Publications

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2011 Publication List

[1] Schmedes, J., R. J.Archuleta, and D. Lavallée (2010). Correlation of earthquake source parameters inferred from dynamic rupture simulations, J. Geophys. Res., 115,B03304, doi:10.1029/2009JB006689.

[2] Schmedes, J., R. J. Archuleta, and D. Lavallée (2010). Dependency of supershear transition and ground motion on the autocorrelation of initial stress, Tectonophysics, 293, 222-235, doi: 10.1016/j.tecto.2010.05.013

[3] Liu, Q., Archuleta, R.J., and Smith, R. B. (2010). Ground Motion from Dynamic Ruptures on the Wasatch Fault Embedded in a 3-D Velocity Structure, Seismol. Res. Lett., 81(2), p. 320. (2010 SSA Annual Meeting)

[4] Liu, Q., Archuleta,R. J. and Smith, R.B.(2010). Nucleation by Dynamic Triggering on a Multi-Segment Fault, Abstract S33E-03 presented at 2010 Fall Meeting, AGU, San Francisco, Calif.

[5] Liu, Q., Ma, S., and Archuleta, R. J.(2011). Dynamic Rupture Modeling of the 2008 Wenchuan Earthquake, Seismol. Res. Lett., 82(2), p.

[1] Day, S.M., K.B. Olsen, and Y. Cui (2011). Large-scale earthquake simulations and the prediction of strong ground motion (invited talk), SIAM Conference on Mathematical and Computational Issues in the Geosciences, March 21-24, 2011, Long Beach.

[2] Shi, Z., and S. Day (2010), Dynamic ground motion from earthquake ruptures in models of non-planar faults, Abstract S21C-2071, presented at 2010 Fall Meeting, AGU, San Francisco, Calif., 13-17 Dec.

[1] Graves, R. W., and B. T. Aagaard (2011). Testing Long-Period Ground-Motion Simulations of Scenario Earthquakes Using the Mw 7.2 El Mayor–Cucapah Mainshock: Evaluation of Finite-Fault Rupture Characterization and 3D Seismic Velocity Models, BSSA, 101, 895-907, doi: 10.1785/0120100233.

[2] RAMIREZ-GUZMAN, L., GRAVES, R. W., OLSEN, K. B., BOYD, O. S., HARTZELL, S., U.S. NI, S., SOMERVILLE, P. G., WILLIAMS, R. A., and ZHONG, J. (2011). Central United States Earthquake Ground Motion Simulation Working Group: The 1811–1812 New Madrid Earthquake Sequence, SRL, 82(2), p. 275, 10.1785/gssrl.82.2.273.

[3] SOMERVILLE, P. G., CALLAGHAN, S., MAECHLING, P., GRAVES, R. W., COLLINS, N., OLSEN, K. B., IMPERATORI, W., JONES, M., ARCHULETA, R., SCHMEDES, J., and JORDAN, T.H. (2011). The SCEC Broadband Ground Motion Simulation Platform, SRL, 82(2), p. 275, 10.1785/gssrl.82.2.273.

[4] ELY, G.P., JORDAN, T.H., MAECHLING, P., OLSEN, K.B., DAY, S.M., MINSTER, J.-B., GRAVES, R.W., BIELAK, J., Taborda , R., Beroza , G., Ma, S., Cui , Y., Urbanic , J., and Callaghan , S. (2010). The Big Ten Earthquake Scenarios for Southern California, SRL, 81(2), p. 311.

[5] GRAVES, R., CALLAGHAN, S., SMALL, P., MEHTA, G., MILNER, K., JUVE, G., VAHI, K.,FIELD, E., Deelman , E., Okaya , D., Maechling , P., and Jordan , T. (2010). The CyberShake Project: Full-Waveform Probabilistic Seismic Hazard Calculations for Southern California, SRL, 81(2), p. 329.

[6] Milner, K., Jordan, T. H., Graves, R. W., Callaghan, S., Maechling, P. J., Field, E. H., Small, P., and the CyberShake Working Group (2010), A CyberShake-Based System for Operational Forecasting of Earthquake Ground Motions, Abstract S51A-1926 presented at 2010 Fall Meeting, AGU, San Francisco, Calif., 13-17 Dec.

Bielak, J., Karaoglu, H., and Taborda, R. (2011). Memory-efficient displacement-based internal friction for wave propagation simulation. Geophysics. Submitted for publication.

Taborda, R. and Bielak, J. (2011). Large-scale earthquake simulation — Computational seismology and complex engineering systems. Computing in Science and Engineering, 13(4). Accepted for publication.

Bielak, J., Graves, R. W., Olsen, K. B., Taborda, R., Ram´ırez-Guzm´an, L., Day, S. M., Ely, G. P., Roten, D., Jordan, T. H., Maechling, P. J., Urbanic, J., Cui, Y., and Juve, G. (2010). The ShakeOut earthquake scenario: Verification of three simulation sets. Geophysical Journal International, 180(1):375–404.

Taborda, R., Lopez, J., Karaoglu, H., Urbanic, J., and Bielak, J. (2010). Speeding up finite element wave propagation for large-scale earthquake simulations. Technical Report CMU-PDL-10-109, Carnegie Mellon University, Parallel Data Lab.

Taborda, R. and Bielak, J. (2011). Full 3D integration of site-city effects in regional scale earthquake simulations. In Proceedings of the 2011 EURODYN Conference. Accepted for publication.

Taborda, R. and Bielak, J. (2010). Three dimensional nonlinear soil and site-city effects in earthquake simulations. In Abstracts presented at 2010 Fall Meeting, AGU, San Francisco, California, December 13–17. Abstract S51A-1923.

Bielak, J., Karaoglu, H., and Taborda, R. (2010). Memory-efficient displacement-based internal friction for wave propagation simulation. In Abstracts presented at 2010 Fall Meeting, AGU, San Francisco, California, December 13–17. Abstract S43B-2078.

Taborda, R. and Bielak, J. (2010). Full 3D nonlinear soil effects in large-scale ground motion simulations. In Proceedings and Abstracts of the 2010 SCEC Annual Meeting, Palm Springs, CA, September 11-15.

Taborda, R. and Bielak, J. (2010). Site-city effects in large-scale 3D earthquake simulations. In Proceedings and Abstracts of the 2010 SCEC Annual Meeting, Palm Springs, CA, September 11-15.

Taborda, R., Trocha, P. and Bielak, J. (2011). Influence of the built environment on ground motion using 3D large-scale earthquake simulation. In Abstracts presented at the 2011 Annual Meeting, SSA, Memphis, TN, April 12--16.

Karaoglu, H., Taborda, R. and Bielak, J. (2011). Strain-energy compatible partition of Hooke's law --- Application to the modeling of intrinsic attenuation in wave propagation. In Abstracts presented at the 2011 Annual Meeting, SSA, Memphis, TN, April 12--16.

Bao, H., Bielak, J., Ghattas, O., Kallivokas, L.F., O’Hallaron, D.R., Shewchuk, J.R. & Xu, J., 1998. Large-scale simulation of elastic wave propagation in heterogeneous media on parallel computers, Comput. Methods Appl. Mech. Eng., 152(1-2), 85–102.

Bielak, J., Xu, J. & Ghattas, O., 1999. Earthquake ground motion and structural response in alluvial valleys, J. Geotech. Geoenviron. Eng., ASCE, 125(5), 413–423.

Bielak, J., Ghattas, O. & Kim, E.J., 2005. Parallel octree-based finite element method for large-scale earthquake ground motion simulation, Comput. Model. Eng. Sci., 10(2), 99–112.

Bielak, J., Karaoglu, H. & Taborda, R., 2011. Memory-efficient displacement-based internal friction for wave propagation simulation, Geophysics, (accepted for publication).

Bielak, J., Graves, R. W., Olsen, K. B., Taborda, R., Ramírez-Guzmán, L., Day, S. M., Ely, G. P., Roten, D., Jordan, T. H., Maechling, P. J., Urbanic, J., Cui, Y. and Juve, G. (2010). The ShakeOut earthquake scenario: Verification of three simulation sets. Geophysical Journal International, 180(1): 375–404.

Lysmer, J. & Kuhlemeyer, R.L., 1969. Finite dynamic model for infinite media, J. Eng. Mech. Div., ASCE, 95(EM4), 859–877.

Tu, T., Yu, H., Ramírez-Guzmán, L., Bielak, J., Ghattas, O., Ma, K.-L., & O’Hallaron, D.R., 2006. From mesh generation to scientific visualization: an end-to-end approach to parallel supercomputing, in Proceedings of the 2006 ACM/IEEE International Conference for High Performance Computing, Networking, Storage and Analysis, p. 15, IEEE Computer Society, Tampa, Florida. Available [online]: http://dx.doi.org/10.1109/SC.2006.32

Taborda, R., López, J., Karaoglu, H., Urbanic, J. and Bielak, J. (2010). Speeding up finite element wave propagation for large-scale earthquake simulations. Technical Report CMU-PDL-10-109, Parallel Data Lab, Carnegie Mellon University. Available [online]: http://www.pdl.cmu.edu/PDL-FTP/AstroDISC/CMU-PDL-10-109.pdf


Publications during 2010 - 2011

[1] Bielak, J., R.W. Graves, K.B. Olsen, R. Taborda, L. Ramírez-Guzmán, S.M. Day, G.P. Ely, D. Roten, T.H. Jordan, P.J. Maechling, J. Urbanic, Y. Cui, G. Juve, “The ShakeOut earthquake scenario: Verification of three simulation sets,” Geophysical Journal International, 180(1):375–404, doi: 10.1111/j.1365-246X.2009.04417x, 2009.

[2] Bielak, J., Karaoglu, H., and Taborda, R. (2010). Memory-efficient displacement-based internal friction for wave propagation simulation. In Abstracts presented at 2010 Fall Meeting, AGU, San Francisco, California, December 13–17. Abstract S43B-2078.

[3] Bielak, J., Karaoglu, H., and Taborda, R. (2011). Memory-efficient displacement-based internal friction for wave propagation simulation. Geophysics. Submitted for publication.

[4] Callaghan, S., Deelman, E., Gunter, D., Gideon Juve, Philip Maechling, Christopher Brooks, Karan Vahi, Kevin Milner, Robert Graves, Edward Field, David Okaya, Thomas Jordan (2010), Scaling up workflow-based applications, Journal of Computer and System Sciences, 76:6, pp. 428-446,September 2010

[5] Callaghan, S., Maechling, P., Small, P., Milner, K., Juve, G., Jordan, T. H., Deelman, E., Mehta, G., Vahi, K., Gunter, D., Beattie, K., Brooks, C. "Metrics for Heterogeneous Scientific Workflows: A Case Study of an Earthquake Science Application". International Journal of High Performance Computing Applications, in press.

[6] Chen, P., Jordan T. H., and Lee, E.J. (2010) Perturbation Kernels for Generalized Seismological Data Functionals (GSDF), Geophysical Journal International, 183, 869-883, doi: 10.1111/j.1365-246X.2010.04758.x

[7] Chen, P., Jordan T. H., and Zhou, L. (2010) Resolving fault plane ambiguity for small earthquakes, Geophysical Journal International, 181, 493-501, doi: 10.1111/j.1365-246X.2010.04515.x

[8] Chourasia, A. 2010. GlyphSea. In ACM SIGGRAPH 2010 Computer Animation Fesitval (Los Angeles, California, July 26 - 30, 2010). SIGGRAPH '10. ACM, New York, NY, 111-111

[9] Cruz-Atienza, V.M., and K.B. Olsen, K.B. (2010). Supershear Mach-waves expose the fault breakdown slip, Tectonophysics , pp 1-12, doi:10.1016/j.tecto.2010.05.012

[10] Cui, Y., Looking forward to Architecture Changes with Seismic Wave Propagation Using a 3D Finite Difference Code, Int'l Conference of Numerical Analysis and Applied Mathematics, Rhodes, Greece, 19-25 September 2010.

[11] Cui, Y., Olsen, K. B., Jordan, T. H., Lee, K., Zhou, J., Small, P., Roten, D., Ely, G., Panda, D. K., Chourasia, A., Levesque, J., Day, S. M., and Maechling, P. (2010) Scalable Earthquake Simulation on Petascale Supercomputers. In Proceedings of the 2010 ACM/IEEE International Conference for High Performance Computing, Networking, Storage and Analysis, doi=10.1109/SC.2010.45 (SC10 Gordon Bell Finalist) [12] Ely, G.P., Jordan, T.H., Maechling, P., Olsen, K.B., Day, S.M., Minster, J.-B., Graves, R.W., Bielak, J., Taborda , R., Beroza , G., Ma, S., Cui , Y., Urbanic , J., and Callaghan , S. (2010). The Big Ten Earthquake Scenarios for Southern California, SRL, 81(2), p. 311.

[13] Ely, G. P., S. M. Day, and J.-B. Minster (2010), Dynamic rupture models for the southern San Andreas fault, Bull. Seism. Soc. Am. , Vol. 100, pp. 131-150, doi: 10.1785/0120090187

[14] Graves, R. W., and B. T. Aagaard (2011). Testing Long-Period Ground-Motion Simulations of Scenario Earthquakes Using the Mw 7.2 El Mayor–Cucapah Mainshock: Evaluation of Finite-Fault Rupture Characterization and 3D Seismic Velocity Models, BSSA, 101, 895-907, doi: 10.1785/0120100233.

[15] Graves, R., Callaghan, S., Small, P., Mehta, G., Milner, K., Juve, G., Vahi, K.,Field, E., Deelman , E., Okaya , D., Maechling , P., and Jordan , T. (2010). The CyberShake Project: Full-Waveform Probabilistic Seismic Hazard Calculations for Southern California, SRL, 81(2), p. 329.

[16] Graves, R.W., Pitarka, A. (2010) Broadband ground-motion simulation using a hybrid approach Bulletin of the Seismological Society of America (October 2010), 100(5A):2095-2123, doi:10.1785/0120100057

[17] Graves, R. W., B. T. Aagaard, and K. W. Hudnut (2010). The ShakeOut Earthquake source and ground motion simulations, Earthquake Spectra, in press.

[18] Graves, R., T. Jordan; S. Callaghan; E. Deelman; E. Field; G. Juve; C. Kesselman; P. Maechling; G. Mehta; K. Milner; D. Okaya; P. Small; and K. Vahi (2010). CyberShake: A Physics-Based Seismic Hazard Model for Southern California, Pure Applied Geophys., May 2010

[19] Juve, G., Ewa Deelman, E., Vahi, K., Mehta, g., Berriman, B., Berman, B. P., Maechling, P. (2010), Data Sharing Options for Scientific Workflows on Amazon EC2, 22nd IEEE/ACM Conference on Supercomputing (SC10), New Orleans, Louisiana, November 2010

[20] Juve, G., Ewa Deelman, E., Vahi, K., Mehta, g., Berriman, B., Berman, B. P., Maechling, P. (2010): Scientific Workflow Applications on Amazon EC2 CoRR abs/1005.2718: (2010)

[21] Juve, G., Ewa Deelman, E., Vahi, K., Mehta, g., Berriman, B., Berman, B. P., Maechling, P. (2010) Data Sharing Options for Scientific Workflows on Amazon EC2 CoRR abs/1010.4822: (2010)

[22] Juve, G., Deelman, E., Vahi, K., Mehta, G. (2010) Experiences with Resource Provisioning for Scientific Workflows Using Corral, Scientific Programming, 18:2, pp. 77-92, April 2010

[23] Juve, G., Ewa Deelman (2010), "Scientific Workflows and Clouds", ACM Crossroads, vol. 16, no. 3, pp. 14-18, Spring 2010.

[24] Juve, G. and Ewa Deelman (2010), "Scientific Workflows in the Cloud", in Grids, Clouds and Virtualization, M. Cafaro and G. Aloisio, Eds. Springer, pp. 71-91, 2010.

[25] Karaoglu, H., Taborda, R. and Bielak, J. (2011). Strain-energy compatible partition of Hooke's law --- Application to the modeling of intrinsic attenuation in wave propagation. In Abstracts presented at the 2011 Annual Meeting, SSA, Memphis, TN, April 12--16.

[26] Liu, Q., Archuleta,R. J. and Smith, R.B.(2010). Nucleation by Dynamic Triggering on a Multi-Segment Fault, Abstract S33E-03 presented at 2010 Fall Meeting, AGU, San Francisco, Calif.

[27] Liu, Q., Ma, S., and Archuleta, R. J.(2011). Dynamic Rupture Modeling of the 2008 Wenchuan Earthquake, Seismol. Res. Lett., 82(2), p.

[28] Mai, P.M., W. Imperatori, and K.B. Olsen (2010). Hybrid broadband ground-motion simulations: combining long-period deterministic synthetics with high-frequency multiple S-to-S back-scattering, Bull. Seis. Soc. Am. 100, 5A, 2124-2142

[29] Mena, B., P.M. Mai, K.B. Olsen, M.D. Purvance, and J.N. Brune (2010). Hybrid broadband ground motion simulation using scattering Green's functions: application to large magnitude events, Bull. Seis. Soc. Am. 100, 5A, 2143-2162

[30] Moczo, P., J Kristek, P Franek, E Chalub, PY Bard, S Tsune, F Hollender, T Iwata, A Iwaki, E Priolo, P Klin, S Aoi, C Mariotti, J Bielak, R Taborda, H Karaoglu, V Etienne, J Virieux (2010), Numerical Modeling of Earthquake Ground Motion in the Mygdonian Basin, Greece: Verification of the 3D Numerical Methods, Proc. of the Annual Meeting of the Seis. Soc. of America.

[31] Olsen, K.B., and J.E. Mayhew (2010). Goodness-of-fit Criteria for Broadband Synthetic Seismograms, With Application to the 2008 Mw5.4 Chino Hills, CA, Earthquake, Seism. Res. Lett. 81 , 715-723

[32] Potluri, S., P. Lai, K. Tomko, S. Sur, Y. Cui, M. Tatineni, K. Schulz, W. Barth, A. Majumdar, and D. K. Panda (2010), "Quantifying performance benefits of overlap using MPI-2 in a seismic modeling application", Proceedings of the 24th ACM Int'l Conference on Supercomputing, 2010, pp. 17-25, doi: 10.1145/1810085.1810092

[33] Ramirez-Guzman, L., Graves, R. W., Olsen, K. B., Boyd, O. S., Hartzell, S., U.S. Ni, S., Somerville, P. G., Williams, R. A., And Zhong, J. (2011). Central United States Earthquake Ground Motion Simulation Working Group: The 1811–1812 New Madrid Earthquake Sequence, SRL, 82(2), p. 275, 10.1785/gssrl.82.2.273.

[34] Schmedes, J., R. J.Archuleta, and D. Lavallée (2010). Correlation of earthquake source parameters inferred from dynamic rupture simulations, J. Geophys. Res., 115,B03304, doi:10.1029/2009JB006689.

[35] Schmedes, J., R. J. Archuleta, and D. Lavallée (2010). Dependency of supershear transition and ground motion on the autocorrelation of initial stress, Tectonophysics, 293, 222-235, doi: 10.1016/j.tecto.2010.05.013

[36] Somerville, P. G., Callaghan, S., Maechling, P., Graves, R. W., Collins, N., Olsen, K. B., Imperatori, W., Jones, M., Archuleta, R., Schmedes, J., And Jordan, T.H. (2011). The SCEC Broadband Ground Motion Simulation Platform, SRL, 82(2), p. 275, 10.1785/gssrl.82.2.273.

[37] Taborda, R. and Bielak, J. (2011). Large-scale earthquake simulation — Computational seismology and complex engineering systems. Computing in Science and Engineering, 13(4). Accepted for publication.

[38] Taborda, R., Lopez, J., Karaoglu, H., Urbanic, J., and Bielak, J. (2010). Speeding up finite element wave propagation for large-scale earthquake simulations. Technical Report CMU-PDL-10-109, Carnegie Mellon University, Parallel Data Lab.

[39] Taborda, R. and Bielak, J. (2011). Full 3D integration of site-city effects in regional scale earthquake simulations. In Proceedings of the 2011 EURODYN Conference. Accepted for publication.

[40] Taborda, R. and Bielak, J. (2010). Three dimensional nonlinear soil and site-city effects in earthquake simulations. In Abstracts presented at 2010 Fall Meeting, AGU, San Francisco, California, December 13–17. Abstract S51A-1923.

[41] Taborda, R. and Bielak, J. (2010). Full 3D nonlinear soil effects in large-scale ground motion simulations. In Proceedings and Abstracts of the 2010 SCEC Annual Meeting, Palm Springs, CA, September 11-15.

[42] Taborda, R. and Bielak, J. (2010). Site-city effects in large-scale 3D earthquake simulations. In Proceedings and Abstracts of the 2010 SCEC Annual Meeting, Palm Springs, CA, September 11-15.

[43] Taborda, R., Trocha, P. and Bielak, J. (2011). Influence of the built environment on ground motion using 3D large-scale earthquake simulation. In Abstracts presented at the 2011 Annual Meeting, SSA, Memphis, TN, April 12--16.

[44] Zhou, J., Y. Cui, S. Davis, C. C. Guest, P. Maechling, "Workflow-based high performance data transfer and ingestion to petascale simulations on TeraGrid", IEEE Computational Sciences and Optimization (CSO10), vol. 1, pp. 343-347, 2010.


Examples of recent SCEC/CME publications

  1. Bielak, J., R.W. Graves, K.B. Olsen, R. Taborda, L. Ramírez-Guzmán, S.M. Day, G.P. Ely, D. Roten, T.H. Jordan, P.J. Maechling, J. Urbanic, Y. Cui, G. Juve, “The ShakeOut earthquake scenario: Verification of three simulation sets,” Geophysical Journal International doi: 10.1111/j.1365-246X.2009.04417x, 2009.
  2. Callaghan, Scott, Ewa Deelman, Dan Gunter, Gideon Juve, Philip Maechling, Christopher Brooks, Karan Vahi, Kevin Milner, Robert Graves, Edward Field, David Okaya, Thomas Jordan (2010), Scaling up workflow-based applications, Journal of Computer and System Sciences, 76:6, pp. 428-446,September 2010
  3. Chen, P., Jordan T. H., and Lee, E.J. (2010) Perturbation Kernels for Generalized Seismological Data Functionals (GSDF), Geophysical Journal International, 183, 869-883, doi: 10.1111/j.1365-246X.2010.04758.x
  4. Chen, P., Jordan T. H., and Zhou, L. (2010) Resolving fault plane ambiguity for small earthquakes, Geophysical Journal International, 181, 493-501, doi: 10.1111/j.1365-246X.2010.04515.x
  5. Cruz-Atienza, V.M., and K.B. Olsen, K.B. (2010). Supershear Mach-waves expose the fault breakdown slip, Tectonophysics , pp 1-12, doi:10.1016/j.tecto.2010.05.012
  6. Cui, Y., Olsen, K. B., Jordan, T. H., Lee, K., Zhou, J., Small, P., Roten, D., Ely, G., Panda, D. K., Chourasia, A., Levesque, J., Day, S. M., and Maechling, P. (2010) Scalable Earthquake Simulation on Petascale Supercomputers. In Proceedings of the 2010 ACM/IEEE International Conference for High Performance Computing, Networking, Storage and Analysis, doi=10.1109/SC.2010.45 (SC10 Gordon Bell Finalist)
  7. Cui, Y., Chourasia, A., Moore, R., Olsen, K., Maechling, P., Jordan, T., The TeraShake Computational Platform, Advances in Geocomputing, Lecture Notes in Earth Sciences 119, DOI 10.1007/978-3-540-85879-9_7, pp229-278, editor H. Xing, Springer-Verlag Berlin Heidelberg, 2009.
  8. Cruz-Atienza, V.M., K.B. Olsen, and L.A. Dalguer (2009). Estimation of the breakdown slip from strong-motion seismograms: insights from numerical experiments Bull. Seis. Soc. Am. 9, 3454-3469, doi:10.1785/0120080330
  9. Dalguer, L.A., and S.M. Day (2009). Asymmetric rupture of large aspect-ratio faults at bimaterial interface in 3D, Geophys. Res. Lett. , Vol. 36, L23307, doi:10.1029/2009GL040303
  10. Doser, D.I., K.B. Olsen, F.F. Pollitz, R.S. Stein, and S. Toda (2009). The 1911 M~6.6 Calaveras earthquake: Source parameters and the role of static, viscoelastic and dynamic Coulomb stress changes imparted by the 1906 San Francisco earthquake, Bull. Seis. Soc. Am. 99, 1746-1759.
  11. Ely, G. P., S. M. Day, and J.-B. Minster (2010), Dynamic rupture models for the southern San Andreas fault, Bull. Seism. Soc. Am. , Vol. 100, pp. 131-150, doi: 10.1785/0120090187
  12. Ely, G. P., S. M. Day, and J.-B. Minster (2009), A support-operator method for 3D rupture dynamics, Geophys. J. Int., 177(3), 1140-1150, doi:10.1111/j.1365-246X.2009.04117.x.
  13. Graves, R.W., Pitarka, A. (2010) Broadband ground-motion simulation using a hybrid approach Bulletin of the Seismological Society of America (October 2010), 100(5A):2095-2123, doi:10.1785/0120100057
  14. Graves, R. W., B. T. Aagaard, and K. W. Hudnut (2010). The ShakeOut Earthquake source and ground motion simulations, Earthquake Spectra, in press.
  15. Graves, R., T. Jordan; S. Callaghan; E. Deelman; E. Field; G. Juve; C. Kesselman; P. Maechling; G. Mehta; K. Milner; D. Okaya; P. Small; and K. Vahi (2010). CyberShake: A Physics-Based Seismic Hazard Model for Southern California, Pure Applied Geophys., May 2010
  16. Harris, R. A., Barall, M., Archuleta, R., Dunham, E., Aagaard, B., Ampuero, J. P., Bhat, H., Cruz-Atienza, V., Dalguer, L., Dawson, P., Day, S., Duan, B., Ely, G., Kaneko, Y., Kase, Y., Lapusta, N., Liu, Y., Ma, S., Oglesby, D., Olsen, K., Pitarka, A., Song, S., Templeton, E. (2009) The SCEC/USGS Dynamic Earthquake Rupture Code Verification Exercise, Seismological Research Letters Vol. 80, p. 119-126
  17. Juve, G., Deelman, E., Vahi, K., Mehta, G. (2010) Experiences with Resource Provisioning for Scientific Workflows Using Corral, Scientific Programming, 18:2, pp. 77-92, April 2010
  18. Juve, G., Ewa Deelman, E., Vahi, K., Mehta, g., Berriman, B., Berman, B. P., Maechling, P. (2010), Data Sharing Options for Scientific Workflows on Amazon EC2, 22nd IEEE/ACM Conference on Supercomputing (SC10), New Orleans, Louisiana, November 2010
  19. Juve, G., Ewa Deelman, E., Vahi, K., Mehta, g., Berriman, B., Berman, B. P., Maechling, P. (2010): Scientific Workflow Applications on Amazon EC2 CoRR abs/1005.2718: (2010)
  20. Juve, G., Ewa Deelman, E., Vahi, K., Mehta, g., Berriman, B., Berman, B. P., Maechling, P. (2010) Data Sharing Options for Scientific Workflows on Amazon EC2 CoRR abs/1010.4822: (2010)
  21. Lee, K., Cui, Y., Maechling, P., Olsen, K. and Jordan, T., Communication Optimizations of SCEC AWP-Olsen Application for Petascale Computing (accept, Supercomputing 09, Portland, 2009; Lee, K., Cui, Y., Kaiser, T., Maechling, P., Olsen, K. and Jordan, T., IO Optimizations of SCEC AWP-Olsen Application for Petascale Earthquake Computing (both FINALISTS of Best Posters), SC09, Portland, 2009.
  22. Maechling, P., E. Deelman, Y. Cui (2009), Implementing Software Acceptance Tests as Scientific Workflows, Proceedings of the International Conference on Parallel and Distributed Processing Techniques and Applications, July 13-17, 2009, 2 Volumes. CSREA Press 2009, ISBN 1-60132-123-6, pp. 317-323
  23. Mai, P.M., W. Imperatori, and K.B. Olsen (2010). Hybrid broadband ground-motion simulations: combining long-period deterministic synthetics with high-frequency multiple S-to-S back-scattering, Bull. Seis. Soc. Am. 100, 5A, 2124-2142
  24. Mena, B., P.M. Mai, K.B. Olsen, M.D. Purvance, and J.N. Brune (2010). Hybrid broadband ground motion simulation using scattering Green's functions: application to large magnitude events, Bull. Seis. Soc. Am. 100, 5A, 2143-2162
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