共查询到18条相似文献,搜索用时 140 毫秒
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本文了分析1991年太阳活动峰年南极中山站地磁静日Sq变化,结果表明:1)地磁静日Sq变化叠加很多扰动。Sq场是由S0q场和Spq场所组成。2)Sop场变化比较规则,其极昼月的变幅比极夜月大很多。在极昼月S0q(H)变化出现有双峰图象。Sop场主要是由高结局度极区电离层Sq电流体系所控制。 相似文献
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利用南极地磁资料研究了地磁扰日变化SD场特征。1)SD场变化不如Sq场变化规则,无明显的昼夜差异;太阳活动高年(1991年)比下降年(1994年)SD场变化更强烈。2)极隙区中山站SD场变幅比亚极光区长城站和北半球低纬区北京台的SD场变幅大10倍以上。3)中山站S0D(H)变化呈“正弦波”形态,与长城站和北京台S0D(H)变化形态相反。4)中山站S0D等效电流矢量在早晨-下午(02~15h)矢量方向为反时针西向,下午-夜间(15~02h)矢量方向为顺时针东向,这是由极区东向、西向电射流和极区电流涡旋所引起;长城站与北京台S0D等效电流矢量很小,这是由极区东向和西向电射流的影响所致。 相似文献
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利用南极地磁资料研究了地磁扰日变化SD场特征。1.SD场变化不如Sq场变化规则,无明显的昼夜差异;太阳活动高年比下降年SD场变化更强烈。2.极隙区中山站SD场变幅比亚极光区长城站和北半球低纬区北京台的SD场变幅大10倍以上。3.中山站S^-D变化呈“正弦波”形态,与长城站和北京台S^-D变化形态相反。4.中山站S^-D等效电流矢量在早晨-下午矢量方向为反时针西向,下午-夜音矢量方向为顺时针东向,这 相似文献
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本文利用南极长城站1987年4月至9月的地磁资料,分析了长城站地区冬季地磁S_q变化特征。分析结果表明:(1)南极长城站在初冬(4月)与冬末(9月)月份的S_q变化形态与北半球中纬度的北京地磁台的S_q变化形态基本相似,这可能是由中纬度电离层中的发电机电流所控制的。在仲冬月份(6月与7月),由于太阳紫外辐射效应减少,高纬度的地磁扰动占主导地位,反映出S_q变幅很小和以8小时以下的较短周期谐波起主要作用,(2)在初冬与冬末月份的S_q等效电流矢量,白天比黑夜大约5倍;其矢量方向在白天(08—15时)为顺时针,黑夜为反时针。在仲冬月由于电离层中电流的影响相对减弱,S_q等效电流矢量很小,白天与黑夜基本一样;其矢量分布方向与初冬和冬末的矢量方向不同,这可能是极区的电离层电流或场向电流的影响造成的。 相似文献
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E层占优电离层是指E层的峰值电子密度大于F层的峰值电子密度(NmE>NmF)时的电离层,记为ELDI(E-Layer Dominated Ionosphere)。针对ELDI,利用2007-2010年的COSMIC (Constellation Observing System for Meteorology, Ionosphere, and Climate satellite)掩星数据,在修正地磁纬度-磁地方时标系下统计分析了它在南北极区极夜期间(南北半球的冬至日前后30天)的分布特征,结果表明极夜期间电离层ELDI特征明显,其分布与极光椭圆位形基本一致,而且其在夜侧的发生率较高,特别是磁子夜之后,北极为70%左右,而南极为90%左右;另外南极的ELDI特征在磁纬度分布上要略宽于北极的分布范围。在ELDI高发区,电离层峰值电子密度要高于其两侧地区,特别是在夜侧,尤其是磁子夜前的峰值电子密度要接近甚至大于磁正午的峰值电子密度,在南极地区格外明显;而且ELDI高发区内的E层的电子含量(TECE)、电离层总电子含量(TECI)及TECE占TECI的比重(TECEI)都高于其两侧地区,北极TECE和TECI大于南极,而TECEI则是南极大于北极。这些现象主要是由于极夜期间极区高能粒子沉降引起底部电离层电离率增大所致;同时,由于地磁轴偏离地理轴的程度在南极要大于北极,使得极夜期间南极地区的电离层的电子密度,特别是在F层要相应地小于北极地区,从而导致了极夜期间南北半球极区电离层ELDI特征之间差异。 相似文献
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利用南极长城站(62°13′S,58°58′W)频高图和磁照图研究了1989年3月13日磁暴的亚极光区电离层效应。在紧接着磁暴急始后F层的虚高h′F急剧上升,临频f0F2急剧下降,然后出现扩展F并持续几小时。在磁暴主相,电离层出现严重的吸收,但有时仍能观测到h′F的增加和伴随着的f0F2的降低。在磁暴急始后的第二和第三个晚上观测到极光型Es和夜间E层,其峰值电子浓度高达7.5×105el/cm3,文中讨论了造成这些现象的原因。在同一经度扇区的4个电离层站的h′F和f0F2的行为表明,观测站的纬度越高出现的吸收越严重,f0F2呈下降的时间越长。 相似文献
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The S~p_q equivalent current system of the quiet day geomagnetic variation in the polar region is very complicated. It is composed of several currents, such as the ionospheric dynamo current and the auroral electrojet caused by the field aligned current. S p q is unsymmetrical in both polar regions. In this paper, the S p q current systems are analyzed in the corrected geomagnetic coordinates (CGM) instead of the conventional geomagnetic coordinates (GM), and the symmetries of the S p q current in different systems are compared. Then the causes of S p q asymmetry in the GM coordinates are discussed; the effects of each component in S p q are determined. 相似文献
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A comparative study on the ionospheric current systems in the Antarctic and Arctic regions 总被引:1,自引:0,他引:1 下载免费PDF全文
AcomparativestudyontheionosphericcurrentsystemsintheAntarcticandArcticregionsXuWenyao(徐文耀)(InstituteofGeophysics,AcademiaSini... 相似文献
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本文利用电离层数字测高仪 (DPS - 4)所测的f0 F2和从美国NOAA和DMSP卫星观测估算的半球功率指数和午夜极光区赤道侧边界纬度等资料 ,考察中山站电离层的极区特征。结果表明 ,冬季中山站电离层内的电离生成主要取决于从磁层沉降的粒子。在太阳活动和地磁变化宁静环境下 ,磁正午极隙区内的软粒子是最主要的电离源 ,它能使f0 F2达全天的最大值 ;上、下午各有数小时处于极光带内时 ,高能粒子的电离作用也很重要 ;夜间进入极盖区后 ,电子密度则很低。夏季太阳辐射电离效应使f0 F2值比冬季增加 1- 1 .5MHz,而其日变化的最大值时间也提前了 1- 2hr。发生很大扰动时 ,极隙区和极光带的位置均向低纬方向移动。若中山站日间也处于极盖区内时 ,电子密度会大幅度下降 ,并常接收不到电离层回波的信号。在中等扰动环境下情况更加复杂。由于高纬电离层对流速度很高 ,离子 /中性分子间的碰撞复合系数就很大。热层中性大气全球经向环流对高纬电离层电子密度的增加无显著作用。磁暴期间中午从极隙区向南的等离子体对流对中山站f0 F2的增高也无明显影响。 相似文献
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极区高空物理现象之观测具有悠久历史。对极区地磁、电离层和极光现象的深入考察将地球物理的研究领域扩展到了外层空间,并提出了太阳风-磁层-电离层-热层间耦合这一重要课题。耦合物理机制的证实不仅是火箭、卫星探测的重要贡献,而且也是基于对地面雷达和遍及全球大陆的地磁台站、电离层垂测站之长期观测成果。对流电场、一区和二区场向电流、电离层扰动电流系(包括极光区电集流),以及电导率的分布和变化乃是一有机整体,对其每一环节的深入认识均与对整体的全面了解密不可分。有关的理论和模式研究则有助于人们深入理解各个耦合过程的相互关系,以及其各发展阶段中不同物理过程的相对重要性。 相似文献
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Summary . The first four harmonics of the lunar, L, and the solar, S, daily geomagnetic variations in the H, D and Z elements are determined for the observatories at Sabhawala and Hyderabad. Also included are similar results for Alibag with the main lunar terms separated into parts of oceanic and ionospheric origin. The data used are the alternate hourly mean values of H, D and Z for locally selected quiet days during the IQSY period, 1964–66. The predominances of the first lunar harmonic of H at Sabhawala and Alibag, and of the second solar harmonic at Sabhawala, are pointed out and discussed. The ratios of the seasonal ranges of both L and S to the respective annual mean ranges are found relatively enhanced in two of the seasons, in comparison with. the average global values for these latitudes for the IGY/C (sunspot maximum) period. This would indicate an inverse relationship of these ratios with solar activity. 相似文献
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Summary. Horizontal and vertical intensity data, obtained between 1957.0 and 1961.0 at 69 observatories, are analysed to determine the worldwide distribution of the annual variation of the geomagnetic field. Only data observed near local midnight are used, to avoid the small, but significant contamination from Sq. Over most of the world the variation is found to be small, with a clear dependence on latitude, but near the poles it is larger and more erratic. The non-polar variation is subjected to spherical harmonic analysis and separated into parts of internal and external origin. The polar variations are shown to be consistent with a north—south oscillation of the mean position of the auroral electrojets during the year. It is suggested that, with the exception of the polar effect, the annual variation is not due to ionospheric currents (as was hitherto believed), but results from an annual variation in the latitude of the ring current. 相似文献
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J. Hanumath Sastri 《Geophysical Journal International》1982,71(1):187-197
Summary. From a study of 'abnormal quiet days' (AQDs) at equatorial latitudes it was found earlier (Sastri) that the occurrence of an abnormal Sq ( H ) phase confined to the equatorial electrojet belt is closely associated with the incidence of complete or partial counter-electrojet (CEJ) conditions (marked daytime depressions in the H field in the electrojet region) for about 5 hr around the normal time interval of the diurnal maximum of the H field. In this paper, we investigate the causative mechanism of the Sq ( H ) phase variability on 'normal quiet days' (NQDs), defined as days on which the diurnal maximum of the H field occurs in the time interval 0930-1230 LT, in the equatorial electrojet belt using published geomagnetic data of stations in the Indian equatorial region. It is found that much of the phase variability of Sq ( H ) on NQDs may be caused by the influence of southward (negative) perturbation fields in the H component, similar in nature to those associated with AQDs but of a much smaller amplitude, close to the usual time of the diurnal maximum of the H field. The perturbation fields are noticed to be essentially of the ionospheric dynamo region origin. Possible mechanisms that might give rise to the observed perturbation fields are discussed. 相似文献