a1_A water-tube tiltmeter system composed of two perpendicular tubes was installed in the underground galleries of the Geodynamic Laboratory in the Książ Castle, Central Sudetes, in 2003. The partially filled water tubes are several tens of metres in length and have high-precision interferometric recording gauges at their ends. The recording gauges continuously measure water level changes in the tubes with single-nanometer accuracy which corresponds to 0.005 milliseconds of arc of plumb line variations. The tiltmeter has recorded several events of water level variations, with a magnitude of a few hundred micrometers and a duration of tens of days. The strongest water level variations were one order greater than variations caused by tidal phenomena and occurred in different months of a year, and hence are expected to have no seasonal origin. Because of the extremely large magnitude of the phenomenon and because time of duration of signals showed no seasonal characteristics, all external sources outside the bedrock space occupied by the instrument can also readily be precluded. Each of the recorded strong signals of water level variations consists of a symmetrical and an asymmetrical component. Because of the proportion of the water system to the large-scale geodynamic sources producing water level changes, all the external geodynamic reasons can generate only symmetrical signals in the tubes. The evidence indicates episodic tilting of the instrument itself or vertical displacements of any part of the tubes, which supports the notion of active bedrock deformation. The combination of symmetrical and asymmetrical signals implies that their source is within the bedrock space in which the instrument is embedded. The events of large water level variations can be explained by non-flat relative vertical displacement of the opposite ends of the tiltmeter tubes., a2_Asymmetrical signals are particularly pronounced in the tube named 03-04, and their magnitude suggests vertical displacement of part of the tube of the order of hundreds of micrometres. The repeatability, temporal irregularity, considerable duration time and high magnitude of the strong signals lead us to attribute them to the tilting of tiltmeter bedrock due to contemporary tectonic movements of the Książ Massif. The Książ Massif consists of a rigid rock mass of Famennian−Tournaisian conglomerates cut by several large and small faults. Rock compaction can be precluded. The massif is a prominent bedrock spur carved by a deeply incised river, and its geomorphic development seems to be related to major faults. Preliminary geological study has recognized strike-slip faults, thrusts and extensional fracture zones, some with an indication of recent activity. A few minor faults cross the bedrock under the tiltmeter geodynamic system. The tiltmeter is thus likely to be recording local signals of neotectonic activity., Marek Kaczorowski and Jurand Wojewoda., and Obsahuje bibliografii
a1_For estimation of recent dynamics of morphology of the Sudetes, satellite radar images of 90-meter resolution have been used. Basing on the Digital Elevation Model, trend surfaces and deviation maps of the morphology were made. The analyzed are a ranges over 23000 sq. km and is bordered by the following coordinates: N51°05’32", N49°56’26", E15°02’42" an d E17°37’57". The 8th-order trend surface records four distinct regional morphological domains. These are two elevations with their centres located at N50°46’24" - E15°29’24" and N50°07’24" - E17°13’07", as well as two depressions with centers located at N 50°05’41" - E15°46’58" and at N50°29’39”- E17°28’30", respectively. The elevations and depressions extend both over the crystalline massifs and sediment ary basins and are highly lithologically differentiated. On the deviation map, the elevations display the highest positive values which suggests a local disequilibrium of morphogenic processes during the formation of recent topography. Today’s landscape have been being shaped since the beginning of the Neogene. As the climatic and hydrological conditions have been rather uniform for the whole area, a tectonic uplift must be accounted for the reason of the indicated anomalies occurrence. There is only one unique profile across the elevations and depressions that reflects the smallest amplitude of relative height (black-white dashed-line). It is parallel to the dominant "Sudetic strike", i.e. 115°, and it follows the Intrasudetic Shear Zone (ISZ) that played an important role in the post-Variscan evolution of the Sudetes. Along and inside the ISZ small, mostly pull-apart basins occur (the Krkonoše Piedmont Basin (KPB), the Nachod Basin (NB), the Upper Nysa Kłodzka Trough (UNKT) - the South Sudetic Basins Suite (SSBS) - which are filled with Permian, Triassic and Neogene-to-Recent sediments., a2_The author postulates right lateral regional displacement along and beneath the ISZ as an important factor controlling long time evolution of topography in the analyzed area., Jurand Wojewoda., and Obsahuje bibliografické odkazy
The trans-border area of the Sudetes between Žďarky and Pstrążna has attracted Prussian/German, Austrian, Czech and Polish geologists since the middle of the 19th century. The history of mapping of this area reflects the scientific development of geological centres in Berlin, Vienna, Prague and Wrocław. This paper presents a description of the oldest geological maps of Lower Silesia in the context of changing knowledge on the Carboniferous and Cretaceous stratigraphy and on the tectonics of the region. On the basis of DEM and field studies the author presents his own geological map of the area of the Pstrążna Elevation together with a description of the local structural geology. A regional structural model is suggested, that explains all the local elevations as having developed in response to a dextral strike-slip activity of the Žďarky-Jakubowice Fault during late Tertiary to Recent times, at an eastern extension of the Poříčí-Hronov Fault Zone., Jurand Wojewoda., and Obsahuje bibliografii