Characteristics of normal fatty acids from sediments as a function of geologic-geochemical factors

Forty-nine samples from Mesozoic rocks of Northern Bulgaria and from recent marine muds of the Black Sea have been analyzed for fatty acids (FA), using extraction, treatment with ion exchange resin and gas chromatography. There is a higher concentration of normal (n) FA in the recent marine sediments, as well as in their bitumen extracts than in the rocks as a whole. There is twice as much n-FA in the rocks containing dispersed organic matter (DOM) formed mainly by benthonic organisms as compared to ancient sediments with planktonic DOM. The content of n-FA has decreased nine and five times, respectively in planktonic DOM in the sequence: limestones-marls-argillites and clayey siltstones, while the amount of organic carbon has risen four and two times. The n-FA are chiefly represented by C₁₆ and C₁₈ and in the recent sediments also by C₂₂ molecules. However when the level of maturity of DOM corresponds to the katagenetic degrees of MK₃ and MK₄, maximum is in n-FA with 19 and 20 carbon atoms. A gradual decrease in the amount of the n-FA with even-numbered carbon atoms was noted as maturity of the planktonic DOM increases from early diagenesis in recent marine sediments to the katagenetic degrees of MK₃ and MK₄ in ancient rocks. The ratios $\text{FA}\text{HC}$ and $\text{FA}\text{HC}\text{+ FA}$ have also decreased when the katagenetic maturity of DOM changes from PK₃ degree to MK₄ degree. These geochemical features may be used as an additional criterion in determining the principal phase of oil formation.     

Results of seismological observations in the western Kaliningrad region and in the Baltic Sea water area

In 2006–2007, researchers of the IO RAS conducted seismological observations in the Baltic Sea and western Kaliningrad region with the use of ocean-bottom and land-based autonomous seismic stations. According to maps of general seismic zoning of the territory of Russia, the Kaliningrad region is aseismic. However, a series of seismic phenomena with magnitudes of about 5 and sources located near the Bay of Gdansk coast occurred here in September 2004. The total duration of the IO RAS seismological observations in five areas of the region under investigation was more than 200 days. The analysis of seismic records of the IO RAS network located sources of two local weak earthquakes with magnitudes M _L = 3.4–3.5, which indicates that the seismic process in the western part of the Kaliningrad region continues and the region is far from being seismically stable.     

Marine seismological observations in the Central Kurile segment before catastrophic earthquakes on November, 2006 (<Emphasis Type="Italic">M</Emphasis> = 8.3) and January, 2007 (<Emphasis Type="Italic">M</Emphasis> = 8.1)

The results of detailed seismological observations with bottom seismographs in the Central Kurile segment in August-September, 2006 are discussed. The system of six bottom seismographs was placed on the island slope of the Kurile deep-sea trench southeast of Urup Island and southwest of the Bussol Strait. Over 230 earthquakes with M _LH = 0.5–5.5 were registered in the area with a radius of 150 km around the center of the observation system at depths up to 300 km during 16 days. Records of 80 earthquakes with hypocenters in the earth crust (h = 0–30 km) beneath the island slope of the Kurile deep-sea trench were first obtained by bottom seismographs. These data are inconsistent with previous concepts of aseismicity of this zone. The discovery of the unique morphological structure of the Benioff zone beneath the central Kurile Arc represents the most important result of detailed seismological observations. The zone consists of an inner seismoactive subzone, which is located beneath the island slope of the arc at depths of 15–210 km, being characterized by an angle of incline of 50° under the latter and crosses the ocean bottom approximately 80 km away from the trench axis, and outer low-activity subzone. The latter is traceable beyond the trench almost parallel to the inner zone beginning from a depth of 50 km below the sea bottom up to a depth of approximately 300 km. Due to the slightly lower incline (∼45°) of the outer subzone, both subzones gradually converge downward. The integral thickness of the Benioff zone varies from 150 km in its upper part to 125 km at depths of 210–260 km. The medium sandwiched between these subzones is practically aseismic. The reality of this defined structure is confirmed by the distribution of aftershocks of the earthquake that occurred on November 15, 2006 (M = 8.3). These seismic events served as foreshocks for the subsequent strong earthquake of January 13, 2007 (M = 8.1) with the hypocenter located beyond the trench under the ocean bottom. Such a structure of this zone within the central Kurile Arc segment is unique, having no analogues either in the flanks of the Kurile-Kamchatka Arc or other arcs. The results of detailed seismological observations obtained two months before the first of the catastrophic Central Kurile earthquakes appeared to be typical for the period of foreshocks (the lower seismic activity of the Simushir block, which hosted the hypocenter of the earthquake that occurred on November 15, 2006, particularly at depths of 0–50 km, the gentler incline of the recurrence plot, and other features).     

Seismic microzonation and assessment of earthquake hazard for the construction sites of sea-based facilities in low seismicity water areas

This paper reports the results from a study on earthquake hazard assessment for the northwestern part (until now considered to have been a low seismicity area) of the northern Caspian Sea around Morskoi Ivan-Karaul Island where oil-producing facilities are to be built. This earthquake hazard assessment is based on the traditional approach by analysis and summary of geological and geophysical data (primarily fault tectonics and geophysical fields). Seismic microzonation was carried out by the dynamic method based on the comparison of ground motion spectral amplitudes at a reference site and at other sites in the water area of interest. The basic data were records of aftershocks of teleseismic events made by OBSs. The experiment in dynamic microzonation turned out to be unique, in the sense that it was conducted in very shallow water (1–5 m), where the level of seismic noise is affected, not only by currents, but also by sea waves. We stress the importance of seismic monitoring during the operation period of the oil-gas facilities to provide checks on the technological process and to ensure the ecological safety of the environment.     

Some spectrophotometric data for 31 galaxies from Karchentsev's list

U, B, V photoelectric observations of the eclipsing binary system DX Aqr, secured in 1981, have been presented. Present results, when compared with earlier ones (cf. Srivastava and Sinha, 1985), suggest that the features of the system are changing. Some new features are reported.     

New data on seismicity of the middle Caspian Basin and their possible tectonic interpretation

Short-term (three months) bottom seismic observations in the area of the Yalam-Samur structure in the Middle Caspian Basin revealed a deep-seated compact zone of mantle-earthquake sources that dips beneath the southeastern Caucasus. To a first approximation, this zone may be interpreted as a seismofocal layer that characterizes thrusting of the Turan Plate under the southeastern Caucasus. However, the obtained spatial distribution of sources of microearthquakes and weak earthquakes is insufficiently reliable owing to the low aperture of the observation network of bottom seismographs. More reliable data on the position and parameters of the seismofocal layer could be obtained by the observation network with a wider spread of bottom seismographs (up to 50–100 km). If this result is confirmed, the current concept of interaction between the Alpine structures of the southeastern Caucasus, Turan, and South Caspian plates should probably be revised. The geotectonics of the Caucasus is preliminarily analyzed in the light of the newly revealed relationships.     

New Data on Seismotectonics of the Laptev Sea from Observations by Ocean Bottom Seismographs

Doklady Earth Sciences - The results of new local seismic observations in the Laptev Sea obtained using ocean bottom seismographs were compared with actual data from global and regional earthquake...