 Sr (7.0%) and 88 Sr (82.58%)

13. 4 stable naturally occurring isotopes 84 Sr (0.56%), 86 Sr (9.86%), 87 Sr (7.0%) and 88 Sr (82.58%)

14. Capo et al., 1998

15. IN A MAGMA, IGNEOUS PROCESSES CONCENTRATE RUBIDUM IN THE RESIDUAL MELT SO THE LATER FORMED MINERALS CONTAIN MORE AND MORE RUBIDIUM IN A MAGMA, IGNEOUS PROCESSES CONCENTRATE RUBIDUM IN THE RESIDUAL MELT SO THE LATER FORMED MINERALS CONTAIN MORE AND MORE RUBIDIUM SOURCES OF Sr From radioactive decay of 87 Rb 85 Rb = 72.165% 87 Rb = 27.834%

16. Primordial 87 Sr/ 86 Sr ratio of 0.699, value derived from meteorites, NOW HIGHER ON EARTH due to the decay of 87 Rb Faure, 1991

21. Goldrich Stability Series First to Crystallize Last to Crystallize Slow Weathering Fast Weathering Bowen’s Reaction Series First to Crystallize Last to Crystallize Last to Crystallize WEATHERING

27. CONTESSA QUARRY marine carbonates

28. Modern seawater = 87 Sr/ 86 Sr = 0.7092

29. CONTROLLED BY THE EXTENT THE Sr 2+ CAN SUBSTITUTE FOR Ca 2+ IN CALCIUM BEARING MINERALS CONTROLLED BY THE EXTENT THE Sr 2+ CAN SUBSTITUTE FOR Ca 2+ IN CALCIUM BEARING MINERALS

30. Two sources of 87 Sr in any material: (1) formed primordial nucleo-synthesis along with 84 Sr, 86 Sr and 88 Sr (2) radioactive decay of 87 Rb.

31. The ratio 87 Sr/ 86 Sr is the parameter typically reported in geologic investigations

35. Elderfield, 1986

36. PRESENT DAY SPREADING CENTERS

39. WHAT EFFECT DOES RAPID/SLOW SEAFLOOR SPREADING HAVE ?

40. Based on results of Alt et al, 1986,

41. WHAT DOES RAPID SEA FLOOR SPREADING DO TO THE OCEANS?

44. Elderfield, 1986

45. Visser, 1989

50. Sr IN GYPSUM REMAINS WITHIN SULPHATE EVEN WHEN IT DEHYDRATES BUT WHEN IT REHYDRATES, MUCH Sr IS LOST ALSO WHEN ARAGONITE GOES TO CALCITE MUCH Sr IS LOST Sr IN GYPSUM REMAINS WITHIN SULPHATE EVEN WHEN IT DEHYDRATES BUT WHEN IT REHYDRATES, MUCH Sr IS LOST ALSO WHEN ARAGONITE GOES TO CALCITE MUCH Sr IS LOST

56. CONTESSA QUARRY marine carbonates

58. BACKGROUND During fractional crystallization, Sr tends to be come concentrated in the first minerals to crystallize, leaving Rb in the liquid phase. Hence, the Rb/Sr ratio in residual magma may increase over time, resulting in rocks with increasing Rb/Sr ratios with increasing differentiation. Highest ratios occur in pegmatites. Typically, Rb/Sr increases in the order plagioclase, hornblende, K-feldspar, biotite, muscovite. Therefore, given sufficient time for significant production (ingrowth) of radiogenic 87 Sr, measured 87 Sr/ 86 Sr values will be different in the minerals, increasing in the same order. The Rb-Sr dating method has been used extensively in dating rocks. If the initial amount of Sr is known or can be extrapolated, the age can be determined by measurement of the Rb and Sr concentrations and 87 Sr/ 86 Sr ratio. The dates indicate the true age of the minerals only if the rocks have not been subsequently altered.

59. Secondly, differences in the relative mobilities of water at scales ranging from inter-grain pores to the catchment scale may also profoundly affect 87 Sr/ 86 Sr (Bullen et al., 1996). For example, the chemical composition and the resultant 87 Sr/ 86 Sr in immobile waters at a plagioclase-hornblende grain boundary versus a quartz-mica boundary will be different from eachother.

60. Third, a difference in the relative "effective" surface areas of minerals in one portion o f the rock unit will also cause differences in chemistry and isotopic composition; "poisoning" of reactive surfaces by organic coatings is an example of this kind of process. In a fundamental sense, because the waters in shallow systems are not in chemical equilibrium with the rocks, it is unrealistic to expect that waters along flowpaths within even a constant-mineralogy unit should have a constant 87 Sr/ 86 Sr. Instead, the waters moving along specific flowpaths slowly react with the rocks and gradually approach

61. The important concept for isotopic tracing is that Sr derived from any mineral through weathering reactions will have the same 87 Sr/ 86 Sr as the mineral itself. Therefore, differences in 87 Sr/ 86 Sr among ground waters require either (a) differences in mineralogy along contrasting flowpaths, or (b) differences in the relative amounts of Sr weathered from the same suite of minerals.