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The Postglacial Rebound Signal of Fennoscandia Observed by Absolute Gravimetry, GPS, and Tide Gauges

DOI: 10.1155/2011/957329

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Abstract:

We have compiled time derivatives of gravity and vertical motion for a dozen sites in Fennoscandia. Time series of absolute gravimetry and permanent GPS cover a time span of about a decade. Tide gauges have operated for many decades near seven of the sites. Linear relations are found to range from ?0.17 to ?0.22 for the slope between gravity and vertical uplift rates. An eustatic sea level rate of 1.2?mm/year is derived from these data. This compares well with results for North America and with theoretical predictions for viscoelastic Earth models. 1. Introduction The postglacial movements of Fennoscandia have been monitored geometrically by terrestrial as well as space geodetic observing techniques. Vertical uplift rates relative to mean sea level have been derived to map the apparent uplift (e.g., [1]). Time series of permanent GPS-stations reveal both vertical and horizontal movements [2, 3]. The geographical distribution of vertical uplift rates from these two independent sets of observations reveals an oval shaped uplift area with the major axis oriented towards northeast and maximum uplift in the northern part of the Gulf of Bothnia. The western perimeter of the uplift oval indicates a zero uplift line at or just outside the western coastline of Norway. Investigations of gravity changes related to the postglacial uplift of Fennoscandia began in 1966 with relative gravimeters. Longitudinal land uplift gravity lines between 56°N and 65°N were established under the auspices of the Nordic Geodetic Commission. Observations are being collected episodically [1, 4]. Several campaigns with absolute gravimeters were organized between 1976 and 1998. This effort became annual in 2003. We have compiled GPS uplift rates for a dozen sites in Fennoscandia for which time series of absolute gravimetry also exists, spanning about a decade. Seven of these sites are located at the coast with nearby tide gauges having produced times series for the last 50–100 years. 2. Data Gravity was first measured by absolute gravimeters in Fennoscandia in 1976 [5, 6]. The number of observing sites increased in 1993 when two FG5-instruments [7] campaigned Finland, Norway, and Sweden. Episodic follow-up observations were made in 1995 and 1998 [8]. An ongoing observing program was initiated in 2003, employing several recently acquired FG5-instruments on an annual basis at more than three dozen sites throughout the Nordic countries [9]. Currently available data produce time series of absolute gravity observations for about a dozen sites covering a time span of a decade or more. They

References

[1]  M. Ekman and J. M?kinen, “Recent postglacial rebound, gravity change and mantle flow in Fennoscandia,” Geophysical Journal International, vol. 126, no. 1, pp. 229–234, 1996.
[2]  G. A. Milne, J. L. Davis, J. X. Mitrovica et al., “Space-geodetic constraints on glacial isostatic adjustment in Fennoscandia,” Science, vol. 291, no. 5512, pp. 2381–2385, 2001.
[3]  H.-G. Scherneck, J. M. Johansson, H. Koivula, T. van Dam, and J. L. Davis, “Vertical crustal motion observed in the BIFROST project,” Journal of Geodynamics, vol. 35, no. 4-5, pp. 425–441, 2003.
[4]  J. M?kinen, A. Engfeldt, B. G. Harsson, et al., “The Fennoscandian land uplift gravity lines 1966–2003,” in Gravity, Geoid and Space Missions, C. Jekeli, L. Bastos, and J. Fernandes, Eds., IAG Symposium 129, pp. 328–332, Springer, Berlin, Germany, 2005.
[5]  L. Cannizzo, G. Cerutti, and I. Marson, “Absolute-gravity measurements in Europe,” Il Nuovo Cimento C, vol. 1, no. 1, pp. 39–85, 1978.
[6]  J. M?kinen, M. Bilker-Koivula, F. Klopping, R. Falk, L. Timmen, and O. Gitlein, “Time series of absolute gravity in Finland,” in Proceedings of the 1st International Symposium of the International Gravity Field Service, Istanbul, Turkey, August-September 2006.
[7]  T. M. Niebauer, G. S. Sasagawa, J. E. Faller, R. Hilt, and F. Klopping, “A new generation of absolute gravimeters,” Metrologia, vol. 32, no. 3, pp. 159–180, 1995.
[8]  H. Wilmes, R. Falk, F. Klopping, et al., “Long-term gravity variations in Scandinavia from repeated absolute gravity measurements in the period 1991 to 2003,” in Proceedings of the IAG International Symposium on Gravity, Geoid, and Space Missions (GGSM '04), IAG Symposium 129, 2004, CD.
[9]  L. Timmen, O. Gitlein, J. Müller, et al., “Observing Fennoscandian gravity change by absolute gravimetry,” in Geodetic Deformation Monitoring: From Geophysical to Engineering Roles, IAG Symposium 131, pp. 193–199, Springer, London, UK, 2006.
[10]  A. Engfeldt, L. Timmen, O. Gitlein, et al., “Observing absolute gravity acceleration in the Fennoscandian Land Uplift Area,” in Proceedings of the 1st International Symposium of the International Gravity Field Service, Istanbul, Turkey, August-September 2006.
[11]  K. Kaniuth and S. Vetter, “Vertical velocities of European coastal sites derived from continuous GPS observations,” GPS Solutions, vol. 9, no. 1, pp. 32–40, 2005.
[12]  M. Lidberg, J. M. Johansson, H.-G. Scherneck, and J. L. Davis, “An improved and extended GPS-derived 3D velocity field of the glacial isostatic adjustment (GIA) in Fennoscandia,” Journal of Geodesy, vol. 81, no. 3, pp. 213–230, 2007.
[13]  O. Kristiansen, personal communication, November 2005.
[14]  A. Lambert, N. Courtier, and T. S. James, “Long-term monitoring by absolute gravimetry: tides to postglacial rebound,” Journal of Geodynamics, vol. 41, no. 1–3, pp. 307–317, 2006.
[15]  J. Wahr, D. Han, and A. Trupin, “Predictions of vertical uplift caused by changing polar ice volumes on a viscoelastic earth,” Geophysical Research Letters, vol. 22, no. 8, pp. 977–980, 1995.
[16]  T. S. James and E. R. Ivins, “Predictions of Antarctic crustal motions driven by present-day ice sheet evolution and by isostatic memory of the Last Glacial Maximum,” Journal of Geophysical Research B, vol. 103, no. 3, pp. 4993–5017, 1998.
[17]  M. Fang and B. H. Hager, “Vertical deformation and absolute gravity,” Geophysical Journal International, vol. 146, no. 2, pp. 539–548, 2001.
[18]  C. de Linage, J. Hinderer, and Y. Rogister, “A search for the ratio between gravity variation and vertical displacement due to a surface load,” Geophysical Journal International, vol. 171, no. 3, pp. 986–994, 2007.

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