Earth rotation and geodynamics

• Autorzy: Bogusz J. , Brzezinski A. , Kosek W. , Nastula J.

Identyfikatory

DOI

10.1515/geocart-2015-0013

• Języki publikacji: EN

Abstrakty

EN

This paper presents the summary of research activities carried out in Poland in 2011-2014 in the field of Earth rotation and geodynamics by several Polish research institutions. It contains a summary of works on Earth rotation, including evaluation and prediction of its parameters and analysis of the related excitation data as well as research on associated geodynamic phenomena such as geocentre motion, global sea level change and hydrological processes. The second part of the paper deals with monitoring of geodynamic phenomena. It contains analysis of geodynamic networks of local, and regional scale using space (GNSS and SLR) techniques, Earth tides monitoring with gravimeters and water-tube hydrostatic clinometer, and the determination of secular variation of the Earth’ magnetic field.

Słowa kluczowe

EN

GNSS; SLR; tidal investigations; Earth's magnetic field; Earth rotation

PL

ruch obrotowy Ziemi; pole magnetyczne; pływy morskie

• Wydawca: Komitet Geodezji PAN
• Czasopismo: Geodesy and Cartography
• Rocznik: 2015
• Tom: Vol. 64, no. 2
• Strony: 201--242
• Opis fizyczny: Bibliogr. 77 poz., rys., tab., wykr.

Twórcy

autor

Bogusz J.

• Military University of Technology Faculty of Civil Engineering and Geodesy 2 Gen. S. Kaliskiego St., 00-908 Warsaw, Poland

autor

Brzezinski A.

• Warsaw University of Technology Department of Geodesy and Geodetic Astronomy 1 Pl. Politechniki., 00-661 Warsaw, Poland
• Polish Academy of Sciences Space Research Centre 18A Bartycka St., 00-716 Warsaw, Poland

autor

Kosek W.

• University of Agriculture in Krakow Faculty of Environmental Engineering and Land Surveying 24-28 Al. Mickiewicza, 30-059 Krakow, Poland

autor

Nastula J.

• Polish Academy of Sciences Space Research Centre 18A Bartycka St., 00-716 Warsaw, Poland

Bibliografia

• [1] Alothman, A.O. and Schillak, S. (2014). Recent Results for the Arabian Plate Motion Using Satellite Laser Ranging Observations of Riyadh SLR Station to LAGEOS-1 and LAGEOS-2 Satellites. Arabian Journal For Science and Engineering, Vol. 39, No 1, 217-226, DOI:10.1007/s13369-013-0823-7.
• [2] Baryla, R., Paziewski, J., Wielgosz, P., Stepniak, K., and Krukowska, M. (2014). Accuracy assessment of the ground deformation monitoring with the use of GPS local network: open pit mine Koźmin case study. Acta Geodynamica et Geomaterialia, Vol. 11, No 4 (176), DOI:10.13168/AGG.2014.0013.
• [3] Birylo, M. and Nastula, J. (2012a). GRACE Signal Filtering as a Means of Determining Equivalent Water Thickness in Poland. Papers on Global Change, National IGBP-Global Change Committee PAS, Vol. 19, pp. 33-42.
• [4] Birylo, M. and Nastula, J. (2012b). Local Equivalent Water Thickness Determination as a Source of Data For Flood Phenomenon Observation. Papers on Global Change, National IGBP - Global Change Committee PAS, Vol. 19, pp. 43-52.
• [5] Birylo, M. and Nastula, J. (2012c). GRACE Satellites usage for hydrological models determinations, Monography of University of Warmia and Mazury in Olsztyn, 4th PhD Seminar on Geodesy and Cartography, Olsztyn, Poland 9-10 June 2011, pp. 27-34.
• [6] Blachowski, J., Ellefmo, S. and Ludvigsen, E. (2011). Monitoring system for observations of rock mass deformations caused by sublevel caving mining system, Acta Geodynamica et Geomaterialia, Vol. 8, No 3(163), 335-344.
• [7] Blachowski, J. and Ellefmo, S. (2012). Numerical modelling of rock mass deformation in sublevel caving mining system. Acta Geodynamica et Geomaterialia, Vol. 9, No 3(167), 379-388.
• [8] Blachowski, J. and Milczarek, W. (2014). Analysis of surface changes in the Walbrzych hard coal mining grounds (SW Poland) between 1886 and 2009. Geological Quarterly, Vol. 58, No 2, 353-367, DOI:10.7306/gq.1162.
• [9] Blachowski, J., Milczarek, W. and Stefaniak, P. (2014). Deformation information system for facilitating studies of mining-ground deformations, development, and applications. Natural Hazards And Earth System Sciences, Vol. 14, No 7, 1677-1689, DOI:10.5194/nhess-14-1677-2014.
• [10] Bogusz, J., Jarosiński, M. and Wnuk, K. (2011). Regional 2.5D model of deformations in Central Europe from GNSS observations: general assumptions of project. Reports on Geodesy, No 2 (91), 59-66.
• [11] Bogusz, J. and Figurski, M. (2012). Problem of intraplate velocity determination for geokinematic interpretations. Reports on Geodesy, Vol. 93, No 2, 25-33.
• [12] Bogusz, J., Figurski, M., Kontny, B. and Grzempowski, P. (2012a). Horizontal velocity field derived from EPN and ASG-EUPOS satellite data on the example of south-western part of Poland. Acta Geodynamica et Geomaterialia, Vol. 9, No 3(167), 349-357.
• [13] Bogusz, J., Figurski, M., Kontny, B. and Grzempowski, P. (2012b). Unmodeled effects in the horizontal velocity fields: ASG-EUPOS case study. Artificial Satellites, Vol. 47, No 2, 67-79, DOI:10.2478/ v10018-012-0014-x.
• [14] Bogusz, J., Kłos, A., Figurski, M., Jarosinski, M. and Kontny, B. (2013a). Investigation of the reliability of local strain analysis by the triangle modelling. Acta Geodynamica et Geomaterialia, Vol. 10, No 3(171), 293-305, DOI:10.13168/AGG.2013.0029.
• [15] Bogusz, J., Klos, A., Grzempowski, P. and Kontny, B. (2013b). Modelling velocity field in regular grid on the area of Poland on the basis of the velocities of European permanent stations. Pure and Applied Geophysics, Vol. 171, No 6(2014), 809-833, DOI:10.1007/s00024-013-0645-2.
• [16] Bogusz, J., Figursk,i M., Klos, A. and Araszkiewicz, A. (2014a). The use of locally weighted scatterplot smoothing in the analyses of GPS time series autocorrelations. Proceedings of the 14th International Multidisciplinary Scientific GeoConference (SGEM 2014). ISSN 1314-2704, ISBN 978-619-7105-11-7, pp. 591-598, DOI:10.5593/sgem2014B22.
• [17] Bogusz, J., Figurski, M., Klos, A. and Araszkiewicz, A. (2014b). The goodness of fit of linear regression model in the determination of permanent stations’ velocity. Proceedings of the 14th International Multidisciplinary Scientific GeoConference (SGEM 2014). ISSN 1314-2704, ISBN 978-619-7105-11-7, pp. 513-520, DOI:10.5593/sgem2014B22.
• [18] Böhm, S., Brzezinski, A. and Schuh, H. (2012). Complex demodulation in VLBI estimation of high frequency Earth rotation components. Journal of Geodynamics, 62, 56-68, DOI: 10.1016/j.jog.2011.10.002.
• [19] Brzezinski, A. (2011): Diurnal excitation of Earth rotation estimated from recent geophysical models. Proc. Journées 2010 “Systèmes de référence spatio-temporels”, (ed.) N. Capitaine, Observatoire de Paris, pp. 131-136.
• [20] Brzezinski, A. (2012). On estimation of the high frequency geophysical signals in Earth rotation by complex demodulation, Journal of Geodynamics, 62, 74-82, DOI:10.1016/j.jog.2012.01.008.
• [21] Brzezinski, A., Dobslaw, H., Dill, R. and Thomas, M. (2011). Geophysical excitation of the Chandler wobble revisited, Proc. IAG 2009 Scientific Assembly “Geodesy for Planet Earth”. S. Kenyon et al. (eds.), IAG Symposia Series Vol. 136, Springer-Verlag Berlin Heidelberg, pp. 497-503, DOI 10.1007/978-3-642-20338-1_60.
• [22] Brzezinski, A. and Böhm, S. (2012). Analysis of the high frequency components of Earth rotation demodulated from VLBI data, Proc. Journées 2011 “Systèmes de référence spatio-temporels”. (eds.) H. Schuh, S. Böhm, T. Nilsson, and N. Capitaine, Observatoire de Paris, pp. 132-135.
• [23] Brzezinski, A. and Rajner, M. (2014). Estimation of the Chandler wobble parameters by the use of the Kalman deconvolution filter. Proc. Journées 2013 “Systèmes de référence spatio-temporels”, (ed.) N. Capitaine, Observatoire de Paris, pp.189-192.
• [24] Brzezinski, A., Dobslaw, H. and Thomas, M. (2014).Atmospheric and Oceanic Excitation of the Free Core Nutation Estimated from Recent Geophysical Models. Proc. IAG 2011 Scientific Assembly “Earth on the Edge: Science for a Sustainable Planet”, C. Rizos and P. Willis (eds.), IAG Symposia Vol. 139, pp. 461-466, DOI:10.1007/978-3-642-37222-3 61, Springer-Verlag Berlin Heidelberg 2014.
• [25] Cacon, S., Kostak, B. and Makolski, K. (2012). Geodynamic effects detected in the Stolowe Góry mountains investigated originally for gravitational mass movements. Acta Geodynamica et Geomaterialia, Vol. 9, No 4(168), 457-472.
• [26] Cmielewski, K., Kuchmister, J., Goluch, P. and Kowalski, K. (2012). The use of optoelectronic techniques in studies of relative displacements of rock mass. Acta Geodynamica et Geomaterialia, Vol. 9, No 3(167), 409-418.
• [27] Dykowski, P. (2012). Calibration of Relative Spring Gravimeters with the Use of the A10 Absolute Gravimeter, Symposium Gravity. Geoid and Height Systems GGHS2012, Venice, Italy, 9-12 October 2012.
• [28] Dykowski, P. and Sekowski, M. (2014). Tidal investigations at Borowa Gora Geodetic-Geophysical Observatory. EGU General Assembly 2014, held 27 April - 2 May, 2014 in Vienna, Austria, EGU2014-14048.
• [29] Grzempowski, P., Badura, J., Cacon, S., Kaplon, J., Rohm, W. and Przybylski, B. (2012). Geodynamics of south-eastern part of the Central European subsidence zone. Acta Geodynamica et Geomaterialia, Vol. 9, No 3(167), 359-369.
• [30] Kaczorowski, M. (2013). Unrecognized origin signals disturbing water-tubes tiltmeters measurements in geodynamic laboratory of SRC in Ksiaz. Acta Geodynamica et Geomaterialia, Vol. 10, No 3(171), 323-333, DOI:10.13168/AGG.2013.0031.
• [31] Kaczorowski, M. and Wojewoda, J. (2011). Neotectonic activity interpreted from a long water-tube tiltmeter record at the SRC Geodynamic Laboratory in Ksiaz Central Sudetes, SW Poland. Acta Geodynamica et Geomaterialia, Vol. 8, No 3(163), 249-261.
• [32] Kaplon, J., Kontny, B. Grzempowski, P., Schenk, V., Schenkova, Z., Balek, J. and Holesovsky, J. (2014). Geosud/Sudeten network GPS data reprocessing and horizontal site velocity estimation. Acta Geodynamica et Geomaterialia, Vol. 11, No 1(173), 65-75, DOI:10.13168/AGG.2013.0058.
• [33] Kasza, D., Kaczorowski, M., Zdunek, R. and Wronowski, R. (2014). The damages of Ksiaz castle architecture in relation to routes of recognized tectonic faults and indications of recent tectonic activity of Swiebodzice depression orogen - central Sudetes, SW Poland. Acta Geodynamica et Geomaterialia, Vol. 11, No 3(174), 225-234, DOI:10.13168/AGG.2014.0011.
• [34] Kolaczek, B., Pasnicka, M. and Nastula, J. (2012). Analysis of the geodetic residuals as differences between geodetic and sum of the atmospheric and oceanic excitation of polar motion. Proc. Journées 2011 “Systèmes de référence spatio-temporels”, (eds.) H. Schuh, S. Böhm, T. Nilsson, and N. Capitaine, Observatoire de Paris, pp. 164-165.
• [35] Kontny, B. and Bogusz, J. (2012). Models of vertical movements of the Earth crust surface in the area of Poland derived from leveling and GNSS data. Acta Geodynamica et Geomaterialia, Vol. 9, No 3(167), 331-337.
• [36] Kosek, W. (2012). Future improvements in EOP prediction, Proc. IAG 2009 Scientific Assembly “Geodesy for Planet Earth”. S. Kenyon et al. (eds.), IAG Symposia Series Vol. 136, Springer-Verlag Berlin Heidelberg, pp. 513-520, DOI:10.1007/978-3-642-20338-1_62.
• [37] Kosek, W., Popinski, W. and Niedzielski, T. (2011a). Wavelet based comparison of high frequency oscillations in the geodetic and fluid excitation functions of polar motion, Proc. Journées 2010 “Systèmes de référence spatio-temporels”, (ed.) N. Capitaine, Observatoire de Paris, pp. 168-171.
• [38] Kosek, W., Luzum, B., Kalarus, M., Wnek, A. and Zbylut, M. (2011b). Analysis of Pole Coordinate Data Predictions in the Earth Orientation Parameters Combination of Prediction Pilot Project. Artificial Satellites, 46, No 4/2011, DOI:10.2478/v10018-012-0006-x, pp. 139-150.
• [39] Kosek, W., Niedzielski, T., Popinski, W., Zbylut, M. and Wnek, A. (2013). Variable seasonal and subseasonal oscillations in sea level anomaly data and their impact on prediction accuracy, IAG Symposium Series Vol. 142, proceedings of the VIII Hotine Marussi Symposium..
• [40] Kosek, W., Wnek, A., Zbylut, M. and Popinski, W. (2014). Wavelet analysis of the Earth centre of mass time series determined by satellite techniques. Journal of Geodynamics, 80, 58-65, DOI: 10.1016/j. jog.2014.02.005.
• [41] Kowalczyk, K., Bednarczyk, M. and Kowalczyk, A. (2011). Relational database of four precise levelling campaigns in Poland. 8th International Conference Environmental Engineering, Vilnius, LITHUANIA, (eds.) D. Cygas; K.D. Froehner, Environmental Engineering, Vol. 1-3, pp. 1356-1361.
• [42] Kowalczyk, K. and Rapinski, J. (2012). Adjustment of vertical crustal movement network on the basis of last three leveling campaigns in Poland. Reports on Geodesy, Vol. 92, No 1, 123-134.
• [43] Kowalczyk, K. and Rapinski, J. (2013). Evaluation of levelling data for use in vertical crustal movements model in Poland. Acta Geodynamica et Geomaterialia, Vol. 10, No 4(172), 401-410, DOI:10.13168/ AGG.2013.0039.
• [44] Kowalczyk, K., Bogusz, J. and Figurski, M. (2014a). The analysis of the selected data from Polish Active Geodetic Network stations with the view on creating a model of vertical crustal movements. The 9th International Conference “Environmental Engineering”, Section: Technologies of Geodesy and Cadastre, 22-23 May 2014, Vilnius, Lithuania, eISSN 2029-7092 / eISBN 978-609-457-640-9, DOI:10.3846/enviro.2014.221.
• [45] Kowalczyk, K., Bogusz, J. and Figurski, M. (2014b). On the possibility of using GNSS data to model the vertical crustal movements. Proceedings of the 14th International Multidisciplinary Scientific GeoConference (SGEM 2014), ISSN 1314-2704, ISBN 978-619-7105-11-7, pp. 567-574, DOI:10.5593/sgem2014B22.
• [46] Krynski, J. and Zanimonskiy, Y.M. (2012). Search for geodynamic signals in time series of astrometric observations. Reports on Geodesy,Vol. 92, No 1, 87-102.
• [47] Kuchmister, J., Cmielewski, K. and Goluch, P. (2014). The application of the optoelectronic technique of transferring heights from the recessed benchmarks in networks in the examination of rock mass deformation. Acta Geodynamica et Geomaterialia, Vol. 11, No 1(173), pp. 23-33, DOI:10.13168/ AGG.2013.0052.
• [48] Lejba, P. and Schillak, S. (2011). Determination of station positions and velocities from laser ranging observations to Ajisai, Starlette and Stella satellites. Advances in Space Research, Vol. 47, No 4, 654-662, DOI:10.1016/j.asr.2010.10.013.
• [49] Nastula, J. (2014). Gravimetric excitation function of polar motion from the GRACE RL05 solution, Proc. Journées 2013 “Systèmes de référence spatio-temporels”. (ed.) N. Capitaine, Observatoire de Paris, pp. 208-211.
• [50] Nastula, J., Pasnicka, M. and Kolaczek, B. (2011a). Comparison of the geophysical excitations of polar motion from the period: 1980.0 - 2009.0, Acta Geophysica, 59(3), 561-577.
• [51] Nastula, J., Pasnicka, M., Kolaczek, B. and Salstein, D.A. (2011b). Comparison of the hydrological excitation functions HAM of polar motion for the period 1980.0-2007.0. Proc. Journées 2010 “Systèmes de référence spatio-temporels”, (ed.) N. Capitaine, Observatoire de Paris, pp. 164-167.
• [52] Nastula J. and Salstein D.A. (2012): Regional Geophysical Excitation Functions of Polar Motion over Land Area, Proc. IAG 2009 Scientific Assembly “Geodesy for Planet Earth”, S. Kenyon et al. (eds.), IAG Symposia Series Vol. 136, Springer-Verlag Berlin Heidelberg, 486-492, DOI:10.1007/978-3-642-203338-1_59.
• [53] Nastula, J., Gross, R. and Salstein, D.A. (2012). Oceanic excitation of polar motion: Identification of specific oceanic areas important for polar motion excitation. Journal of Geodynamics, DOI:10.1016/j. jog.2012.012.002.
• [54] Nastula, J., Salstein, D.A. and Gross, R. (2014). Regional Multi-Fluid-Based Geophysical Excitation of Polar Motion. Proc. IAG 2011 Scientific Assembly “Earth on the Edge: Science for a Sustainable Planet”, C. Rizos and P. Willis (eds.), IAG Symposia Vol. 139, pp. 467-472.
• [55] Niedzielski, T. (2011a). Is there any teleconnection between surface hydrology in Poland and El Niño/ Southern Oscillation? Pure and Applied Geophysics, 168, 871-886.
• [56] Niedzielski T., (2011b): Modelling and prediction of geospatial time series, In: W. Żyszkowska and W. Spallek (eds.), Główne problemy współczesnej kartografii 2011, Zastosowanie statystyki w GIS i kartografii, Uniwersytet Wrocławski, Wroclaw, pp. 73-82.
• [57] Niedzielski T., (2014): El Niño/Southern Oscillation and selected environmental consequences, Advances in Geophysics, 55, pp. 77-122.
• [58] Niedzielski, T. and Kosek, W. (2011a).Minimum time span of TOPEX/Poseidon, Jason-1 and Jason-2 global altimeter data to detect a significant trend and acceleration in sea level change. Advances in Space Research, 47, 1248-1255.
• [59] Niedzielski, T. and Kosek, W. (2011b). Nonlinear sea level variations in the equatorial pacific due to ENSO, Proc. Journées 2010 “Systèmes de référence spatio-temporels”. (ed.) N. Capitaine, Observatoire de Paris, pp. 217-218.
• [60] Niedzielski, T. and Kosek, W. (2012a). The statistical characteristics of altimetric sea level anomaly time series. Proc. IAG 2009 Scientific Assembly “Geodesy for Planet Earth”, S. Kenyon et al. (eds.), IAG Symposia Series Vol. 136, Springer-Verlag Berlin Heidelberg, 545-550, DOI:10.1007/978-3-642-20338-1_66.
• [61] Niedzielski, T. and Kosek, W. (2012b). Prediction analysis of UT1-UTC time series by combination of the least-squares and multivariate autoregressive method. Proc. VII Hotine-Marussi Symposium on Mathematical Geodesy, N. Sneeuw, P. Novák, M. Crespi, F. Sansò (eds.), IAG Symposia Series Vol. 137, Springer-Verlag Berlin Heidelberg, pp. 153-157, DOI:10.1007/978-3-642-22078-4.
• [62] Niedzielski, T. and Miziński, B. (2013). Automated system for near-real time modelling and prediction of altimeter-derived sea level anomalies. Computers & Geosciences, 58, 29-39.
• [63] Perski, Z. and Mroz, M. (2012). Natural recent earth surface displacements of Sambia Peninsula (Baltic Sea coast) studied with persistent scatterers interferometry. Acta Geodynamica et Geomaterialia, Vol. 9, No 1(165), 19-29.
• [64] Rajner, M. (2012). Earth crust deformation in Poland: modelling and its implication for positioning with satellite based geodetic techniques. Reports on Geodesy, Vol. 92, No 1, 37-46.
• [65] Rajner, M. and Liwosz, T. (2011). Studies of crustal deformation due to hydrological loading on GPS height estimates. Geodesy and Cartography, Vol. 60, No 2, 135-144, DOI:10.2478/v10277-012-0012-y.
• [66] Rajner, M., Olszak, T., Rogowski, J.B. and Walo, J. (2012). The influence of continental water storage on gravity rates estimates: case study using absolute gravity measurements from area of lower Silesia, Poland. Acta Geodynamica et Geomaterialia, Vol. 9, No 4(168), 449-455.
• [67] Rogowski, J.B. and Brzeziński, A. (2012). The celestial reference system and its role in the epoch of global geodetic technologies. Reports on Geodesy, Vol. 92. 163-174.
• [68] Seoane, L., Nastula, J., Bizouard, C. and Gambis, D. (2011). Hydrological excitation of polar motion derived from GRACE gravity field solutions. International Journal of Geophysics, 10, DOI:10.1155/2011/174396.
• [69] Szafranek K., Schillak S., (2012): Introduction to joint analysis of SLR and GNSS data, Reports on Geodesy, Vol. 92, No 1, 139-150.
• [70] Szafranek, K., Bogusz, J., Figurski, M., Sapota, M., Schillak, S. and Nykiel G. (2014). Determination of post-seismic decays from selected GNSS and SLR co-located sites. Proc. 14th International Multidisciplinary Scientific GeoConference (SGEM 2014). ISSN 1314-2704, ISBN 978-619-7105-11-7, pp. 199-206, DOI:10.5593/sgem2014B22.
• [71] Szczerbowski, Z., Banasik, P. and Kudrys, J. (2011). Geological conditions and local changes of vertical deflections. Acta Geodynamica et Geomaterialia, Vol. 8, No 3(163), 263-271.
• [72] Szostak-Chrzanowsk, A. and Chrzanowski, A. (2014). Study of natural and man-induced ground deformation in Mackenzie delta region. Acta Geodynamica et Geomaterialia, Vol. 11, No 2(174), 117-123, DOI:10.13168/AGG.2013.0060.
• [73] Swierczynska, M., Niedzielski, T. and Kosek, W. (2014). Semiannual and annual oscillations of sea level and their impact on asymmetry between El Niño and La Niña episodes. Studia Geophysica et Geodaetica, 58, 302-325.
• [74] Tian, W., Brzezinski, A., Soffel, M.H., Gebauer, A., Schreiber, K.U. and Klügel, T. (2011). The interpretation of high frequency signals in the G-ring laser gyroscope.Proc. Journées 2010 “Systèmes de référence spatio-temporels”, (ed.) N. Capitaine, Observatoire de Paris, pp. 225-226.
• [75] Welker, E. (2011). The influence of variantions of the Earth magnetic field intensity on the elaboration of geomagnetic observations in Poland. Geoinformation Issues, Vol. 3, No 1(3), 19-37.
• [76] Zdunek, R. (2012). Permanent GPS station in Ksiaz Geodynamic Laboratory for supporting investigations of neo-tectonic motions in the Ksiaz massif. Acta Geodynamica et Geomaterialia, Vol. 9, No 3(167), 371-377.
• [77] Zdunek, R., Kaczorowski, M., Kasza, D. and Wronowski, R. (2014). Preliminary interpretation of determined movements of KSIA and KSI1 GPS stations in context of collected information about Swiebodzice trough tectonics. Acta Geodynamica et Geomaterialia, Vol. 11, No 4(176), 305-315, DOI: 10.13168/AGG.2014.0016.