paleontological age magnetic anomaly number Seafloor ages from
paleontological age magnetic anomaly number Seafloor ages from deep sea drilling versus geomagnetic reversal chronology data for Atlantic ocean; similar data from older oceans permit reversal chronology to be calibrated back to 180 Ma age (Ma) from geomagnetic reversal chronology extrapolated in South Atlantic assuming constant rate of spreading
Chronology of geomagnetic field reversals recorded on ocean floor Ocean floor age, millions of years (Ma), determined largely from deep sea drilling (ODP program)
Chronology of geomagnetic field reversals recorded on ocean floor magnetic anomaly “number” is a convenient identifier of specific features of the magnetic anomaly profiles that have proven useful for correlation between different profiles. Ocean floor age, millions of years (Ma), determined largely from deep sea drilling (ODP program)
Age of the ocean floor Spatial correlation of magnetic anomalies produced by the seafloor spreading “tape recorder” of reversals of the geomagnetic field” Chronology of reversals of geomagnetic field Map pattern of magnetic anomalies and age of ocean floor
Map pattern of magnetic anomaly number ODP drilling site
Map pattern of magnetic anomaly number: North Atlantic
Map pattern of ocean floor age anomaly no. 5 10. 9 6 13 18 21 25 31 34 M 10 N M 0 M 4 M 16 M 21 M 25 120. 4 154. 3 From Muller, et al. , 1997 180
Continental rifting continental shelf
Mid-ocean ridge: rift valley
Fracture zones: transform faults
7000 3500 1500 -500 0 500 -1500 -2500 -3500 -4500 -5500 -6500 South Atlantic Mid-Ocean Ridge
South Atlantic Mid-Ocean Ridge inactive fracture zone 7000 3500 active transform fault 1500 -500 0 500 -1500 -2500 -3500 -4500 -5500 -6500 active ridge crest
Bathymetry of world’s oceans: close correlation with ocean floor age shown in next slide Global topography and bathymetry
Ocean floor age from seafloor spreading tape recorder seafloor age, Ma
Close correlation with ocean floor age and bathymetry Seafloor bathymetry seafloor age, Ma
depth spreading ridge sea water onduction c heat flow by Heat flow by convection Simple thermal model for spreading ridge showing • conductive thermal “boundary layer” (= lithosphere) • convecting mantle beneath. • (oceanic crust is not shown) heat flow by conduction
sea water profile A depth spreading ridge onduction c heat flow by Heat flow by convection temperature profile A depth The temperature profile B (temperature versus depth) at the ridge crest has a very rapid increase from sea bottom temperatures near 0 C to temperatures of 1300 C near the top of the hot, convecting mantle heat flow by conduction
v sea water heat flow by onduction Heat flow by convection conduction x profile B c heat flow by temperature At some distance, x, away from the ridge crest, the seafloor has an age = x/v (where v is half the spreading rate). During the time since the plate formed at the spreading ridge, the plate has cooled to form a conductive “boundary layer”. The thickness of the conductive boundary layer increases with time. depth v spreading ridge profile B
sea water onduction c heat flow by Heat flow by convection heat flow by temperature Thus the depth of the ocean increases with the age of the sea floor. temperature depth profile A depth The decrease in temperature due to cooling of the plate as it moves away from the ridge crest leads to • thermal contraction and • consequent deepening of the ocean bottom. conduction profile B profile A depth spreading ridge profile B
See thermal. pdf for derivation of these curves ocean depth vrs age of ocean floor
Thickness of conductive boundary layer (lithosphere) vrs age of ocean floor
Continental Margin subduction zone What happened to the sub-oceanic plates older than 200 Ma? ch n e tr Su lit bdu ho ct sp ed he o re cea Subduction! nic volcanic arc trench rust Oceanic c Su lit bdu ho c sp ted he o re ce a ni c “island arc” subduction zone
ocean age from seafloor spreading tape recorder seafloor age, Ma
0 Ma NAM EUR AFR SAM
20 Ma
40 Ma
60 Ma
80 Ma
100 Ma
120 Ma
140 Ma
160 Ma
180 Ma The reconstructions are from C. R. Scotese’s PALEOMAP Project
Plate motions: the movie Click on the above to play the “movie”, a file called SFS. MOV. This is a large file (38+ mb); at first it will be slow as the file is downloading, but then you can run it back and forth quite rapidly. It will play faster if you first right-click on the link above, download the file, and then run it from your own machine. Alternatively, you can find the same file (SFS. MOV) on our class folder in the computer lab. The CD that comes with the class text (Stanley) has a lower resolution version of the same reconstruction. The file shows accurate reconstructions of plate positions based on fitting the map patterns of ocean floor ages decoded from the map patterns of magnetic reversals recorded by the seafloor spreading “tape recorder”. The reconstructions are from the PALEOMAP Project (C. R. Scotese) at the University of Texas in Austin.
- Slides: 37