ПРАВОВІ ТА ПСИХОЛОГІЧНІ АСПЕКТИ ЗАСТОСУВАННЯ ВОГНЕПАЛЬНОЇ ЗБРОЇ ПЕРСОНАЛОМ ПОЛІЦІЇ

The author has provided the results of the study of international countries’ legislation regulating the use of firearms by the police. Various positions of specialists in the field of law have attracted the author’s attention. Thus, scholars within administrative law consider the use of firearms by the police as an administrative compulsion. Others believe that the use of firearms by the police is a criminal and legal measure, since it is aimed at neutralizing a criminal rather than an administrative offense. It has been noted that the police service is a part of extreme occupations, the police themselves constitute a high-risk group, and this is due to a large number of stress factors. Due to the results of the analysis of the causes of police officers’ deaths in different regions of the world, the problem of high level of mortality and traumatism occupies the special place within police activities. The results of the author’s correlation analysis confirmed that crime is one of the factors that directly affect the deaths of police officers and offenders. Some aspects of fire fighting between police officers and armed criminals have been considered. It has been emphasized that the use of firearms causes high level of psychological traumatization of police personnel. This is due to the pathogenic effects of extreme stressors and the psycho-traumatic consequences of the use of weapons. In order to reduce psychological trauma and sanitary losses among police personnel after the use of department-issued sidearm, the author has offered a compulsory conduction of a complex of emergency special measures of psychological, medical and pharmacological nature; to eliminate the negative consequences of using firearms, the author also considers it important to conduct a special debriefing for this category of police officers.Розглянуто питання застосування поліцією табельної вогнепальної зброї. Дано аналіз стрес-факторів професійної діяльності поліції, які безпосередньо впливають на травматизацію та загибель особового складу. Установлено кореляційну залежність між рівнем злочинності у країні та кількістю вбитих поліцією злочинців. Детально проаналізовано вогневий двобій між поліцейськими та злочинцями. Розглянуто проблеми, пов’язані з високим рівнем психічної травматизації особового складу поліції внаслідок застосування табельної зброї на ураження

Asymmetric Upwarp of the Asthenosphere beneath the Baikal Rift Zone, Siberia

In the summer of 1991 we installed 27 seismic stations about lake Baikal, Siberia, aimed at obtaining accurately timed digital seismic data to investigate the deep structure and geodynamics of the Baikal rift zone and adjacent regions. Sixty-six teleseismic events with high signal-to-noise ratio were recorded. Travel time and Q analysis of teleseisms characterize an upwarp of the lithosphere-asthenosphere boundary under Baikal. Theoretical arrival times were calculated by using the International Association of Seismology and Physics of the Earth\u27s interior 1991 Earth model, and travel time residuals were found by subtracting computed arrival times from observed ones. A three-dimensional downward projection inversion method is used to invert the P wave velocity structure with constraints from deep seismic sounding data. Our results suggest that (1) the lithosphere-asthenosphere transition upwarps beneath the rift zone, (2) the upwarp has an asymmetric shape, (3) the velocity contrast is -4.9% in the asthenosphere, (4) the density contrast is -0.6%, and (5) the P wave attenuation contrast t* is 0.1 s

S K S Splitting beneath Continental Rift Zones

We present measurements of S K S splitting at 28 digital seismic stations and 35 analog stations in the Baikal rift zone, Siberia, and adjacent areas, and at 17 stations in the East African Rift in Kenya and compare them with previous measurements from the Rio Grande Rift of North America. Fast directions in the inner region of the Baikal rift zone are distributed in two orthogonal directions, NE and NW, approximately parallel and perpendicular to the NE strike of the rift. In the adjacent Siberian platform and northern Mongolian fold belt, only the rift-orthogonal fast direction is observed. In southcentral Mongolia, the dominant fast direction changes to rift-parallel again, although a small number of measurements are still rift-orthogonal. For the axial zones of the East African and Rio Grande Rifts, fast directions are oriented on average NNE, that is, rotated clockwise from the N-S trending rift. All three rifts are underlain by low-velocity upper mantle as determined from teleseismic tomography. Rift-related mantle flow provides a plausible interpretation for the rift-orthogonal fast directions. The rift-parallel fast directions near the rift axes can be interpreted by oriented magmatic cracks in the mantle or small-scale mantle convection with rift-parallel flow. The agreement between stress estimates and corresponding crack orientations lends some weight to the suggestion that the rift-parallel fast directions are caused by oriented magmatic cracks

Reply [to “Comment on “SKS Splitting beneath Continental Rifts Zones” by Gao et al.”]

Vauchez et al. [this issue] (hereinafter refered to as VBN) interpret the petrologic, tomographic, and anisotropy data from continental rifts to support a model of continental rifting [Nicolas, 1993; Nicolas et al., 1994] in which the lithosphere splits along the rift axis and asthenosphere flows in from the sides to fill the resulting gap. We suggest here that the data can also be described by a model in which the lower lithosphere is modified or eroded by active mantle upwelling over a region of significantly greater dimensions than the rift graben and that partial melt developing in the upwelling region can account for the widespread volcanism, as well as the seismic properties. Nicolas [1993] argued that rift-aligned anisotropy could be explained by rift-parallel mantle flow. We thank VBN for bringing this relevant paper to our attention. Volcanism about the East African Rift and the Rio Grande is not confined to the rifts but extends hundreds of kilometers from the rift axes (Mount Kilimanjaro, Mount Elgon, Mount Kenya in East Africa, The Jemez Lineament on the Rio Grande) in regions uplifted relative to their surroundings. The low-velocity tomographic anomalies also extend beneath the uplifted regions and are thought to be related to the uplift possibly supporting it by thermostatic buoyancy. The size of the P and S velocity contrasts and attenuation of high frequencies have led to the suggestion that large regions of the anomalous bodies have temperatures at or above the solidus [Achauer et al, 1994; Slack et al., 1994, 1996]. The wide extent of the anomalous regions is not explicable as resulting from an abyssal lithospheric dike beneath the rift intruded by asthenosphere. The extension of the East African, Baikal, and Rio Grande rift grabens has been estimated to be about 10 km [Baker et al., 1972; Baldridge et al., 1984; Morgan and Golombek, 1984; Logatchev and Florensov, 1978]. Passive influx of asthenosphere into a 10 km lithospheric dike is insufficient to explain the tomographic anomalies [Davis, 1991]. In addition, the amount of finite strain from lithospheric diking is insufficient to explain the anisotropy anomalies. Active replacement or modification of lower lithosphere either prior to, or contemporaneous with, rifting could generate tomographic anomalies of this magnitude

CMS physics technical design report : Addendum on high density QCD with heavy ions

Peer reviewe

Crustal structure of central Lake Baikal : insights into intracontinental rifting

This paper is not subject to U.S. copyright. The definitive version was published in Journal of Geophysical Research 107, B7 (2002): 2132, doi:10.1029/2001JB000300.The Cenozoic rift system of Baikal, located in the interior of the largest continental mass on Earth, is thought to represent a potential analog of the early stage of breakup of supercontinents. We present a detailed P wave velocity structure of the crust and sediments beneath the Central Basin, the deepest basin in the Baikal rift system. The structure is characterized by a Moho depth of 39–42.5 km; an 8-km-thick, laterally continuous high-velocity (7.05–7.4 km/s) lower crust, normal upper mantle velocity (8 km/s), a sedimentary section reaching maximum depths of 9 km, and a gradual increase of sediment velocity with depth. We interpret the high-velocity lower crust to be part of the Siberian Platform that was not thinned or altered significantly during rifting. In comparison to published results from the Siberian Platform, Moho under the basin is elevated by <3 km. On the basis of these results we propose that the basin was formed by upper crustal extension, possibly reactivating structures in an ancient fold-and-thrust belt. The extent and location of upper mantle extension are not revealed by our data, and it may be offset from the rift. We believe that the Baikal rift structure is similar in many respects to the Mesozoic Atlantic rift system, the precursor to the formation of the North Atlantic Ocean. We also propose that the Central Baikal rift evolved by episodic fault propagation and basin enlargement, rather than by two-stage rift evolution as is commonly assumed.This project was jointly funded by the U.S. Geological Survey Coastal and Marine Program and the Russian Academy of Sciences