Investigation of the interrelationship between changes and redistribution of angular momentum of the earth, the antarctic tectonic plate, the atmosphere, and the ocean

Третяк, К.; Аль-Алусі, Ф. К. Ф.; Бабій, Л.; Tretyak, K.; Al-Alusi, F. K. F.; Babiy, L.; Аль-Алуси, Ф. К. Ф.; Бабий, Л.

Investigation of the interrelationship between changes and redistribution of angular momentum of the earth, the antarctic tectonic plate, the atmosphere, and the ocean

dc.citation.epage	26
dc.citation.issue	1 (24)
dc.citation.journalTitle	Геодинаміка : науковий журнал
dc.citation.spage	5
dc.contributor.affiliation	Національний університет “Львівська політехніка”
dc.contributor.affiliation	Lviv Polytechnic National University
dc.contributor.affiliation	Национальный университет “Львовская политехника”
dc.contributor.author	Третяк, К.
dc.contributor.author	Аль-Алусі, Ф. К. Ф.
dc.contributor.author	Бабій, Л.
dc.contributor.author	Tretyak, K.
dc.contributor.author	Al-Alusi, F. K. F.
dc.contributor.author	Babiy, L.
dc.contributor.author	Третяк, К.
dc.contributor.author	Аль-Алуси, Ф. К. Ф.
dc.contributor.author	Бабий, Л.
dc.coverage.placename	Львів
dc.date.accessioned	2019-05-21T11:10:49Z
dc.date.available	2019-05-21T11:10:49Z
dc.date.created	2018-02-26
dc.date.issued	2018-02-26
dc.description.abstract	Мета. Метою цієї роботи є опрацювання результатів довготривалих ГНСС-спостережень на перманентних станціях, розташованих на території Антарктичної тектонічної плити; визначення зміни її ротаційних параметрів та моменту імпульсу, обчислення зміни моменту імпульсу Землі , океанічних та атмосферних мас і встановлення взаємозв’язку між цими параметрами. Методика. У роботі представлено удосконалений алгоритм визначення параметрів полюсу Ейлера і кутової швидкості обертання тектонічної плити з урахуванням безперервності та нерівномірності часових серій щоденних розв’язків просторового розташування перманентних ГНСС-станцій. Результати. За результатами щоденних розв’язків 28 перманентних ГНСС-станцій Антарктиди за період (1996–2014 рр.) визначено положення середнього полюсу Ейлера, кутової швидкості обертання плити та їхні щорічні зміни. Визначено щорічні параметри тензора інерції та моменту імпульсу Антарктичної тектонічної плити. Обчислено за даними служби обертання Землі та геофізичних спостережень щорічні зміни моменту імпульсу Землі та тензори моменту інерції та величини моменту імпульсу океанічних та атмосферних мас за період (1996–2014 р.). Наукова новизна. Встановлено, що практично протягом усього періоду спостережень збільшенню моменту імпульсу Антарктичної тектонічної плити відповідає зменшення моменту імпульсу Землі та атмосфери, що свідчить про збереження моменту імпульсу. Збільшенню моменту імпульсу Антарктичної тектонічної плити відповідає збільшення моменту імпульсу океану. Пояснення цього взаємозв’язку вимагає додаткових досліджень.
dc.description.abstract	Purpose. The purpose of this work is elaboration of the results of long-term GNSS-observations at permanent stations located on the Antarctic tectonic plate; the determination of the change in its rotational parameters and angular momentum, the calculation of the angular momentum of the Earth, the oceanic and atmospheric masses, and the establishment of the interrelationship between these parameters. Methods. The work represents an improved algorithm for determining the parameters of the Euler pole and the angular velocity of the tectonic plate, taking into account the continuity and unevenness of time series of daily solutions of the spatial location of permanent GNSS-stations. Results. According to the results of daily solutions of 28 permanent GNSS-stations in Antarctica for the period (1996–2014), the average position of Euler pole, the angular velocity of the plate, and their annual changes are determined. The annual parameters of the tensor of inertia and angular momentum of the Antarctic tectonic plate are determined. Using the data of the Earth’s rotation service and geophysical observations, the annual changes in the angular momentum of the Earth, the tensors of moment of inertia, and angular momentum of oceanic and atmospheric masses for the period (1996–2014) have been calculated. Scientific novelty. It is established that during the whole observation period the increase of the angular momentum of the Antarctic tectonic plate corresponds to the decrease of the angular momentum of the Earth and the atmosphere. This indicates the conservation of angular momentum. The increases of the angular momentum of Antarctic tectonic plate corresponds to the increases of the angular momentum of the ocean. Explanation of this interrelationship requires additional research.
dc.description.abstract	Цель. Целью данной работы является обработка результатов длительных ГНСС-наблюдений на перманентных станциях, расположенных на территории Антарктической тектонической плиты; определения изменения ее ротационных параметров и момента импульса, вычисления изменения момента импульса Земли, океанических и атмосферных масс и установление взаимосвязи между этими параметрами. Методика. В работе представлены усовершенствованный алгоритм определения параметров полюса Эйлера и угловой скорости вращения тектонической плиты с учетом непрерывности и неравномерности временных серий ежедневных решений пространственного расположения перманентных ГНСС-станций. Результаты. По результатам ежедневных решений 28 перманентных ГНСС-станций Антарктиды за период (1996–2014 гг.), определено положение среднего полюса Эйлера и угловой скорости вращения плиты и их ежегодные изменения. Определены ежегодные параметры тензора инерции и момента импульса Антарктической тектонической плиты. Вычислено по данным службы вращения Земли и геофизических наблюдений ежегодные изменения момента импульса Земли и тензоры момента инерции и величины момента импульса океанических и атмосферных масс за период (1996–2014 гг.). Научная новизна. Установлено, что практически в течение всего периода наблюдений увеличению момента импульса Антарктической тектонической плиты соответствует уменьшение момента импульса Земли и атмосферы, это свидетельствует о сохранении момента импульса. Увеличению момента импульса Антарктической тектонической плиты соответствует увеличение момента импульса океана. Объяснение этого взаимосвязи требует дополнительных исследований.
dc.format.extent	5-26
dc.format.pages	22
dc.identifier.citation	Tretyak K. Investigation of the interrelationship between changes and redistribution of angular momentum of the earth, the antarctic tectonic plate, the atmosphere, and the ocean / K. Tretyak, F. K. F. Al-Alusi, L. Babiy // Геодинаміка : науковий журнал. — Львів : Видавництво Львівської політехніки, 2018. — № 1 (24). — С. 5–26.
dc.identifier.citationen	Tretyak K. Investigation of the interrelationship between changes and redistribution of angular momentum of the earth, the antarctic tectonic plate, the atmosphere, and the ocean / K. Tretyak, F. K. F. Al-Alusi, L. Babiy // Heodynamika : naukovyi zhurnal. — Lviv : Vydavnytstvo Lvivskoi politekhniky, 2018. — No 1 (24). — P. 5–26.
dc.identifier.uri	https://ena.lpnu.ua/handle/ntb/44998
dc.language.iso	en
dc.publisher	Видавництво Львівської політехніки
dc.relation.ispartof	Геодинаміка : науковий журнал, 1 (24), 2018
dc.relation.references	Altamimi, Z., Métivier, L., & Collilieux, X. (2012).
dc.relation.references	ITRF2008 plate motion model. Journal of
dc.relation.references	Geophysical Research: Solid Earth, 117(B7).doi:10.1029/2011jb008930
dc.relation.references	Argus, D. F., & Gordon, R. G. (1991). Nо-
dc.relation.references	o‐net‐rotation model of current plate velocities incorporating
dc.relation.references	plate motion model NUVEL‐1.
dc.relation.references	Geophysical research letters, 18(11), 2039–2042.
dc.relation.references	Argus, D. F., Gordon, R. G., & Demets, C. (2011).
dc.relation.references	Geologically current motion of 56 plates relative
dc.relation.references	to the no-net-rotation reference frame.
dc.relation.references	Geochemistry, Geophysics, Geosystems, 12(11).doi:10.1029/2011gc003751
dc.relation.references	Baranov, A., & Morelli, A. (2013, April). The Moho
dc.relation.references	depth and the inner crustal structure of the
dc.relation.references	Antarctica region. In EGU General Assembly
dc.relation.references	Conference Abstracts (Vol. 15).
dc.relation.references	Bowin, C. (2010). Plate tectonics conserves angular
dc.relation.references	momentum. EEarth, 5(1), 1–20. doi:10.5194/ee-5-12010
dc.relation.references	Brosche, P., & Sündermann, J. (1985). The Antarctic
dc.relation.references	Circumpolar Current and its influence on the
dc.relation.references	Earth’s rotation. Deutsche Hydrografische
dc.relation.references	Zeitschrift, 38(1), 1–6.
dc.relation.references	Brosche, P., Wünsch, J., Frische, A., Sündermann, J.,& Maier-Reimer, E. (1990). The seasonal
dc.relation.references	variation of the angular momentum of the
dc.relation.references	oceans. Naturwissenschaften, 77(4), 185–186.
dc.relation.references	Brosche, P., Wünsch, J., Maier-Reimer, E.,
dc.relation.references	Segschneider, J., & Sündermann, J. (1997). The
dc.relation.references	axial angular momentum of the general circulation
dc.relation.references	of the oceans. Astronomische Nachrichten, 318(3),193–199.
dc.relation.references	Bryan, F. O. (1997). The axial angular momentum
dc.relation.references	balance of a global ocean general circulation
dc.relation.references	model. Dynamics of atmospheres and
dc.relation.references	oceans, 25(3), 191–216.
dc.relation.references	Sottili, G., Palladino, D. M., Cuffaro, M., & Doglioni,
dc.relation.references	C. (2015). Earth’s rotation variability triggers
dc.relation.references	explosive eruptions in subduction zones. Earth,
dc.relation.references	Planets and Space, 67(1), 208.
dc.relation.references	Celaya, M. A., Wahr, J. M., & Bryan, F. O. (1999).
dc.relation.references	Climatе-driven polar motion. Journal of
dc.relation.references	Geophysical Research: Solid Earth, 104(B6),12813–12829.
dc.relation.references	Chen, J. L., Wilson, C. R., Chao, B. F., Shum, C. K.,
dc.relation.references	& Tapley, B. D. (2000). Hydrological and oceanic
dc.relation.references	excitations to polar motion andlength-of-day
dc.relation.references	variation. Geophysical Journal International,141(1), 149–156.
dc.relation.references	Dickey, J. O., Marcus, S. L., Johns, C. M., Hide, R.,
dc.relation.references	& Thompson, S. R. (1993). The oceanic
dc.relation.references	contribution to the Earth’s seasonal angular
dc.relation.references	momentum budget. Geophysical research
dc.relation.references	letters, 20(24), 2953–2956.
dc.relation.references	Dickman, S. R. (1998). Determination of oceanic
dc.relation.references	dynamic barometer corrections to atmospheric
dc.relation.references	excitation of Earth rotation. Journal of
dc.relation.references	Geophysical Research: Solid Earth, 103(B7),15127–15143.
dc.relation.references	Dietrich, R., & Rülke, A. (2008). A precise reference
dc.relation.references	frame for Antarctica from SCAR GPS campaign
dc.relation.references	data and some geophysical implications.
dc.relation.references	In Geodetic and Geophysical Observations in
dc.relation.references	Antarctica (pp. 1-10). Springer, Berlin,
dc.relation.references	Heidelberg.
dc.relation.references	Dietrich, R., Dach, R., Engelhardt, G., Ihde, J., Korth,
dc.relation.references	W., Kutterer, H. J., ... & Müller, C. (2001). ITRF
dc.relation.references	coordinates and plate velocities from repeated
dc.relation.references	GPS campaigns in Antarctica–an analysis based
dc.relation.references	on different individual solutions. Journal of
dc.relation.references	Geodesy, 74(11–12), 756–766.
dc.relation.references	Dietrich, R., Rülke, A., Ihde, J., Lindner, K., Miller,
dc.relation.references	H., Niemeier, W., ... & Seeber, G. (2004). Plate
dc.relation.references	kinematics and deformation status of the Antarctic
dc.relation.references	Peninsula based on GPS. Global and Planetary
dc.relation.references	Change, 42(1-4), 313–321.
dc.relation.references	Drewes, H. (2009). The actual plate kinematic and
dc.relation.references	crustal deformation model APKIM2005 as basis
dc.relation.references	for a non-rotating ITRF. In Geodetic Reference
dc.relation.references	Frames (pp. 95–99). Springer, Berlin, Heidelberg.DOI:10.1007/978-3-642-00860-3_15, 2009.
dc.relation.references	Drewes, H., & Angermann, D. (2001). The actual
dc.relation.references	plate kinematic and crustal deformation model 2000 (APKIM 2000) as a geodetic reference
dc.relation.references	system. In IAG 2001 Scientific Assembly,
dc.relation.references	Budapest, Hungary.
dc.relation.references	Drewes, H. (1998). Combination of VLBI, SLR and
dc.relation.references	GPS determined station velocities for actual plate
dc.relation.references	kinematic and crustal deformation models.
dc.relation.references	In Geodesy on the Move (pp. 377–382). Springer,
dc.relation.references	Berlin, Heidelberg.
dc.relation.references	Eubanks, T. M. (1993). Interactions between the
dc.relation.references	atmosphere, oceans and crust: Possible oceanic
dc.relation.references	signals in Earth rotation. Advances in Space
dc.relation.references	Research, 13(11), 291–300.
dc.relation.references	Frische, A., & Sündermann, J. (1990). The seasonal
dc.relation.references	angular momentum of the thermohaline ocean
dc.relation.references	circulation. In Earth’s Rotation From Eons to
dc.relation.references	Days (pp. 108–126). Springer, Berlin, Heidelberg.
dc.relation.references	Furuya, M., & Hamano, Y. (1998). Effect of the
dc.relation.references	Pacific Ocean on the Earth’s seasonal wobble
dc.relation.references	inferred from National Center for Environmental
dc.relation.references	Prediction ocean analysis data. Journal of
dc.relation.references	Geophysical Research: Solid Earth, 103(B5),10131–10140.
dc.relation.references	Fylatj'ev V. P. (2007). The influence of rotational
dc.relation.references	effects on the tectonics of the planet (on the
dc.relation.references	example of the transition zone from the Asian
dc.relation.references	continent to the Pacific Ocean). Rotational
dc.relation.references	processes in Geology and Physics. Moscow., 341–360 (in Russian).
dc.relation.references	Khain, V. E., & A. I. Poletayev. (2007). Rotation
dc.relation.references	tectonics of the Earth. Science in Russia, (6), 14–21 (in Russian).
dc.relation.references	National Geophysical Data Center. (2006, July 26).
dc.relation.references	ETOPO5 Data and Documentation \| ngdc.noaa.gov. Retrieved from https://www.ngdc.noaa.gov/mgg/global/etopo5.HTML
dc.relation.references	Pandul, Y. (2017). Geodetic astronomy applied to the
dc.relation.references	solution of engineering and geodesic problems.
dc.relation.references	Litres.
dc.relation.references	Project Overview. (n.d.). Retrieved from http://ggosatm.hg.tuwien.ac.at/
dc.relation.references	Sottili, G., Palladino, D. M., Cuffaro, M., & Doglioni,
dc.relation.references	C. (2015). Earth’s rotation variability triggers
dc.relation.references	explosive eruptions in subduction zones. Earth,
dc.relation.references	Planets and Space, 67(1), 208. https://doi.org/10.1186/s40623-015-0375-z
dc.relation.references	Seitz, F., & Schmidt, M. (2005). Atmospheric and
dc.relation.references	oceanic contributions to Chandler wobble
dc.relation.references	excitation determined by wavelet
dc.relation.references	filtering. Journal of Geophysical Research: Solid
dc.relation.references	Earth,110(B11). doi:10.1029/2005jb003826
dc.relation.references	Navigation and service. (n.d.). Retrieved fromhttps://www.iers.org/IERS/EN/Home/home_node.html
dc.relation.references	Johnson, T. J., Wilson, C. R., & Chao, B. F. (1999).
dc.relation.references	Oceanic angular momentum variability estimated
dc.relation.references	from the Parallel Ocean Climate Model, 1988–1998. Journal of Geophysical Research: SolidEarth,104(B11), 25183-25195.doi:10.1029/1999jb900231
dc.relation.references	Khain, V. E. (2010). Constructing a truly global
dc.relation.references	model of Earth’s dynamics: basic principles.
dc.relation.references	Russian Geology and Geophysics, 51(6), 587–591.
dc.relation.references	Tretjak K. R., Alj-Alusi F. K. F. About relationship of
dc.relation.references	uneven of the Earth rotational movement and
dc.relation.references	Antarctic tectonic plate. Ukrainian Antarctic
dc.relation.references	Journal, (14), 43–57 (in Ukrainian).
dc.relation.references	Tretyak, K., Forat, A., & Holubinka, Y. (2017).
dc.relation.references	Investigation of Changes of the Kinematic
dc.relation.references	Parameters of Antarctic Tectonic Plate Using Data
dc.relation.references	Observations of Permanent GNSS Stations.
dc.relation.references	Reports on Geodesy and Geoinformatics, 103(1).doi:10.1515/rgg-2017-0010
dc.relation.references	Kane, M. F. (1972). Rotational Inerfia of Continents:
dc.relation.references	A Proposed Link between Polar Wandering and
dc.relation.references	Plate Tectonics. Science, 175(4028), 1355–1357.doi:10.1126/science.175.4028.1355
dc.relation.references	Nastula, J., & Ponte, R. M. (1999). Further evidence
dc.relation.references	for oceanic excitation of polar motion.
dc.relation.references	Geophysical Journal International, 139(1), 123–130. doi:10.1046/j.1365-246x.1999.00930.x
dc.relation.references	Link to our Data Products Page:. (n.d.). Retrievedfrom http://geodesy.unr.edu/
dc.relation.references	Ponte, R. M., & Gutzler, D. S. (1991). The Madden-
dc.relation.references	Julian oscillation and the angular momentum
dc.relation.references	balance in a barotropic ocean model. Journal of
dc.relation.references	Geophysical Research: Oceans, 96(C1), 835–842.doi:10.1029/90jc02277
dc.relation.references	Ponte, R. M., & Stammer, D. (2000). Global and
dc.relation.references	regional axial ocean angular momentum signals and
dc.relation.references	length-of-day variations (1985–1996). Journal of
dc.relation.references	Geophysical Research: Oceans, 105(C7), 17161–17171. doi:10.1029/1999jc000157
dc.relation.references	Ponte, R. M., & Stammer, D. (1999). Role of ocean
dc.relation.references	currents and bottom pressure variability on
dc.relation.references	seasonal polar motion. Journal of Geophysical
dc.relation.references	Research: Oceans, 104(C10), 23393–23409.doi:10.1029/1999jc900222
dc.relation.references	Ponte, R. M., & Rosen, R. D. (1994). Oceanic angular
dc.relation.references	momentum and torques in a general circulation
dc.relation.references	model. Journal of physical oceanography, 24(9),1966–1977.
dc.relation.references	Ponte, R. M. (1990). Barotropic motions and the
dc.relation.references	exchange of angular momentum between the oceans
dc.relation.references	and solid Earth. Journal of Geophysical Research,95(C7), 11369. doi:10.1029/jc095ic07p11369
dc.relation.references	Ponte, R. M., Stammer, D., & Marshall, J. (1998).
dc.relation.references	Oceanic signals in observed motions of the Earths
dc.relation.references	pole of rotation. Nature, 391(6666), 476–479.doi:10.1038/35126.
dc.relation.references	Ponte, R. M. (1997). Oceanic excitation of daily to
dc.relation.references	seasonal signals in Earth rotation: Results from a
dc.relation.references	constant-density numerical model. Geophysical
dc.relation.references	Journal International, 130(2), 469–474.doi:10.1111/j.1365-246x.1997.tb05662.x
dc.relation.references	Schettino, A. (1999). Computational methods for
dc.relation.references	calculating geometric parameters of tectonic
dc.relation.references	plates. Computers & Geosciences, 25(8), 897–907. doi:10.1016/s0098-3004(99)00054-0
dc.relation.references	Scripps Orbit and Permanent Array Center (SOPAC).
dc.relation.references	(n.d.). Retrieved from http://sopac.ucsd.edu/
dc.relation.references	Sella, G. F., Dixon, T. H., & Mao, A. (2002).
dc.relation.references	REVEL: A model for Recent plate velocities from
dc.relation.references	space geodesy. Journal of Geophysical Research:
dc.relation.references	Solid Earth, 107(B4). doi:10.1029/2000jb000033
dc.relation.references	Jin, S., & Zhu, W. (2004). A revision of the
dc.relation.references	parameters of the NNR-NUVEL-1A plate velocity
dc.relation.references	model. Journal of Geodynamics, 38(1), 85–92.doi:10.1016/j.jog.2004.03.004
dc.relation.references	Tretyak, K. R., & Vovk, A. I. (2016). Differentation
dc.relation.references	of the rotational movements of the european
dc.relation.references	continents Earth crust. Acta Geodynamica et
dc.relation.references	Geomaterialia, 13(1), 181.
dc.relation.references	Vikulin, А. (2015). Geodynamics as wave dynamics
dc.relation.references	of the medium composed of rotating
dc.relation.references	blocks. Geodynamics & Tectono-physics, 6(3),345–364. doi:10.5800/gt-2015-6-3-0185
dc.relation.references	Vikulin, A. V., Makhmudov, Kh. F., Ivanchin, A. G.,
dc.relation.references	Gerus, A. I., & Dolgaya, A. A. (2016). On the
dc.relation.references	wave and reid properties of the Earth’s crust. Solid
dc.relation.references	State Physics, 58 (3), 547–557.
dc.relation.references	Jiang, W., E, D., Zhan, B., & Liu, Y. (2009). New
dc.relation.references	Model of Antarctic Plate Motion and Its
dc.relation.references	Analysis. Chinese Journal of Geophysics, 52(1),23-32. i:10.1002 /cjg2. 1323
dc.relation.references	Wu, X., Ray, J., & Dam, T. V. (2012). Geocenter
dc.relation.references	motion and its geodetic and geophysicalimplications. Journal of Geodynamics, 58, 44–61.doi:10.1016/j.jog.2012.01.007
dc.relation.referencesen	Altamimi, Z., Métivier, L., & Collilieux, X. (2012).
dc.relation.referencesen	ITRF2008 plate motion model. Journal of
dc.relation.referencesen	Geophysical Research: Solid Earth, 117(B7).doi:10.1029/2011jb008930
dc.relation.referencesen	Argus, D. F., & Gordon, R. G. (1991). No-
dc.relation.referencesen	o‐net‐rotation model of current plate velocities incorporating
dc.relation.referencesen	plate motion model NUVEL‐1.
dc.relation.referencesen	Geophysical research letters, 18(11), 2039–2042.
dc.relation.referencesen	Argus, D. F., Gordon, R. G., & Demets, C. (2011).
dc.relation.referencesen	Geologically current motion of 56 plates relative
dc.relation.referencesen	to the no-net-rotation reference frame.
dc.relation.referencesen	Geochemistry, Geophysics, Geosystems, 12(11).doi:10.1029/2011gc003751
dc.relation.referencesen	Baranov, A., & Morelli, A. (2013, April). The Moho
dc.relation.referencesen	depth and the inner crustal structure of the
dc.relation.referencesen	Antarctica region. In EGU General Assembly
dc.relation.referencesen	Conference Abstracts (Vol. 15).
dc.relation.referencesen	Bowin, C. (2010). Plate tectonics conserves angular
dc.relation.referencesen	momentum. EEarth, 5(1), 1–20. doi:10.5194/ee-5-12010
dc.relation.referencesen	Brosche, P., & Sündermann, J. (1985). The Antarctic
dc.relation.referencesen	Circumpolar Current and its influence on the
dc.relation.referencesen	Earth’s rotation. Deutsche Hydrografische
dc.relation.referencesen	Zeitschrift, 38(1), 1–6.
dc.relation.referencesen	Brosche, P., Wünsch, J., Frische, A., Sündermann, J.,& Maier-Reimer, E. (1990). The seasonal
dc.relation.referencesen	variation of the angular momentum of the
dc.relation.referencesen	oceans. Naturwissenschaften, 77(4), 185–186.
dc.relation.referencesen	Brosche, P., Wünsch, J., Maier-Reimer, E.,
dc.relation.referencesen	Segschneider, J., & Sündermann, J. (1997). The
dc.relation.referencesen	axial angular momentum of the general circulation
dc.relation.referencesen	of the oceans. Astronomische Nachrichten, 318(3),193–199.
dc.relation.referencesen	Bryan, F. O. (1997). The axial angular momentum
dc.relation.referencesen	balance of a global ocean general circulation
dc.relation.referencesen	model. Dynamics of atmospheres and
dc.relation.referencesen	oceans, 25(3), 191–216.
dc.relation.referencesen	Sottili, G., Palladino, D. M., Cuffaro, M., & Doglioni,
dc.relation.referencesen	C. (2015). Earth’s rotation variability triggers
dc.relation.referencesen	explosive eruptions in subduction zones. Earth,
dc.relation.referencesen	Planets and Space, 67(1), 208.
dc.relation.referencesen	Celaya, M. A., Wahr, J. M., & Bryan, F. O. (1999).
dc.relation.referencesen	Climate-driven polar motion. Journal of
dc.relation.referencesen	Geophysical Research: Solid Earth, 104(B6),12813–12829.
dc.relation.referencesen	Chen, J. L., Wilson, C. R., Chao, B. F., Shum, C. K.,
dc.relation.referencesen	& Tapley, B. D. (2000). Hydrological and oceanic
dc.relation.referencesen	excitations to polar motion andlength-of-day
dc.relation.referencesen	variation. Geophysical Journal International,141(1), 149–156.
dc.relation.referencesen	Dickey, J. O., Marcus, S. L., Johns, C. M., Hide, R.,
dc.relation.referencesen	& Thompson, S. R. (1993). The oceanic
dc.relation.referencesen	contribution to the Earth’s seasonal angular
dc.relation.referencesen	momentum budget. Geophysical research
dc.relation.referencesen	letters, 20(24), 2953–2956.
dc.relation.referencesen	Dickman, S. R. (1998). Determination of oceanic
dc.relation.referencesen	dynamic barometer corrections to atmospheric
dc.relation.referencesen	excitation of Earth rotation. Journal of
dc.relation.referencesen	Geophysical Research: Solid Earth, 103(B7),15127–15143.
dc.relation.referencesen	Dietrich, R., & Rülke, A. (2008). A precise reference
dc.relation.referencesen	frame for Antarctica from SCAR GPS campaign
dc.relation.referencesen	data and some geophysical implications.
dc.relation.referencesen	In Geodetic and Geophysical Observations in
dc.relation.referencesen	Antarctica (pp. 1-10). Springer, Berlin,
dc.relation.referencesen	Heidelberg.
dc.relation.referencesen	Dietrich, R., Dach, R., Engelhardt, G., Ihde, J., Korth,
dc.relation.referencesen	W., Kutterer, H. J., ... & Müller, C. (2001). ITRF
dc.relation.referencesen	coordinates and plate velocities from repeated
dc.relation.referencesen	GPS campaigns in Antarctica–an analysis based
dc.relation.referencesen	on different individual solutions. Journal of
dc.relation.referencesen	Geodesy, 74(11–12), 756–766.
dc.relation.referencesen	Dietrich, R., Rülke, A., Ihde, J., Lindner, K., Miller,
dc.relation.referencesen	H., Niemeier, W., ... & Seeber, G. (2004). Plate
dc.relation.referencesen	kinematics and deformation status of the Antarctic
dc.relation.referencesen	Peninsula based on GPS. Global and Planetary
dc.relation.referencesen	Change, 42(1-4), 313–321.
dc.relation.referencesen	Drewes, H. (2009). The actual plate kinematic and
dc.relation.referencesen	crustal deformation model APKIM2005 as basis
dc.relation.referencesen	for a non-rotating ITRF. In Geodetic Reference
dc.relation.referencesen	Frames (pp. 95–99). Springer, Berlin, Heidelberg.DOI:10.1007/978-3-642-00860-3_15, 2009.
dc.relation.referencesen	Drewes, H., & Angermann, D. (2001). The actual
dc.relation.referencesen	plate kinematic and crustal deformation model 2000 (APKIM 2000) as a geodetic reference
dc.relation.referencesen	system. In IAG 2001 Scientific Assembly,
dc.relation.referencesen	Budapest, Hungary.
dc.relation.referencesen	Drewes, H. (1998). Combination of VLBI, SLR and
dc.relation.referencesen	GPS determined station velocities for actual plate
dc.relation.referencesen	kinematic and crustal deformation models.
dc.relation.referencesen	In Geodesy on the Move (pp. 377–382). Springer,
dc.relation.referencesen	Berlin, Heidelberg.
dc.relation.referencesen	Eubanks, T. M. (1993). Interactions between the
dc.relation.referencesen	atmosphere, oceans and crust: Possible oceanic
dc.relation.referencesen	signals in Earth rotation. Advances in Space
dc.relation.referencesen	Research, 13(11), 291–300.
dc.relation.referencesen	Frische, A., & Sündermann, J. (1990). The seasonal
dc.relation.referencesen	angular momentum of the thermohaline ocean
dc.relation.referencesen	circulation. In Earth’s Rotation From Eons to
dc.relation.referencesen	Days (pp. 108–126). Springer, Berlin, Heidelberg.
dc.relation.referencesen	Furuya, M., & Hamano, Y. (1998). Effect of the
dc.relation.referencesen	Pacific Ocean on the Earth’s seasonal wobble
dc.relation.referencesen	inferred from National Center for Environmental
dc.relation.referencesen	Prediction ocean analysis data. Journal of
dc.relation.referencesen	Geophysical Research: Solid Earth, 103(B5),10131–10140.
dc.relation.referencesen	Fylatj'ev V. P. (2007). The influence of rotational
dc.relation.referencesen	effects on the tectonics of the planet (on the
dc.relation.referencesen	example of the transition zone from the Asian
dc.relation.referencesen	continent to the Pacific Ocean). Rotational
dc.relation.referencesen	processes in Geology and Physics. Moscow., 341–360 (in Russian).
dc.relation.referencesen	Khain, V. E., & A. I. Poletayev. (2007). Rotation
dc.relation.referencesen	tectonics of the Earth. Science in Russia, (6), 14–21 (in Russian).
dc.relation.referencesen	National Geophysical Data Center. (2006, July 26).
dc.relation.referencesen	ETOPO5 Data and Documentation \| ngdc.noaa.gov. Retrieved from https://www.ngdc.noaa.gov/mgg/global/etopo5.HTML
dc.relation.referencesen	Pandul, Y. (2017). Geodetic astronomy applied to the
dc.relation.referencesen	solution of engineering and geodesic problems.
dc.relation.referencesen	Litres.
dc.relation.referencesen	Project Overview. (n.d.). Retrieved from http://ggosatm.hg.tuwien.ac.at/
dc.relation.referencesen	Sottili, G., Palladino, D. M., Cuffaro, M., & Doglioni,
dc.relation.referencesen	C. (2015). Earth’s rotation variability triggers
dc.relation.referencesen	explosive eruptions in subduction zones. Earth,
dc.relation.referencesen	Planets and Space, 67(1), 208. https://doi.org/10.1186/s40623-015-0375-z
dc.relation.referencesen	Seitz, F., & Schmidt, M. (2005). Atmospheric and
dc.relation.referencesen	oceanic contributions to Chandler wobble
dc.relation.referencesen	excitation determined by wavelet
dc.relation.referencesen	filtering. Journal of Geophysical Research: Solid
dc.relation.referencesen	Earth,110(B11). doi:10.1029/2005jb003826
dc.relation.referencesen	Navigation and service. (n.d.). Retrieved fromhttps://www.iers.org/IERS/EN/Home/home_node.html
dc.relation.referencesen	Johnson, T. J., Wilson, C. R., & Chao, B. F. (1999).
dc.relation.referencesen	Oceanic angular momentum variability estimated
dc.relation.referencesen	from the Parallel Ocean Climate Model, 1988–1998. Journal of Geophysical Research: SolidEarth,104(B11), 25183-25195.doi:10.1029/1999jb900231
dc.relation.referencesen	Khain, V. E. (2010). Constructing a truly global
dc.relation.referencesen	model of Earth’s dynamics: basic principles.
dc.relation.referencesen	Russian Geology and Geophysics, 51(6), 587–591.
dc.relation.referencesen	Tretjak K. R., Alj-Alusi F. K. F. About relationship of
dc.relation.referencesen	uneven of the Earth rotational movement and
dc.relation.referencesen	Antarctic tectonic plate. Ukrainian Antarctic
dc.relation.referencesen	Journal, (14), 43–57 (in Ukrainian).
dc.relation.referencesen	Tretyak, K., Forat, A., & Holubinka, Y. (2017).
dc.relation.referencesen	Investigation of Changes of the Kinematic
dc.relation.referencesen	Parameters of Antarctic Tectonic Plate Using Data
dc.relation.referencesen	Observations of Permanent GNSS Stations.
dc.relation.referencesen	Reports on Geodesy and Geoinformatics, 103(1).doi:10.1515/rgg-2017-0010
dc.relation.referencesen	Kane, M. F. (1972). Rotational Inerfia of Continents:
dc.relation.referencesen	A Proposed Link between Polar Wandering and
dc.relation.referencesen	Plate Tectonics. Science, 175(4028), 1355–1357.doi:10.1126/science.175.4028.1355
dc.relation.referencesen	Nastula, J., & Ponte, R. M. (1999). Further evidence
dc.relation.referencesen	for oceanic excitation of polar motion.
dc.relation.referencesen	Geophysical Journal International, 139(1), 123–130. doi:10.1046/j.1365-246x.1999.00930.x
dc.relation.referencesen	Link to our Data Products Page:. (n.d.). Retrievedfrom http://geodesy.unr.edu/
dc.relation.referencesen	Ponte, R. M., & Gutzler, D. S. (1991). The Madden-
dc.relation.referencesen	Julian oscillation and the angular momentum
dc.relation.referencesen	balance in a barotropic ocean model. Journal of
dc.relation.referencesen	Geophysical Research: Oceans, 96(P.1), 835–842.doi:10.1029/90jc02277
dc.relation.referencesen	Ponte, R. M., & Stammer, D. (2000). Global and
dc.relation.referencesen	regional axial ocean angular momentum signals and
dc.relation.referencesen	length-of-day variations (1985–1996). Journal of
dc.relation.referencesen	Geophysical Research: Oceans, 105(P.7), 17161–17171. doi:10.1029/1999jc000157
dc.relation.referencesen	Ponte, R. M., & Stammer, D. (1999). Role of ocean
dc.relation.referencesen	currents and bottom pressure variability on
dc.relation.referencesen	seasonal polar motion. Journal of Geophysical
dc.relation.referencesen	Research: Oceans, 104(P.10), 23393–23409.doi:10.1029/1999jc900222
dc.relation.referencesen	Ponte, R. M., & Rosen, R. D. (1994). Oceanic angular
dc.relation.referencesen	momentum and torques in a general circulation
dc.relation.referencesen	model. Journal of physical oceanography, 24(9),1966–1977.
dc.relation.referencesen	Ponte, R. M. (1990). Barotropic motions and the
dc.relation.referencesen	exchange of angular momentum between the oceans
dc.relation.referencesen	and solid Earth. Journal of Geophysical Research,95(P.7), 11369. doi:10.1029/jc095ic07p11369
dc.relation.referencesen	Ponte, R. M., Stammer, D., & Marshall, J. (1998).
dc.relation.referencesen	Oceanic signals in observed motions of the Earths
dc.relation.referencesen	pole of rotation. Nature, 391(6666), 476–479.doi:10.1038/35126.
dc.relation.referencesen	Ponte, R. M. (1997). Oceanic excitation of daily to
dc.relation.referencesen	seasonal signals in Earth rotation: Results from a
dc.relation.referencesen	constant-density numerical model. Geophysical
dc.relation.referencesen	Journal International, 130(2), 469–474.doi:10.1111/j.1365-246x.1997.tb05662.x
dc.relation.referencesen	Schettino, A. (1999). Computational methods for
dc.relation.referencesen	calculating geometric parameters of tectonic
dc.relation.referencesen	plates. Computers & Geosciences, 25(8), 897–907. doi:10.1016/s0098-3004(99)00054-0
dc.relation.referencesen	Scripps Orbit and Permanent Array Center (SOPAC).
dc.relation.referencesen	(n.d.). Retrieved from http://sopac.ucsd.edu/
dc.relation.referencesen	Sella, G. F., Dixon, T. H., & Mao, A. (2002).
dc.relation.referencesen	REVEL: A model for Recent plate velocities from
dc.relation.referencesen	space geodesy. Journal of Geophysical Research:
dc.relation.referencesen	Solid Earth, 107(B4). doi:10.1029/2000jb000033
dc.relation.referencesen	Jin, S., & Zhu, W. (2004). A revision of the
dc.relation.referencesen	parameters of the NNR-NUVEL-1A plate velocity
dc.relation.referencesen	model. Journal of Geodynamics, 38(1), 85–92.doi:10.1016/j.jog.2004.03.004
dc.relation.referencesen	Tretyak, K. R., & Vovk, A. I. (2016). Differentation
dc.relation.referencesen	of the rotational movements of the european
dc.relation.referencesen	continents Earth crust. Acta Geodynamica et
dc.relation.referencesen	Geomaterialia, 13(1), 181.
dc.relation.referencesen	Vikulin, A. (2015). Geodynamics as wave dynamics
dc.relation.referencesen	of the medium composed of rotating
dc.relation.referencesen	blocks. Geodynamics & Tectono-physics, 6(3),345–364. doi:10.5800/gt-2015-6-3-0185
dc.relation.referencesen	Vikulin, A. V., Makhmudov, Kh. F., Ivanchin, A. G.,
dc.relation.referencesen	Gerus, A. I., & Dolgaya, A. A. (2016). On the
dc.relation.referencesen	wave and reid properties of the Earth’s crust. Solid
dc.relation.referencesen	State Physics, 58 (3), 547–557.
dc.relation.referencesen	Jiang, W., E, D., Zhan, B., & Liu, Y. (2009). New
dc.relation.referencesen	Model of Antarctic Plate Motion and Its
dc.relation.referencesen	Analysis. Chinese Journal of Geophysics, 52(1),23-32. i:10.1002 /cjg2. 1323
dc.relation.referencesen	Wu, X., Ray, J., & Dam, T. V. (2012). Geocenter
dc.relation.referencesen	motion and its geodetic and geophysicalimplications. Journal of Geodynamics, 58, 44–61.doi:10.1016/j.jog.2012.01.007
dc.relation.uri	https://www.ngdc.noaa.gov/mgg/global/etopo5.HTML
dc.relation.uri	http://ggosatm.hg.tuwien.ac.at/
dc.relation.uri	https://doi.org/10.1186/s40623-015-0375-z
dc.relation.uri	https://www.iers.org/IERS/EN/Home/home_node.html
dc.relation.uri	http://geodesy.unr.edu/
dc.relation.uri	http://sopac.ucsd.edu/
dc.rights.holder	© Інститут геології і геохімії горючих копалин Національної академії наук України, 2018
dc.rights.holder	© Інститут геофізики ім. С. І. Субботіна Національної академії наук України, 2018
dc.rights.holder	© Державна служба геодезії, картографії та кадастру України, 2018
dc.rights.holder	© Львівське астрономо-геодезичне товариство, 2018
dc.rights.holder	© Національний університет “Львівська політехніка”, 2018
dc.rights.holder	© К. Р. Третяк, Ф. К. Ф. Аль-Алусі,Л. В. Бабій
dc.subject	Антарктична плита
dc.subject	момент імпульсу
dc.subject	тензор інерції
dc.subject	кутова швидкість
dc.subject	полюс Ейлера
dc.subject	ГНСС-станції
dc.subject	Antarctic plate
dc.subject	angular momentum
dc.subject	tensor of inertia
dc.subject	angular velocity
dc.subject	Euler pole
dc.subject	GNSSstations
dc.subject	Антарктическая плита
dc.subject	момент импульса
dc.subject	тензор инерции
dc.subject	угловая скорость
dc.subject	полюс Эйлера
dc.subject.udc	528.481
dc.title	Investigation of the interrelationship between changes and redistribution of angular momentum of the earth, the antarctic tectonic plate, the atmosphere, and the ocean
dc.title.alternative	Дослідження взаємозв’язку між змінами та перерозподілом моменту імпульсу землі, антарктичної тектонічної плити, атмосфери та океану
dc.title.alternative	Исследование взаимосвязи между изменениями и перераспределением момента импульса земли, антарктической тектонической плиты, атмосферы и океана
dc.type	Article

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