PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
Tytuł artykułu

Modeling of rupture using strong motion generation area: a case study of Hualien earthquake (Mw 6.1) occurred on April 18, 2019

Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The strong Hualien earthquake (Mw 6.1) occurred along the suture zone of the Eurasian Plate and the Philippine Sea Plate, which struck the Hualien city in eastern Taiwan on April 18, 2019. The focal mechanism of this earthquake shows that it is caused by a rupture within a thrust. In the present study, the rupture plane responsible for this earthquake has been modeled using the modified semi-empirical technique (MSET). The whole rupture plane is assumed to be composed of strong motion generation areas (SMGAs) along which the slip occurs with large velocities. The spatiotemporal distribution of aftershocks of this earthquake within identified rupture plane suggests that there are two SMGAs within the rupture plane. The source displacement spectra (SDS) obtained from the observed records have been used to compute the source parameters of these two SMGAs. The MSET efficiently simulates strong ground motion (SGM) at the rock site. The shallow subsurface shear wave velocity profile at various stations has been used as an input to SHAKE91 algorithm for converting records at the surface to that at the rock site. The simulated records are compared with the observed records based on root-mean-square error (RMSE) in peak ground acceleration (PGA) of horizontal components. Various parameters of the rupture plane have been selected using an iterative forward modeling scheme. The accelerograms have been simulated for all the stations that lie within an epicentral distance ranging from 5 to 100 km using the final rupture plane parameters. The comparison of observed and synthetic records validates the effectiveness of the simulation technique and suggests that the Hualien earthquake consists of two SMGAs responsible for high-frequency SGM.
Czasopismo
Rocznik
Strony
1--28
Opis fizyczny
Bibliogr. 62 poz.
Twórcy
  • Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee, India
autor
  • Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee, India
autor
  • Department of Geophysics, Institute of Science, Banaras Hindu University, Varanasi, India
autor
  • National Center for Research on Earthquake Engineering, Taipei, Taiwan
  • Department of Earth Sciences, National Central University, Taoyuan City, Taiwan
  • Department of Earth Sciences, National Central University, Taoyuan City, Taiwan
  • Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee, India
  • Department of Earthquake Engineering, Indian Institute of Technology Roorkee, Roorkee, India
autor
  • Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee, India
autor
  • Department of Earth Sciences, Indian Institute of Technology Roorkee, Roorkee, India
Bibliografia
  • 1. Aki K (1967) Scaling law of seismic spectrum. J Geophys Res 72(4):1217–1231
  • 2. Aki K, Richards PG (2002) University Science Books. Sausalito, California.
  • 3. Atkinson GM, Boore DM (1995) Ground-motion relations for eastern North America. Bull Seismol Soc Am 85(1):17–30
  • 4. Boore DM (1983) Stochastic simulation of high-frequency ground motions based on seismological models of the radiated spectra. Bull Seismol Soc Am 73(6A):1865–1894
  • 5. Brune JN (1970) Tectonic stress and the spectra of seismic shear waves from earthquakes. J Geophys Res 75(26):4997–5009
  • 6. Chin SJ, Lin JY, Chen YF, Wu WN, Liang CW (2016) Transition of the Taiwan-Ryukyu collision-subduction process as revealed by ocean-bottom seismometer observations. J Asian Earth Sci 128:149–157
  • 7. Erdik M, Durukal E (2004) Strong ground motion. In: Recent advances in earthquake geotechnical engineering and microzonation (pp. 67–100). Springer, Dordrecht.
  • 8. Frankel A (1991) High-frequency spectral falloff of earthquakes, fractal dimension of complex rupture, b value, and the scaling of strength on faults. J Geophys Res: Solid Earth 96(B4):6291–6302
  • 9. Hanks TC, McGuire RK (1981) The character of high-frequency strong ground motion. Bull Seismol Soc Am 71(6):2071–2095
  • 10. Hartzell SH (1978) Earthquake aftershocks as Green's functions. Geophys Res Lett 5(1):1–4
  • 11. Idriss IM, Sun JI (1992) SHAKE91: A computer program for conducting equivalent linear seismic response analyses of horizontally layered soil deposits. Center for Geotechnical Modeling, Department of Civil and Environmental Engineering, University of California, Davis, CA
  • 12. Irikura K (1983) Semi-empirical estimation of strong ground motions during large earthquakes. Bull Dis Prevent Res Institute 33(2):63–104
  • 13. Irikura K (1986) Prediction of strong acceleration motion using empirical Green's function. In: Proc. 7th Japan Earthq. Eng. Symp (Vol. 151, pp. 151–156).
  • 14. Irikura K, Kagawa T, Sekiguchi H (1997) Revision of the empirical Green's function method. In: Program and abstracts of the seismological society of Japan (Vol. 2, No. B25).
  • 15. Irikura K, Kamae K (1994) Estimation of strong ground motion in broad-frequency band based on a seismic source scaling model and an empirical Green's function technique.
  • 16. Joshi A (1997) Modelling of peak ground accelerations for Uttarkashi Earthquake of 20th October, 1991. Bull Indian Soc Earthquake Technol 34(2):75–96
  • 17. Joshi A, Patel RC (1997) Modelling of active lineaments for predicting a possible earthquake scenario around Dehradun, Garhwal Himalaya. India Tectonophys 283(1–4):289–310
  • 18. Joshi A, Kumar B, Sinvhal A, Sinvhal H (1999) Generation of synthetic accelerograms by modelling of rupture plane. ISET J Earthq Technol 36(1):43–60
  • 19. Joshi A (2001) Strong motion envelope modelling of the source of the Chamoli earthquake of March 28, 1999 in the Garhwal Himalaya. India J Seismol 5(4):499–518
  • 20. Joshi A, Singh S, Giroti K (2001) The simulation of ground motions using envelope summations. Pure Appl Geophys 158(5):877–901
  • 21. Joshi A (2004) A simplified technique for simulating wide-band strong ground motion for two recent Himalayan earthquakes. Pure Appl Geophys 161(8):1777–1805
  • 22. Joshi A, Midorikawa S (2004) A simplified method for simulation of strong ground motion using finite rupture model of the earthquake source. J Seismolog 8(4):467–484
  • 23. Joshi A, Mohan K (2010) Expected peak ground acceleration in Uttarakhand Himalaya, India region from a deterministic hazard model. Nat Hazards 52(2):299–317
  • 24. Joshi A, Kumari P, Sharma ML, Ghosh AK, Agarwal MK, Ravikiran A (2012a) A strong motion model of the 2004 great Sumatra earthquake: simulation using a modified semi empirical method. J Earthquake and Tsunami 6(04):1250023
  • 25. Joshi A, Kumari P, Singh S, Sharma ML (2012b) Near-field and far-field simulation of accelerograms of Sikkim earthquake of September 18, 2011 using modified semi-empirical approach. Nat Hazards 64(2):1029–1054
  • 26. Joshi A, Sandeep K (2014) Modeling of strong motion generation areas of the 2011 Tohoku, Japan earthquake using modified semi empirical technique. Nat Hazards 71:587–609
  • 27. Joshi A, Kuo CH, Dhibar P, Sharma ML, Wen KL, Lin CM (2015) Simulation of the records of the 27 March 2013 Nantou Taiwan earthquake using modified semi-empirical approach. Nat Hazards 78(2):995–1020
  • 28. Joyner WB, Boore DM (1986) On simulating large earthquakes by Green's function addition of smaller earthquakes. Earthquake Source Mech 37:269–274
  • 29. Kanai K (1951) Relation between the nature of surface layer and the amplitude of earthquake motions. Bull Earthquake Res Institute.
  • 30. Kanamori H (1979) A semi-empirical approach to prediction of long-period ground motions from great earthquakes. Bull Seismol Soc Am 69(6):1645–1670
  • 31. Kanamori H, Anderson DL (1975) Theoretical basis of some empirical relations in seismology. Bull Seismol Soc Am 65(5):1073–1095
  • 32. Kumar D, Khattri KN (2002) A study of observed peak ground accelerations and prediction of accelerograms of 1999 Chamoli earthquake. Himalayan Geol 23(1):51–61
  • 33. Kumar D, Khattri KN, Teotia SS, Rai SS (1999) Modelling of accelerograms of two Himalayan earthquakes using a novel semi-empirical method and estimation of accelerogram for a hypothetical great earthquake in the Himalaya. Current Science, pp. 819–830.
  • 34. Kuo-chen H, Vu YM, Chang CH, Hu JC, Chen WS (2004) Relocation of eastern Taiwan earthquakes and tectonic implications. Terrestrial Atmospheric and Oceanic Sci 15:647–666
  • 35. Lal S, Joshi A, Tomer M, Kumar P, Kuo CH, Lin CM, Sharma ML (2018) Modeling of the strong ground motion of 25th April 2015 Nepal earthquake using modified semi-empirical technique. Acta Geophys 66(4):461–477
  • 36. Lee SJ, Wong TP, Liu TY, Lin TC, Chen CT (2020) Strong ground motion over a large area in northern Taiwan caused by the northward rupture directivity of the 2019 Hualien earthquake. J Asian Earth Sci 192:104095
  • 37. Li Z, Roecker S, Kim K, Xu Y, Hao T (2014) Moho depth variations in the Taiwan orogen from joint inversion of seismic arrival time and Bouguer gravity data. Tectonophysics 632:151–159
  • 38. Lin PS, Lee CT (2008) Ground-motion attenuation relationships for subduction-zone earthquakes in northeastern Taiwan. Bull Seismol Soc Am 98(1):220–240
  • 39. Lin Y, Yi-Ying W, Yin-Tung Y (2022). Source properties of the 2019 ML6. 3 Hualien, Taiwan, earthquake, determined by the local strong motion networks. Geophysical J Int.
  • 40. Lysmer J, Bolton SH, Schnabel PB (1971) Influence of base-rock characteristics on ground response. Bull Seismol Soc Am 61(5):1213–1231
  • 41. Mendoza C, Hartzell SH (1988) Inversion for slip distribution using teleseismic P waveforms: North Palm Springs, Borah Peak, and Michoacán earthquakes. Bull Seismol Soc Am 78(3):1092–1111
  • 42. Midorikawa S (1989) Synthesis of ground acceleration of large earthquakes using acceleration envelope waveform of small earthquake. J Struct Construct Eng 398:23–30
  • 43. Midorikawa S (1993) Semi-empirical estimation of peak ground acceleration from large earthquakes. Tectonophysics 218(1–3):287–295
  • 44. Mittal H, Benjamin MY, Tai-Lin T, Yih-Min W (2021) Importance of real-time PGV in terms of lead-time and shakemaps: results using 2018 ML 6. 2 & 2019 ML 6. 3 Hualien Taiwan earthquakes. J Asian Earth Sci 220:1049
  • 45. Miyake H, Iwata T, Irikura K (2003) Source characterization for broadband ground-motion simulation: Kinematic heterogeneous source model and strong motion generation area. Bull Seismol Soc Am 93(6):2531–2545
  • 46. Miyahara M, Sasatani T (2004) Estimation of source process of the 1994 Sanriku Haruka-oki earthquake using empirical Green's function method. Geophys Bull Hokkaido Univ Sapporo Japan 67:197–212 (in Japanese with English abstract)
  • 47. Reiter L (1990) Earthquake hazard analysis: issues and insights (Vol. 22, No. 3, p. 254). New York: Columbia University Press.
  • 48. Sandeep, Joshi A, Kamal, Kumar P, Kumar A (2014a) Effect of frequency dependent radiation pattern in simulation of high frequency ground motion of Tohoku earthquake using modified semi empirical method. Nat Hazards, 73: 1499-1521
  • 49. Sandeep, Joshi A, Kamal, Kumar P, Kumari P (2014b) Modeling of strong motion generation area of the Uttarkashi earthquake using modified semi-empirical approach. Nat. Hazards, 73: 2041–2066
  • 50. Sandeep, Joshi A, Sah SK, Kumar P, Lal S, Kamal (2019) Modelling of strong motion generation areas for a great earthquake in central seismic gap region of Himalayas using the modified semi-empirical approach. J Earth Syst Sci
  • 51. Schnabel PB, Lysmer J, Seed HB (1972) SHAKE: a computer program for earthquake response analysis of horizontally layered sites Report No. UCB/EERC-72/12, Earthquake Engineering Research Center, University of California, Berkeley
  • 52. Sharma B, Chopra S, Sutar AK, Bansal BK (2013) Estimation of strong ground motion from a great earthquake Mw 8 5 in central seismic gap region, Himalaya (India) using empirical Green's function technique. Pure and Appl Geophys 170(12):2127–2138
  • 53. Shyu JH, Chen CF, Wu YM (2016) Seismotectonic characteristics of the northernmost Longitudinal Valley, eastern Taiwan: Structural development of a vanishing suture. Tectonophysics 692:295–308
  • 54. Smoczyk GM, Hayes GP, Hamburger MW, Benz HM, Villaseñor AH, Furlong KP (2013) Seismicity of the Earth 1900–2012 Philippine Sea plate and vicinity (No. 2010–1083-M). US Geological Survey.
  • 55. Sokolov V, Kuo-Liang W, Miksat J, Wenzel F, Chen CT (2009) Analysis of Taipei basin response for earthquakes of various depths and locations using empirical data. TAO: Terrestrial, Atmospheric and Oceanic Sci, 20(5), 6.
  • 56. Takiguchi M, Asano K, Iwata T (2011) The comparison of source models of repeating subduction-zone earthquakes estimated using broadband strong motion records. Zisin (Journal of the Seismological Society of Japan. 2nd ser.), 63(4), 223–242.
  • 57. Toro GR, McGuire RK (1987) An investigation into earthquake ground motion characteristics in eastern North America. Bull Seismol Soc Am 77(2):468–489
  • 58. U.S. Geological Survey (2019). Earthquake Lists, Maps, and Statistics, accessed April 18, 2019 at URL https://www.usgs.gov/natural-hazards/earthquake-hazards/lists-maps-and-statistics.
  • 59. Wells DL, Coppersmith KJ (1994) New empirical relationships among magnitude, rupture length, rupture width, rupture area, and surface displacement. Bull Seismol Soc Am 84(4):974–1002
  • 60. Wen YY, Wen S, Lee YH, Ching KE (2019) The kinematic source analysis for 2018 Mw 6.4 Hualien. Taiwan Earthquake Terr Atmos Ocean Sci 30:377–387
  • 61. Wu FT, Liang WT, Lee JC, Benz H, Villasenor A (2009) A model for the termination of the Ryukyu subduction zone against Taiwan: A junction of collision, subduction/separation, and subduction boundaries. J Geophys Res: Solid Earth, 114(B7).
  • 62. Zeng Y, Anderson JG, Yu G (1994) A composite source model for computing realistic synthetic strong ground motions. Geophys Res Lett 21(8):725–728
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-41026334-177e-482a-a4b6-1a9e976f3588
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.