Groundwater level response to the Wenchuan earthquake of May 2008

References

• Akita F, Matsumoto N. 2004. Hydrological responses induced by the Tokachi–Oki earthquake in 2003 at hot spring wells in Hokkaido, Japan. Geophys Res Lett. 31(16):371–375.
   Google Scholar
• Blanchard FB, Byerly P. 1935. A study of a well gauge as a seismograph. Bull Seismol Soc Am. 25(4):313–321.
   Google Scholar
• Bower DR, Heaton KC. 1978. Response of an aquifer near Ottawa to tidal forcing and the Alaskan earthquake of 1964. Can J Earth Sci. 15(3):331–340.
   Google Scholar
• Bredehoeft JD. 1967. Response of well—aquifer systems to Earth tides. J Geophys Res. 72(12):3075–3087.
   Google Scholar
• Brodsky EE, Roeloffs E, Woodcock D, Gall I, Manga M. 2003. A mechanism for sustained groundwater pressure changes induced by distant earthquakes. J Geophys Res. 108(B8):503–518.
   Google Scholar
• Carr PA, Van Der Kamp GS. 1969. Determining aquifer characteristics by the tidal method. Water Resour Res. 5(5):1023–1031.
   Google Scholar
• Chan CH, Wang Y, Almeida R, Yadav RBS. 2017. Enhanced stress and changes to regional seismicity due to the 2015 M w 7.8 Gorkha, Nepal, earthquake on the neighbouring segments of the Main Himalayan thrust. J Asian Earth Sci. 133:46–55.
   Google Scholar
• Chia Y, Wang YS, Chiu JJ, Liu CW. 2001. Changes of groundwater level due to the 1999 Chi-Chi earthquake in the Choshui River alluvial fan in Taiwan. Bull Seismol Soc Am. 91(5):1062–1068.
   Google Scholar
• Cooper HH, Bredehoeft JD, Papadopulos IS, Bennett RR. 1965. The response of well-AQUIFER systems to seismic waves. J Geophys Res. 70(16):3915–3926.
   Google Scholar
• Cox SC, Rutter HK, Sims A, Manga M, Weir JJ, Ezzy T, White PA, Horton TW, Scott D. 2012. Hydrological effects of the Mw 7.1 Darfield (Canterbury) earthquake, 4 September 2010, New Zealand. New Zealand J Geolog Geophys. 55(3):231–247.
   Google Scholar
• Cui XF, Hu XP, Yu CQ, Tao K, Wang Y, Ning J. 2011. Research on focal mechanism solutions of Wenchuan earthquake sequence. Acta Sci. Nat. Univ. Pekinensis. 6:1063–1072.
   Google Scholar
• Dobry R, Ladd RS, Yokel FY, Chung RM, Powell D. 1982. Prediction of pore water pressure buildup and liquefaction of sands during earthquakes by the cyclic strain method (Vol.138). Gaithersburg (MD): National Bureau of Standards.
   Google Scholar
• Elkhoury JE, Brodsky EE, Agnew DC. 2006. Seismic waves increase permeability. Nature. 441(7097):1135.
   Google Scholar
• Ge S, Stover SC. 2000. Hydrodynamic response to strike- and dip-slip faulting in a half-space. J Geophys Res. 105(B11):25513–25524.
   Google Scholar
• Geballe ZM, Wang CY, Manga M. 2011. A permeability-change model for water-level changes triggered by teleseismic waves. Geofluids. 11(3):302–308.
   Google Scholar
• Grecksch G, Roth F, Kümpel HJ. 1999. Coseismic well-level changes due to the 1992 roermond earthquake compared to static deformation of half-space solutions. Geophys J Int. 138(2):470–478.
   Google Scholar
• Gulley AK, Ward NFD, Cox SC, Kaipio JP. 2013. Groundwater responses to the recent Canterbury earthquakes: a comparison. J Hydrol. 504:171–181.
   Google Scholar
• He A, Fan X, Zhao G, Liu Y, Singh RP, Hu Y. 2017a. Co-seismic response of water level in the Jingle well (China) associated with the Gorkha Nepal (Mw 7.8) earthquake. Tectonophysics. 714–715:82–89.
   Google Scholar
• He A, Singh RP, Sun Z, Ye Q, Zhao G. 2016. Comparison of regression methods to compute atmospheric pressure and earth tidal coefficients in water level associated with Wenchuan Earthquake of 12 May 2008. Pure Appl Geophys. 173(7):2277–2294.
   Google Scholar
• He A, Zhao G, Sun Z, Singh RP. 2017b. Co-seismic multilayer water temperature and water level changes associated with Wenchuan and Tohoku-Oki earthquakes in the Chuan no. 03 well, China. J Seismol. 21(4):719–734.
   Google Scholar
• Hsu CC, Vucetic M. 2004. Volumetric threshold shear strain for cyclic settlement. J Geotech Geoenviron Eng. 130(1):58–70.
   Google Scholar
• Itaba S, Koizumi N, Matsumoto N, Takahashi M, Sato T, Ohtani R. 2008. Groundwater level changes related to the ground shaking of the Noto Hanto earthquake in 2007. Earth Planet Space. 60(12):1153–1159.
   Google Scholar
• Jonsson S, Segall P, Pedersen R, Bjornsson G. 2003. Post-earthquake ground movements correlated to pore-pressure transients. Nature. 424(6945):179.
   Google Scholar
• King CY, Azuma S, Igarashi G, Ohno M, Saito H, Wakita H. 1999. Earthquake-related water-level changes at 16 closely clustered wells in Tono, Central Japan. J Geophys Res. 104(B6):13073–13082.
   Google Scholar
• Kitagawa Y, Koizumi N, Takahashi M, Matsumoto N, Sato T. 2006. Changes in groundwater levels or pressures associated with the 2004 earthquake off the west coast of northern Sumatra (M9. 0). Earth Planet Sp. 58(2):173–179.
   Google Scholar
• Koizumi N, Lai W, Kitagawa Y, Matsumoto N. 2004. Comment on “Coseismic hydrological changes associated with dislocation of the September 21, 1999 Chichi earthquake, Taiwan” by Min Lee et al. Geophys Res Lett. 31(13):n/a.
   Google Scholar
• Lai W-C, Koizumi N, Matsumoto N, Kitagawa Y, Lin C-W, Shieh C-L, Lee Y-P. 2004. Effects of seismic ground motion and geological setting on the coseismic groundwater level changes caused by the 1999 Chi-Chi earthquake, Taiwan. Earth Planet Sp. 56(9):873–880.
   Google Scholar
• Lai G, Jiang C, Han L, Sheng S, Ma Y. 2016. Co-seismic water level changes in response to multiple large earthquakes at the LGH well in Sichuan, China. Tectonophysics. 679:211–217.
   Google Scholar
• Lee M, Liu TK, Ma KF, Chang YM. 2002. Coseismic hydrological changes associated with dislocation of the September 21, 1999 Chichi earthquake, Taiwan. Geophys Res Lett. 29(17):5-1–5-4.
   Google Scholar
• Lee M, Liu TK, Ma KF, Chang YM. 2004. Reply to comment by N. Koizumi et al. on “Coseismic hydrological changes associated with dislocation of the September 21, 1999 Chichi earthquake, Taiwan. Geophys Res Lett. 31(13):n/a.
   Google Scholar
• Liu L, Tan G, Luan F, Tang X, Kang P, Tu C, Pei F. 2012. The use of external fixation combined with vacuum sealing drainage to treat open comminuted fractures of Tibia in the Wenchuan earthquake. Int Orthopaedic. 36(7):1441–1447.
   Google Scholar
• Liu LB, Roeloffs E, Zheng XY. 1989. Seismically induced water level fluctuations in the Wali Well, Beijing, China. J Geophys Res. 94(B7):9453–9462.
   Google Scholar
• Ma Y, Huang F. 2017. Coseismic water level changes induced by two distant earthquakes in multiple wells of the Chinese mainland. Tectonophysics. 694:57–68.
   Google Scholar
• Matsumoto N. 1992. Regression analysis for anomalous changes of ground water level due to earthquakes. Geophys Res Lett. 19(12):1193–1196.
   Google Scholar
• Matsumoto N, Kitagawa G, Roeloffs EA. 2003. Hydrological response to earthquakes in the Haibara well, central Japan–I. Groundwater level changes revealed using state space decomposition of atmospheric pressure, rainfall and tidal responses. Geophys J Int. 155(3):885–898.
   Google Scholar
• Merifield PM, Lamar DL. 1984. Possible strain events reflected in water levels in wells along San Jacinto fault zone, Southern California. Pure and Applied Geophysics. 122(2–4):245–254.
   Google Scholar
• Molnar P, Lyon-Caent H. 1989. Fault plane solutions of earthquakes and active tectonics of the tibetan plateau and its margins. Geophys J Int. 99(1):123–153.
   Google Scholar
• Montgomery DR, Manga M. 2003. Streamflow and water well responses to earthquakes. Science. 300(5628):2047–2049.
   Google Scholar
• Nur A, Booker JR. 1972. Aftershocks caused by pore fluid flow? Science. 175(4024):885–887.
   Google Scholar
• Ogawa R, Heki K. 2007. Slow postseismic recovery of geoid depression formed by the 2004 Sumatra – Andaman earthquake by mantle water diffusion. Geophys Res Lett. 34(6):n/a.
   Google Scholar
• Pawlowicz R, Beardsley B, Lentz S. 2002. Classical tidal harmonic analysis including error estimates in MATLAB using T_TIDE. Comput Geosci. 28(8):929–937.
   Google Scholar
• Peltzer G, Rosen P, Rogez F, Hudnut K. 1996. Postseismic rebound in fault step-overs caused by pore fluid flow. Science. 273(5279):1202–1203.
   Google Scholar
• Piombo A, Martinelli G, Dragoni M. 2005. Post-seismic fluid flow and Coulomb stress changes in a poroelastic medium. Geophys J Int. 162(2):507–515.
   Google Scholar
• Quilty EG, Roeloffs EA. 1997. Water-level changes in response to the 20 December 1994 earthquake near Parkfield, California. Bull Seismol Soc Am. 87(2):310–317.
   Google Scholar
• Radhakrishnan N, Patel P, Kulkarni MN. 2010. Post-seismic effect of Sumatra-Andaman earthquake on the western part of Indian plate. IUP J Earth Sci. 4(3):45–55.
   Google Scholar
• Ramana DV, Chadha RK, Singh C, Shekar M. 2007. Water level fluctuations due to earthquakes in Koyna-Warna region, India. Nat Hazards. 40(3):585–592.
   Google Scholar
• Roeloffs E. 1996. Poroelastic techniques in the study of earthquake-related hydrologic phenomena. In: Dmowska R, editor. Advances in geophysics. San Diego (CA): Academic Press; pp. 135–195.
   Google Scholar
• Roeloffs EA. 1998. Persistent water level changes in a well near Parkfield, California, due to local and distant earthquakes. J Geophys Res. 103(B1):869–889.
   Google Scholar
• Roeloffs E, Sneed M, Galloway DL, Sorey ML, Farrar CD, Howle JF, Hughes J. 2003. Water-level changes induced by local and distant earthquakes at long valley Caldera, California. J Volcanol Geothermal Res. 127(3–4):269–303.
   Google Scholar
• Rojstaczer S, Wolf S. 1992. Permeability changes associated with large earthquakes: An example from Loma Prieta, California. Geol. 20(3):211–214.
   Google Scholar
• Shi ZM, Wang GC, Liu CL, Mei JC, Wang JW, Fang HN. 2013. Coseismic response of groundwater level in the three gorges well network and its relationship to aquifer parameters. Chin Sci Bull. 58(25):3080–3087.
   Google Scholar
• Shi Z, Wang G. 2016. Aquifers switched from confined to semiconfined by earthquakes. Geophys Res Lett. 43(21):11,166–11,172. doi: 10.1002/2016GL070937.
   Google Scholar
• Sil S, Freymueller JT. 2006. Well water level changes in Fairbanks, Alaska, due to the great sumatra-andaman earthquake. Earth Planet Sp. 58(2):181–184.
   Google Scholar
• Stein RS, Lisowski M. 1983. The 1979 Homestead Valley earthquake sequence, California: Control of aftershocks and postseismic deformation. J Geophys Res. 88(B8):6477–6490.
   Google Scholar
• Sun X, Wang G, Yang X. 2015. Coseismic response of water level in Changping well, China, to the Mw 9.0 Tohoku earthquake. J Hydrol. 531:1028–1039.
   Google Scholar
• Vucetic M. 1994. Cyclic threshold shear strains in soils. J Geotech Eng. 120(12):2208–2228.
   Google Scholar
• Wakita H. 1975. Water wells as possible indicators of tectonic strain. Science. 189(4202):553–555.
   Google Scholar
• Wallima L. 2007. Fundamentals of geophysics. New York: Cambridge University Press.
   Google Scholar
• Wang CY, Cheng LH, Chin CV, Yu SB. 2001. Coseismic hydrologic response of an alluvial fan to the 1999 Chi-Chi earthquake, Taiwan. Geol. 29(9):831–834.
   Google Scholar
• Wang CY, Chia Y. 2008. Mechanism of water level changes during earthquakes: Near field versus intermediate field. Geophys Res Lett. 35(12):109.
   Google Scholar
• Wang CY, Manga M. 2010. Earthquakes and water. Lecture Notes in Earth Sciences 114, Berlin: Springer-Verlag.
   Google Scholar
• Wang CY, Wang CH, Kuo CH. 2004. Temporal change in groundwater level following the 1999 (Mw =7.5) Chi-Chi earthquake, Taiwan. Geofluids. 4(3):210–220.
   Google Scholar
• Weingarten M, Ge S. 2014. Insights into water level response to seismic waves: A 24 year high-fidelity record of global seismicity at Devils Hole. Geophys Res Lett. 41(1):74–80.
   Google Scholar
• Xu X, Wen X, Yu G, Chen G, Klinger Y, Hubbard J, Shaw J. 2009. Coseismic reverse-and oblique-slip surface faulting generated by the 2008 Mw 7.9 Wenchuan earthquake, China. Geology. 37(6):515–518.
   Google Scholar
• Xue L, Brodsky EE, Erskine J, Fulton PM, Carter R. 2016. A permeability and compliance contrast measured hydrogeologically on the San Andreas fault. Geochem Geophys Geosyst. 17(3):858–871.
   Google Scholar
• Yang ZZ. 2004. Water-level changes induced by earthquakes and a preliminary study of their mechanism [Doctoral dissertation]. Beijing: Institute of Geology, CEA.
   Google Scholar
• Yoshimi Y, Oh-Oka H. 1975. Influence of degree of shear stress reversal on the liquefaction potential of saturated sand. Soil Foundation. 15(3):27–40.
   Google Scholar
• Zhang Y, Fu LY, Huang F, Chen X. 2015. Coseismic water-level changes in a well induced by teleseismic waves from three large earthquakes. Tectonophysics. 651–652:232–241.
   Google Scholar
• Zheng J, Jiang H, He Z. 2012. Analysis of the co-seismic responses of the fluid well pattern system in Jiangsu Province to the Wenchuan and Tohoku earthquakes. Earthq Sci. 25(3):263–274.
   Google Scholar