%0 Journal Article %1 Schmalholz:2009 %A Schmalholz, S. M. %A Kaus, B. J. P. %A Burg, J. P. %C BOULDER %D 2009 %I GEOLOGICAL SOC AMER, INC %J GEOLOGY %K BENEATH; CRUSTAL; DEFORMATION; EARTHQUAKES; JELLY MANTLE; PLATEAU SANDWICH; TEMPERATURE; THICKNESS; TIBET; %N 9 %P 775--778 %R 10.1130/G25678A.1 %T Stress-strength relationship in the lithosphere during continental collision %V 37 %X Lithospheric strength profiles generated for a shortening continental lithosphere generally predict excessively high differential stresses in the sub-Moho continental mantle; this seems inconsistent with the relative scarcity of earthquakes at this depth. This inconsistency was put forward as evidence for weak mantle rheology. However, this argument implicitly assumes that strength envelopes are valid in actively deforming regions. We test this assumption on two end-member model lithospheres having identical upper crustal rheologies, but with (1) a weak lower crust and strong mantle, and (2) a strong lower crust and weak mantle. For this purpose, we compare one-dimensional (1-D) with 2-D visco-elasto-plastic numerical models of continental shortening. The 2-D models show that strongly heterogeneous deformation typically follows initially homogeneous deformation. Lithospheric-scale buckle folds and shear zones result in strain rate variations of as much as three orders of magnitude. Differential stresses in the upper crust are close to yield, as predicted by 1-D models. Stresses in deeper lithospheric regions, however, are significantly smaller than in 1-D models, especially in actively deforming regions. Systematic numerical simulations as a function of temperature and deformation rate reveal that 1-D models are reliable in hot and/or slowly deforming lithospheres only. The relative scarcity of earthquakes at mantle levels should thus be interpreted as an intrinsic consequence of strong lithospheric deformation rather than as evidence for a weak upper mantle.

@article{Schmalholz:2009, abstract = {Lithospheric strength profiles generated for a shortening continental lithosphere generally predict excessively high differential stresses in the sub-Moho continental mantle; this seems inconsistent with the relative scarcity of earthquakes at this depth. This inconsistency was put forward as evidence for weak mantle rheology. However, this argument implicitly assumes that strength envelopes are valid in actively deforming regions. We test this assumption on two end-member model lithospheres having identical upper crustal rheologies, but with (1) a weak lower crust and strong mantle, and (2) a strong lower crust and weak mantle. For this purpose, we compare one-dimensional (1-D) with 2-D visco-elasto-plastic numerical models of continental shortening. The 2-D models show that strongly heterogeneous deformation typically follows initially homogeneous deformation. Lithospheric-scale buckle folds and shear zones result in strain rate variations of as much as three orders of magnitude. Differential stresses in the upper crust are close to yield, as predicted by 1-D models. Stresses in deeper lithospheric regions, however, are significantly smaller than in 1-D models, especially in actively deforming regions. Systematic numerical simulations as a function of temperature and deformation rate reveal that 1-D models are reliable in hot and/or slowly deforming lithospheres only. The relative scarcity of earthquakes at mantle levels should thus be interpreted as an intrinsic consequence of strong lithospheric deformation rather than as evidence for a weak upper mantle.}, added-at = {2010-08-12T23:06:12.000+0200}, address = {BOULDER}, af = {Schmalholz, Stefan M. Kaus, Boris J. P. Burg, Jean-Pierre}, author = {Schmalholz, S. M. and Kaus, B. J. P. and Burg, J. P.}, author-address = {[Schmalholz, Stefan M.; Kaus, Boris J. P.; Burg, Jean-Pierre] ETH, Dept Earth Sci, CH-8092 Zurich, Switzerland. [Kaus, Boris J. P.] Univ So Calif, Dept Earth Sci, Los Angeles, CA 90089 USA.}, bdsk-url-1 = {http://dx.doi.org/10.1130/G25678A.1}, biburl = {https://www.bibsonomy.org/bibtex/296e85bd75bd46527668f5092d1ca5b06/jkmacc}, cited-reference-count = {28}, date-added = {2010-04-03 12:08:58 -0600}, date-modified = {2010-04-03 12:08:58 -0600}, document-type = {Article}, doi = {10.1130/G25678A.1}, e-mail-address = {schmalholz@erdw.ethz.ch}, fu = {ETH Zurich}, fx = {We thank Susan Ellis, Ebbe Hartz, and an anonymous reviewer for helpful and constructive reviews. This work has been supported by the ETH Zurich.}, interhash = {7eb1bc77958fc70a18a5e9a5ba5eb2b4}, intrahash = {96e85bd75bd46527668f5092d1ca5b06}, isi = {ISI:000269812000004}, isi-document-delivery-number = {494KP}, iso-source-abbreviation = {Geology}, issn = {0091-7613}, journal = {GEOLOGY}, keywords = {BENEATH; CRUSTAL; DEFORMATION; EARTHQUAKES; JELLY MANTLE; PLATEAU SANDWICH; TEMPERATURE; THICKNESS; TIBET;}, language = {English}, month = Sep, number = 9, page-count = {4}, pages = {775--778}, publication-type = {J}, publisher = {GEOLOGICAL SOC AMER, INC}, publisher-address = {PO BOX 9140, BOULDER, CO 80301-9140 USA}, reprint-address = {Schmalholz, SM, ETH, Dept Earth Sci, Sonneggstr 5, CH-8092 Zurich, Switzerland.}, source = {GEOLOGY}, subject-category = {Geology}, times-cited = {0}, timestamp = {2010-08-12T23:06:15.000+0200}, title = {Stress-strength relationship in the lithosphere during continental collision}, volume = 37, year = 2009 }