SciELO - Scientific Electronic Library Online

SciELO - Scientific Electronic Library Online

Referencias del artículo

RUIZ, Francisco et al. Cambios de gravedad de origen tectónico en la transición entre las Sierras Pampeanas Occidentales y la Precordillera Sanjuanina. Rev. Asoc. Geol. Argent. [online]. 2011, vol.68, n.4, pp. 594-605. ISSN 0004-4822.

    1. Anderson, M., Alvarado, P., Zandt, G. y Beck, S. 2007. Geometry and brittle deformation of the subducting Nazca Plate, Central Chile and Argentina. Geophysical Journal international 171: 419-434. [ Links ]

    2. Astini, R.A. 1998. Stratigraphic evidence supporting the rifting, drifting and collision of the Laurentian Precordillera terrane of western Argentina. En Pankhurst, R. y Rapela, C. (eds.) The proto-Andean margin of Gondwana, The Geological Society, Special Publication 142: 11-33, London. [ Links ]

    3. Baldis, B., Martinez, R., Villegas, C., Pereyra, M.Y. y Perez, A. 1990. Estructura Provincialismo geológico y unidades tectonoestratigráficas. 11º Congreso Geológico Argentino, Relatorio: 186-211, San Juan. [ Links ]

    4. Borrello, A.V. 1969. Los geosinclinales de la Argentina. Dirección Nacional de Geología y Minería, Anales 14: 136 p., Buenos Aires. [ Links ]

    5. Cahill, T. y Isacks, B. 1992. Seismicity and shape of the subducted Nazca plate. Journal of Geophysical Research 97: 17503-1752. [ Links ]

    6. Chapman, D.S., Sahm, E. y Gettings, P. 2008. Monitoring aquifer recharge using repeated high-precision gravity measurements: A pilot study in South Weber, Utah. Geophysics 73 (6): WA83-WA93. [ Links ]

    7. Cordell, L., Zorin, Y.A. y Keller, G.R. 1991. The decompensative gravity anomaly and deep structure of the region of the Rio Grande rift. Journal of Geophysical Research 96: 6557- 6568. [ Links ]

    8. Costa, C., Machette, M., Dart, R., Bastias, H., Paredes, J., Perucca, L., Tello, G. y Haller, K. 2000. Map and database of Quaternary faults and folds in Argentina. U.S. Geological Survey Open-File Report 00-0108, 75 p., Virginia. [ Links ]

    9. Chernicoff, C.J., Vujovich, G.I. y Van Staal, C.R. 2009. Geophysical evidence for an extensive Pie de Palo Complex mafic-ultramafic belt, San Juan, Argentina. Journal of South American Earth Sciences 28: 325-332. [ Links ]

    10. Ferguson, J.F., Chen, T., Brady, J., Aiken, C.L.V. y Seibert, J. 2007. The 4D microgravity method for waterflood surveillance II - Gravity measurements for the Prudhoe Bay reservoir, Alaska. Geophysics 72: I33-I43. [ Links ]

    11. Gabalda, G., Bonvalot, S. y Hipkin, R. 2003. CG3TOOL: an interactive computer program to process Scintrex CG-3/3M gravity data for high-resolution Applications. Computers & Geosciences 29: 155-171. [ Links ]

    12. GEOSOFT 2010. Montaj Gravity and Terrain Correction software. Gravity data processing extension for Oasis montaj v7.1. Online catalog (www.geosoft.com). [ Links ]

    13. Hayes, T.J., Tiampo, K.F., Rundle, J.B. y Fernández, J. 2006. Gravity changes from a stress evolution earthquake simulation of California. Journal Geophysical Research 111, B0 9408, doi:10.1029/2005 JB004092. [ Links ]

    14. INPRES (Instituto Nacional de Prevención Sísmica) 2010. Listado de terremotos históricos de Argentina, catálogo en línea (www.inpres.gov.ar). [ Links ]

    15. Introcaso, A. 1997. Gravimetría. Editorial UNR, 350 p., Rosario. [ Links ]

    16. Introcaso, A., Robles, J., Miranda, S., Volponi, F., Sisterna, J., Martínez, P. y Gimenez, M. 1999. Cambios Temporales de g y h sobre la zona sismotectónica de las Sas. Pampeanas de Pie de Palo, de la Huerta y Chepes, Argentina. En Introcaso, A. (ed.) Contribuciones a la Geodesia en la Argentina de fines del siglo 20, Homenaje a Oscar Parachú, UNR Editora, 243- 252, Rosario. [ Links ]

    17. Islam, R. 2009. Cohesive strength and seismogenic stress pattern along the active basement faults of the Precordillera-Sierras Pampeanas ranges, western Argentina: An experimental analysis by means of numerical model. Journal of Mountain Science 6: 331-345. [ Links ]

    18. Jordan, T.E. y Allmendinger, R.W. 1986. The Sierras Pampeanas of Argentina: A modern analogue of rocky mountain foreland deformation. American Journal of Science 286: 737 764. [ Links ]

    19. Kendrick, E., Brooks, B., Bevis, M., Smalley, R., Lauria, E., Araujo, M. y Parra, H. 2006. Active orogeny of the South-Central Andes studied with GPS geodesy. Revista de la Asociación Geológica Argentina 61: 555-566. [ Links ]

    20. Lloret, G. y Suvires, G. 2006. Groundwater basin of the Tulum Valley, San Juan, Argentina: A morphohydrogeologic analysis of its central sector. Journal of South American Earth Sciences 21: 267-275. [ Links ]

    21. Luna, E. 2010. interpretación geofísica de la corteza en la Precordillera Oriental sanjuanina, a partir de datos magnéticos, gravimétricos y neotectónicos. Tesis de Licenciatura, Universidad Nacional de San Juan (inédita), 109 p., San Juan. [ Links ]

    22. Meigs, A., Krugh, W.C., Schiffman, C., Vergés, J. y Ramos, V.A. 2006. Refolding of thin-skinned thrust sheets by active basement involved thrust faults in the eastern Precordillera of western Argentina. Revista de la Asociación Geológica Argentina 61: 589-603. [ Links ]

    23. Miranda, S., Herrada, A. y Sisterna, J. 2006. Una propuesta para el monitoreo de la movilidad cortical actual en la Sierra Chica de Zonda (Precordillera Oriental de San Juan): mediciones de gravedad en red. Revista de la Asociación Geológica Argentina 61: 444-448. [ Links ]

    24. Nabighian, M. 1972. The analytic signal of twodimensional magnetic bodies with polygonal cross-sections: its properties and use for automated anomaly interpretation. Geophysics 37: 507-517. [ Links ]

    25. Nabighian M.N., Grauch, V.J.S., Hansen, R.O., LaFehr, T.R., Li, Y., Peirce, J.W., Phillips, J.D. y Ruder, M.E. 2005. The historical development of the magnetic method in exploration. Geophysics 70: 33-61. [ Links ]

    26. Naipauer, M., Vujovich, G.I., Cingolani, C.A. y McClelland, W.C. 2010. Detrital zircon analysis from the Neoproterozoic-Cambrian sedimentary cover (Cuyania terrane), Sierra de Pie de Palo, Argentina: Evidence of a rift and passive margin system? Journal of South American Earth Sciences 29: 306-326. [ Links ]

    27. Paredes, J. y Perucca, L. 2000. Fallamiento cuaternario en la depresión de Matagusanos, San Juan, Argentina. Revista de la Asociación Geológica Argentina 55: 23-30. [ Links ]

    28. Parker, R. L. 1972. The rapid calculation of potential anomalies. Geophysical Journal of the Royal Astronomical Society 42: 315-334. [ Links ]

    29. Perucca, L.P., Pérez, A.M., Moreiras, S.M. y Bracco, A. 2008. Análisis del campo de esfuerzos en una secuencia lacustre de Precordillera Oriental, San Juan. Revista de la Asociación Geológica Argentina 63: 223-232. [ Links ]

    30. Phillips, J.D. 2007. Geosoft executables (GX's). Developed by the U.S. Geological Survey, Version 2.0, with Notes on GX Development from Fortran Code. Open File Report 2007- 1355, 111 p., Virginia. [ Links ]

    31. Pool, D.R. 2008. The utility of gravity and waterlevel monitoring at alluvial aquifer wells in southern Arizona. Geophysics 73 (6): WA49- WA59. [ Links ]

    32. Ramos, V.A. 2004. Cuyania, an exotic block to Gondwana: Review of a historical success and the present problems. Journal Gondwana Research 7 (4): 1-18. [ Links ]

    33. Ramos, V.A., Cegarra, M. y Cristallini, E. 1996. Cenozoic tectonics of the High Andes of west-central Argentina (30º-36° latitude). Tectonophysics 259: 185-200. [ Links ]

    34. Ramos, V.A., Cristallini, E.O. y Pérez, D.J. 2002. The Pampean flatslab of the central Andes. Journal of South American Earth Sciences 15: 59-78. [ Links ]

    35. Roest W.E., Verhoef, J. y Pilkington, M. 1992. Magnetic interpretation using the 3-D analytic signal. Geophysics 57(1): 116-125. [ Links ]

    36. Ruiz, F., e Introcaso, A. 2004. Curie point depths beneath Precordillera Cuyana and Sierras Pampeanas obtained from spectral analysis of magnetic anomalies. Journal Gondwana Research 8: 1133-1142. [ Links ]

    37. Ruiz, F. e Introcaso, A. 2011. Study of the Claromecó Basin from gravity, magnetic and geoid undulations. Boletín del instituto de Fisiografía y Geología 79-81: 95-106. [ Links ]

    38. Ruiz, F., Laplagne, A., Gallego G. e Introcaso, A. 2008. Variaciones de gravedad en el Valle de Tulum, San Juan: aportes a la caracterización sismotectónica. GEOACTA 33: 115-122, Bahía Blanca. [ Links ]

    39. Ruiz, F., Gimenez, M., Introcaso, A., Martinez, P., Cornaglia, L., Leiva, F. y Sisterna, J. 2009. Cambios periódicos de gravedad vinculados con tectónica activa en la Precordillera Oriental, San Juan, Argentina. 11th International Congress of the Brazilian Geophysical Society, Actas 1761_EVT_6YEAR_2009: 4 p., Salvador. [ Links ]

    40. Ruiz, F., Luna, E., Vargas, D., Gimenez, M. y Martinez, P. 2011. Importancia del ajuste y nivelación de datos aeromagnéticos a partir de magnetometría terrestre. 18º Congreso Geológico Argentino, Actas: 1198-1199, Neuquén. [ Links ]

    41. Rundle, J.B. 1982. Viscoelastic-Gravitational Deformation by a Rectangular Thrust Fault in a Layered Earth, Journal Geophysical Research 87(B9): 7787-7796. [ Links ]

    42. Sambridge, M., Braun, J. y McQueen, H. 1995. Geophysical parameterization and interpolation of irregular data using natural neighbours. Geophysical Journal international 122: 837-857. [ Links ]

    43. SEGEMAR 1999. Intensidad de campo magnético total: grilla de datos aeromagnéticos digitales, Bloque II Precordillera Sur 17 (San Juan - Mendoza). Servicio Geológico Minero Argentino, Buenos Aires. [ Links ]

    44. SEGEMAR 2000. Carta Geológica de la República Argentina. Hoja (3169-IV) San Juan, escala 1:250.000. Servicio Geológico Minero Argentino, Buenos Aires. [ Links ]

    45. SEGEMAR 2001. Intensidad de campo magnético total: grilla de datos aeromagnéticos digitales, área Pie de Palo 26 (San Juan). Servicio Geológico Minero Argentino, Buenos Aires. [ Links ]

    46. Sun, W. y Okubo, S. 1993. Surface potential and gravity changes due to internal dislocations in a spherical earth I. Theory for a point dislocation. Geophysical Journal international 114: 569-592. [ Links ]

    47. Tanaka, Y., Okuno, J. y Okubo, S. 2006. A new method for the computation of global viscoelastic post-seismic deformation in a realistic earth model (I) vertical displacement and gravity variation. Geophysical Journal international 164: 273-289. [ Links ]

    48. Ukawa, M., Nozaki, K., Ueda, H. y Fujita, E. 2010. Calibration shifts in Scintrex CG-3M gravitmeters with an application to detection of microgravity changes at iwo-tou caldera, Japan. Geophysical Prospecting 58: 1123-1132. [ Links ]

    49. Vergés, J., Ramos, V.A., Meigs, A., Cristallini, E., Bettini, F.H. y Cortés, J.M. 2007. Crustal wedging triggering recent deformation in the Andean thrust front between 31ºS and 33ºS: Sierras Pampeanas-Precordillera interaction. Journal Geophysical Research 112, B03S15, doi: 10.1029/2006JB004287. [ Links ]

    50. Vigny, C., Rudloff, A., Ruegg, J., Madariaga, R., Campos, J. y Alvarez, M. 2009. Upper plate deformation measured by GPS in the Coquimbo gap, Chile. Physics of the Earth and Planetary interiors 175(1-2): 86-95. [ Links ]

    51. Volponi, F.S., Sisterna, J. y Robles, J.A. 1982. Orogenia, fuerzas gravitacionales y fuerzas tectónicas. 5º Congreso Latinoamericano de Geología, Actas 3: 719-730, Buenos Aires. [ Links ]

    52. Walsh J. y Rice, J. 1979. Local changes in gravity resulting from deformation. Journal Geophysical Research 84(B1): 165-170. [ Links ]

    53. Zambrano, J.J. 1986. Actualización geológica del valle de Tulum en la provincia de San Juan. Centro Regional de Aguas Subterráneas T 1 (inédito), 198 p., San Juan. [ Links ]

    54. Zambrano, J.J. y Suvires, G.M. 2008. Actualización en el límite entre sierras Pampeanas Occidentales y Precordillera Oriental, en la provincia de San Juan. Revista de la Asociación Geológica Argentina 63: 110-116. [ Links ]

    55. Zhu, Y., Li, H., Zhu, G. y Xu, Y. 2004. Gravity evolution and earthquake activities of the northeastern edge of Qinghai-Xizang block. Acta Seismologica Sinica 17: 76-84. [ Links ]