一九一八年广东南澳大地震及其发震构造背景的初步探讨

1918年2月18日南澳大地震,发生在广东与福建毗邻的南澳、东山之间。震中烈度X~*,震级7(1/2)级。这是华东南诸省(区)除台湾省外,自1606年以来最强烈的一次大地震;乃1600年9月29日南澳大地震的原地重复。极震区主要长轴走向北东东,但极震区中部明显向北北西方向突出,故亦有一走向北北西的长轴与之相交。该地震是在主压应力轴为北西西290~*左右的水平应力场的作用下,发生于南海北部陆缘地震带东段的北侧、现阶段强烈上升的大陆滨海边缘断隆带与强烈下降的北部湾—珠江口外—台湾浅滩断坳带的边缘转折地段。发震断裂为一对X型北东东走向和北北西走向(以前者为主)的高角度走滑断层。     

2015年4月15日阿拉善左旗M_S 5.8地震序列特征

2015年4月15日内蒙古阿拉善左旗发生M_S 5.8地震,震中位于鄂尔多斯块体西北边缘,吉兰泰断陷盆地北端。古近纪以来,受喜山运动强烈影响,阿拉善地块急剧抬升,断裂活动加剧,近年来小震活动呈密集分布。研究地震序列分布,序列整体分布较集中,主体呈北东东向展布,为主余型地震。由震源机制及烈度考察,发现极震区长轴均为北东东向,与北东方向的磴口—本井隐伏活动断裂走向基本一致,综合判定该断裂可能是此次地震的发震构造。     

1992年8月19日吉尔吉斯斯坦苏莎维尔7.5级大震简介

1992年8月19日北京时间10h 04min,在φ_N42°04′,λ_E73°38′处发生里氏震级为7.3～7.5级大地震,震源深度25km。这次大地震是1946年奇姆肯特7.6级地震以来吉尔吉斯斯坦境内发生的最强烈地震,造成54人死亡、100多人受伤,共损失140亿卢布(约折合7千万美元)。 该震宏观震中位于苏莎维尔,较仪器测定位置偏西5km,为一近东西向河谷地带。极震区烈度为9度,呈北东东向延伸的椭园形分布,长轴为35km、短轴为12km。极震区内产生大量     

1932年昌马地震破裂带成因的讨论

本文根据昌马地震破裂带的特征所反映的震区地质块体在空间的运动方式,对前人关于昌马地震的主压应力方向及相应的构造应力场提出了异议。通过讨论,阐述了昌马地震是现今作用于震区的北东东向挤压的区域应力场活动的结果,昌马地震破裂带是北北西向断裂和北西西向断裂在北东东向挤压应力场作用下,分别作兼有右旋的逆冲和近水平左旋扭动的产物。     

1998年张北6.2级地震宏观烈度

充分利用震害评估和宏观考察的资料 ,采用震害程度和震害指数 2个标准共同确定了1 998年张北 6.2级地震的宏观烈度。极震区烈度为 度 ,呈 NWW和 NNE双向分布 ,以NWW为主 ,面积 1 35km2 。 度区呈 NE、NW双向伸展图象 ,但是 SE方向伸展不足 ,面积约340 km2。地震重伤人员普遍集中在 度区和 度区。 度区亦呈 NE、NW双向伸展图象 ,但是 NW、SW方向延伸长 , 度区面积约 1 0 0 0 km2 。宏观震中 :北纬 41°0 9′,东经 1 1 4°2 7′。在极震区的 NNE、SSW和 NWW方向 ,存在 3个烈度异常区 ,它们分别在极震区 3个分支的延伸方向上。文中讨论了烈度不高而震后较重的原因。震区没有发现地表破裂带 ,也没有发现第四纪强烈活动的大型断裂。极震区为主的 NWW方向和震前存在的小地震条带吻合 ,暗示可能存在成因上的联系     

广西灵山地区断裂活动性与土壤中汞气含量变化

本文介绍了广西灵山地区土壤中汞气含量测定的结果，通过对比分析含汞量的变化，指出罗阳山西北麓北东东向断裂是测区最活动的断裂，其次是北西向的蕉极坪断裂。在历史强震区，土壤中汞气含量高，变化幅度大，断裂活动性强。     

1936年广西为山27／4级地震极震区震害和地震影响场的研究

１９３６年广西灵山２７／４级地震是南海北缘内陆最强的一次地震，也是震害最严重的一次，震中烈度９度强。倒房率震害指数甚高，地震破坏和其它宏观现象也非常突出，形成两个极震区，其一长轴北东东向，其二长轴北北西向。     

秭归龙会观5.1级震区及其邻区新生代以来的地壳应力场特征

为了研究三峡坝库区的地壳稳定性,根据奥陶－侏罗纪地层中构造变形的实际观测资料,计算了秭归龙会观５．１级震区及其邻区新生代以来区域应力场的主应力方向。结果表明：主压应力为北东东向,主张应力为北北西向;现代构造应力场与新生代以来应力场基本一致;晚第三纪以来,该区构造应力场相对稳定和统一。     

2002年山西太原郝庄ML5.0地震宏观烈度考察报告

对2002年9月3日山西太原郝庄ML5.0地震的宏观烈度进行了考察，得出极震区烈度为V度，呈椭圆形，长轴走向北北西，长度53km，短轴走向为北东东，长度34km，面积5660km^2的结论。分析了地震发生的构造环境，认为此次地震的震中位于东西、南北和北北西向三级断层的交汇部位，其中北北西向的东山山前断层为发震断层。     

丹江口水库及其邻区地壳应力场的基本特征

利用赤平极射投影等资料，计算了丹江水库及邻区的主应力方向，结果表明，主压应力为北东东向，主张应力为北北西向，现代构造应力场与新生代以来应力场基本一致；晚第三纪以来，该区地壳应力场相对稳定。     

1987年8月2日寻乌地震的破裂方式

1987年8月2日,江西省寻乌发生M_S5.5级地震,震中烈度Ⅷ度,震中位于24°58′N,115°39′E,震源深度13km。本文根据震害特征、地壳构造活动性、震源机制、建筑物破坏的优势方向和介质条件,对这次地震的发震构造及其破裂方式作了初步探讨     

Sulitjelma Gabbro,northern Norway: A palaeomagnetic result

The Sulitjelma Gabbro situated at 67.2°N, 15.4°E was intruded close to the Late Ordovician climax of regional metamorphism in the northern Scandinavian Caledonides. Magnetic properties have been examined from samples collected at seven localities in the south western part of this body. Total NRM directions show a tendency to be aligned near the present earth's magnetic field direction in this region. Stability to a.f. demagnetisation is low and commensurate with low Koenigsberger ratios (0.001–0.16) and the presence of unoxidised magnetite as the principal remanence carrier. After cleaning the site mean directions no longer show an alignment near the present earth's field and of six statistically significant sites three are approximately reversed with respect to remainder. The combined mean direction after cleaning isD = 195°,I = 15° (precision parameterk = 6) and the derived virtual geomagnetic pole is at 0°E, 14°S (α₉₅ = 23°). This pole is close to poles of comparable age from the British Isles and suggests that Britain and Norway were part of the same crustal plate in Ordovician times. Discrepancies between Siluro-Devonian results from the two regions may be due to inadequate age coverage of present results.     

Paleomagnetic and gravimetrical reconnaissance of Cretaceous volcanic rocks from the Western Colombian Andes: paleogeographic connections with the Caribbean Plate

The reconstruction of the tectonic evolution of the oceanic crust, including the recognition of ancient oceanic plumes and the differentiation between multiple and single oceanic arcs, relies on the paleogeographic analysis of accreted oceanic fragments found in orogenic belts. Here we present paleomagnetic and gravity data from Cretaceous oceanic basaltic and gabbroic rocks, the continental metamorphic basement, and their associated cover from northwestern Colombia. Based on regional scale tectonic reconstructions and geochemical constraints, such rocks have been interpreted as remnants of an oceanic large igneous province formed in southern latitudes, which was accreted to the sialic continental margin during the Late Cretaceous. Gravity analyses suggest the existence of a coherent high density segment separated by major suture zones from a lower density material related to the continental crust and/or thick sedimentary sequences trapped during collision. A characteristic paleomagnetic direction in Early and Late Cretaceous oceanic volcano-plutonic rocks, revealing a southeastern declination (D) and a negative inclination (I), may be interpreted in two different ways: (1a primary magnetization (tilt-corrected direction D = 130.3°, I = -23.3°, k = 23.4, α₉₅ = 26.4°), suggesting clockwise rotation around 130°, and magnetization acquired in southern latitudes (range of 4°S to 21°S); or (2) a remagnetization event during a reverse interval of the Earth’s magnetic field in the Cenozoic (in situ direction D = 128.7°, I = -6.2°, k = 23.1, α₉₅ = 26.1°), suggesting a counter-clockwise rotation around 50°. The first scenario seems more plausible, as it is consistent with previous paleomagnetic studies at other localities; it is compatible with a southern paleogeography for this block, and when integrated with other regional geological and paleomagnetic studies, supports a southern Pacific origin of a major oceanic block, formed as a part of a broader Cretaceous plateau that may have extended south or southwest of Galapagos. After its initial accretion, this block was subsequently fragmented due to the oblique SW-NE approach to the continental margin during the Late Cretaceous.     

Crystallization temperature and gas phase composition of alkaline effusives as indicated by primary melt inclusions in the phenocrysts

Minerals formed during magma crystallization trap droplets of melt that are preserved as primary or secondary inclusions. Depending on the rate of cooling, the droplets may solidify as glass, or crystallize. Inclusions may contain one or more bubbles, or none. When inclusions are heated the glass or crystalline material are melted and the inclusion expands, the size of bubbles diminishes, and homogenization of the inclusion occurs. It is possible to observe these transformations by means of high-temperature cameras which permit visual observations to 1600°C and above. The possibility of using the homogenization of inclusions to determine the temperature of formation of the host mineral has been demonstrated experimentally, using inclusions in artificial diopside formed at 1300 ± 10°. Melt inclusions in phenocrysts from nepheline basalt, fergusite porphyry, and tephrite were investigated. In the leucite-bearing rocks leucite crystallized at 1600° or above, and clinopyroxene in the range 1380–1250°. The central part of olivines in nepheline basalt formed at 1290–1270° and the peripheral zones at 1160–1120°; nepheline formed at 1290–1250°; the central part of pyroxenes at 1280–1250° and the peripheral zones at 1160–1120°. These temperatures suggest almost dry magma. Gas from the bubbles of individual inclusions has been analyzed. The predominant gaseous component of the early crystallization stage of the nepheline basalt and fergusite porphry was CO₂, H₂S, SO₂, NH., HCl, HF, and H. comprise less than 5 volume percent except in olivine of olivine basalt in which the total content of these gases was on average 6.22 volume percent, and in leucite of fergusite porphyry in which H₂ was on average 12.7 volume percent. The main gas component in the crystallization of the leucite tephrite were nitrogen and rare gases. Liquid hydrocarbons in the secondary inclusions in pyroxene from nepheline basalt can be accounted for by their assimilation by the magma from enclosing rocks during its rise.     

Palaeomagnetism of the dyke swarms of the Gardar Igneous Province,south Greenland

In the western part of the Gardar Igneous Province of southern Greenland, lamprophyre dykes intruded at ca. 1276-1254 m.y. RbSr biotite ages yield a palaeomagnetic pole at 206.5°E,3°N (nine sites, dψ = 5.1°, d_χ = 10.1°) Slightly younger dolerite dykes with RbSr biotite ages in the range 1278-1263 m.y. give a pole at 201.5°E,8.5°N (24 sites, dψ = 4.7°, d_χ = 9.4°), and the syeno-gabbro ring dyke of the Kûngnât complex (RbSr isochron age 1245 ± 17 m.y.) cutting both of these dykes swarms, gives a pole at 198.5°E, 3.5°N (four sites, dψ = 2.3°,d_χ = 4.4°). All these rock units have the same polarity and the poles are identical to those from Mackenzie and related igneous rocks of North America (1280-1220 m.y.) after closure of the Davis Strait; they confirm that this part of the Gardar Province is a lateral extension of the Mackenzie igneous episode within the Laurentian craton.In the Tugtutôq region of the eastern part of the Gardar Province 47 NNE-trending dykes of various petrologic types, and intruded between 1175 ± 9 and 1168 ± 37 m.y. (RbSr isochron ages) yield a palaeomagnetic pole at 223.9° E, 36.4°N (dψ = 4.1°, d_χ = 6.1°). Fifteen other dykes in this swarm were intruded during a transitional phase of the magnetic field which, however, does not appear to have achieved a complete reversal over a period of several millions of years. The majority of dykes studied are highly stable to AF and thermal demagnetisation and contain single high blocking temperature components with single Curie points in the range 380–560°C.Palaeomagnetic poles from the Gardar Province between ca. 1330 and 1160 m.y. in age define the earlier part of the Great Logan apparent polar-wander loop; they correlate closely with contemporaneous North American results and confirm the coherence of the Laurentian craton in Upper Proterozoic times.     

Palaeomagnetic evidence from the Ordovician and Silurian of northwest Peninsular Malaysia

The Ordovician and Silurian Setul Limestone of the Langkawi Islands, northwest Peninsular Malaysia, has a mean magnetic vector ofD = 338°,I = 62° after cleaning and correction for tilt. This is equivalent to a palaeolatitude of 43°, and a palaeomagnetic pole at 46°N, 76°E. The Silurian part of the Setul limestone also shows a similar direction. The Ordovician results are equivalent to a palaeolatitude of 43°, N or S. Recent reconstructions, based on palaeontology, place Indochina and China in the northern hemisphere in the Ordovician; if this is correct, a palaeolatitide of 43° for Langkawi would imply that Malaya-Indochina was the most northerly continental fragment at that time.     

Paleomagnetic study on orogenic belt: An example from Early Cretaceous volcanic rocks,Inner Mongolia,China

Since the 1990s, a large number of paleomagneticstudies have been carried out in the North China block(NCB) and Tarim block[1-8], and more and more geo-physicists recently believe that the last collision andconvergence between Siberia and the Mongolia-NorthChina plate happened in the Late Jurassic, which wascontributed to a paleomagnetic study on these areas byZhao and his colleagues[2]. However, we lack paleo-magnetic results obtained directly from the orogenicbelt between Siberia and th…     

Paleomagnetism of the Lower Ordovician and Cambrian sedimentary rocks in the section of the Narva River right bank: For the construction of the Baltic Kinematic model in the Early Paleozoic

The paleomagnetic study of the Lower Ordovician and Cambrian sedimentary rocks exposed on the Narva River’s right bank revealed a multicomponent composition of natural remanent magnetization. Among four distinguished medium- and high-temperature magnetization components, the bipolar component, which carries the reversal test, is probably the primary component and reflects the geomagnetic field direction and variations during the Late Cambrian and Early Ordovician. The pole positions corresponding to this component have coordinates 22°N, 87°E (dp/dm = 5°/6°) for the Late Cambrian, and 18°N, 55°E (dp/dm = 5°/7°) for the Early Ordovician (Tremadocian and Arenigian). Together with the recently published paleomagnetic poles for the sections of the Early Ordovician in the Leningrad Region and the series of poles obtained when the Ordovician limestones were studied in Sweden, these poles form new key frameworks for the Upper Cambrian-Middle Ordovician segment of the apparent polar-wander path (APWP) for the Baltica. Based on these data, we propose a renewed version of the APWP segment: the model of the Baltica motion as its clockwise turn by 68° around the remote Euler pole. This motion around the great circle describes (with an error of A₉₅ = 10°) both variations in the Baltic position from 500 to 456 Ma ago in paleolatitude and its turn relative to paleomeridians. According to the monopolar components of natural remanent magnetization detected in the Narva rocks, the South Pole positions are 2°S, 351°E (dp/dm = 5°/9°), 39°S, 327°E, (dp/dm = 4°/7°), and 42°S and 311°E (dp/dm = 9°/13°). It is assumed that these components reflect regional remagnetization events in the Silurian, Late Permian, and Triassic.     

中国南北地震带磁性层构造特征

本文首先给出磁性层下界面反演的等效模型和其在球坐标系下变地磁倾角的二维反演方法,利用航磁资料研究了南北地震带的磁性层结构构造及其与地震活动性的关系为:1.磁性层南北两端厚,中间薄;2.下界面呈南北向的宽隆起带,北浅南深;3.磁性层所处的层位温压条件适于积累应力能量产生粘滑错动,地震多发生在磁性层内,往往位于磁性层由厚变薄的过渡处,并多伴有断裂、温泉、岩浆活动     

Paleomagnetism and ore mineralogy of some basalts of the Geirud Formation of Late Devonian - Early Carboniferous age from the southern Alborz,Iran

Basaltic lavas from the southern Alborz, an area about 40 km northeast of Tehran, Iran, have been paleomagnetically investigated. The lavas are of Late Devonian-Early Carboniferous age, and belong to the basal member of the Geirud Formation. At 11 sites a total of 80 cores was drilled.Detailed analyses by means of progressive demagnetization of the natural remanent magnetization (NRM) were made both by the application of alternating magnetic fields and by heating. Also, on a number of specimens a study was done both with thin sections and with polished sections. There proved to be general agreement between the properties of the characteristic NRM and the kind of Fe-Ti oxides in the lavas. In the case of specimens containing magnetite only the characteristic NRM was entirely removed at temperatures just below 600°C, or in alternating fields up to 1500/2000 Oe peak value; on the other hand, in specimens containing both magnetite and a substantial part of hematite (martite) the final part of the characteristic remanence was removed at temperatures above 600°C, and this remanence resisted alternating fields above 2000 Oe peak value. From the characteristic site-mean directions of 5 sites an average paleomagnetic direction is computed withD = 210.8°,I = 66.9°, and α₉₅ = 3.9°.This result might be taken as an indication that at the Devono-Carboniferous transition the southern part of the Alborz was located in the present Indian Ocean off the Arabian coast.