Thermal structure of oceanic transform faults
Thermal structure of oceanic transform faults
Geology (Boulder) (April 2007) 35 (4): 307-310
- crust
- data processing
- digital simulation
- faults
- finite element analysis
- heat flow
- lithosphere
- mantle
- mid-ocean ridges
- numerical models
- ocean floors
- oceanic crust
- oceanic lithosphere
- plate tectonics
- rheology
- sea-floor spreading
- spreading centers
- strike-slip faults
- temperature
- thermal regime
- thermomechanical properties
- three-dimensional models
- transform faults
- upwelling
- COMSOL
We use three-dimensional finite element simulations to investigate the temperature structure beneath oceanic transform faults. We show that using a rheology that incorporates brittle weakening of the lithosphere generates a region of enhanced mantle upwelling and elevated temperatures along the transform; the warmest temperatures and thinnest lithosphere are predicted to be near the center of the transform. Previous studies predicted that the mantle beneath oceanic transform faults is anomalously cold relative to adjacent intraplate regions, with the thickest lithosphere located at the center of the transform. These earlier studies used simplified rheologic laws to simulate the behavior of the lithosphere and underlying asthenosphere. We show that the warmer thermal structure predicted by our calculations is directly attributed to the inclusion of a more realistic brittle rheology. This temperature structure is consistent with a wide range of observations from ridge-transform environments, including the depth of seismicity, geochemical anomalies along adjacent ridge segments, and the tendency for long transforms to break into small intratransform spreading centers during changes in plate motion.