太阳磁场磁性指数异常变化对南北半球中纬度气候的影响   总被引：14，自引：1，他引：13       下载免费PDF全文

曲维政  邓声贵  黄菲  陈璐  赵雪 《地球物理学报》2004,47(3):398-404

本文参照太阳黑子相对数特征建立了太阳黑子磁场磁性指数时间序列. 大气温度场谱分析结果显示,南北半球中纬度平流层和对流层大气温度场普遍存在22年变化周期. 分析认为,大气温度场的22年变化周期是太阳活动22年磁性周期所激发.  相似文献   

磁层顶高纬边界层的瞬时重联过程          下载免费PDF全文

刘振兴  濮祖荫 《地球物理学报》1995,38(2):141-149

用二维可压缩的ＭＨＤ模型模拟研究了北半球背阳面磁层顶区的瞬时重联过程．结果表明，当行星际磁场（ＩＭＦ）具有南向Ｂｚ分量和背太阳向Ｂｘ分量时，ＩＭＦ与地磁场联接，磁层顶向外扩张，在等离子体幔区可形成流体旋涡，磁力线被扭曲，但不易形成磁涡旋；当ＩＭＦ具有北向Ｂｚ分量时，不论Ｂｘ分量是背向太阳或指向太阳，都可发生瞬时重联，而且当ＩＭＦＢｘ分量与地磁场Ｂｘ分量反向时，在等离子体幔区更易形成磁涡旋．这两种情况，在磁层顶边界层区都能产生多层的电流片．  相似文献   

太阳黑子磁场极性指数时间序列   总被引：3，自引：0，他引：3       下载免费PDF全文

曲维政  秦婷  邓声贵  杜凌 《地球物理学进展》2008,23(6):1727-1735

本文根据苏黎世天文台太阳黑子11年周期资料和太阳黑子磁场磁性变化周期特征,构建了太阳黑子磁场磁性指数IM(Magnetic Index)时间序列,用IM(i)表示.为了便于采用数学方法研究太阳黑子磁场磁性指数变化与诸多地球物理现象之间的联系,本文给出了1749～2007年月平均太阳黑子磁场磁性指数时间序列数据.  相似文献   

行星运动与太阳自转角速度22年周期变化     

刘复刚  王建  白世彪  商志远 《地球物理学进展》2013,28(4)

Tlatov(2007)研究认为,太阳活动和太阳磁场变化的22年周期,可能与太阳自转速度的变化有关.可是关于太阳自转速度为什么呈现出22年的变化周期,尚未见到有说服力的解释.本文通过对行星会合指数、行星系质心绕太阳系质心的运动、太阳绕太阳系质心运动以及太阳自转角动量变化的分析,发现行星系统的会合与相互背离,导致了太阳系质心与太阳质心的背离和靠近,从而引发太阳绕太阳系质心旋转角动量与太阳自转角动量的分离与叠加.由此认为,这两种角动量间的转换是太阳自转角速度呈现22年周期性变化的原因.太阳自转速度极小值对应于行星会合指数极大值;而太阳自转速度极大值对应行星会合指数极小值.其中平均11年左右为太阳自转加速期,另外11年则为太阳自转减速期.这一发现,可能为太阳活动与太阳磁场变化22年周期的成因机制的解释提供一个新的线索.  相似文献   

K-H不稳定性在多电流片系统磁场重联中的效应   总被引：1，自引：0，他引：1       下载免费PDF全文

张洪  沈超 《地球物理学报》1997,40(4):445-452

等离子体系统中存在两个或多个电流片时，电流片中发生的不稳定性可能会相互作用．行星际磁场北向时，背阳面碰层顶电流片与磁尾等离子体片之间可能发生相互作用，高纬边界层强烈的流场剪切可能促进磁场重联，产生磁层亚暴．本文运用二维可压缩磁流体模拟研究具有强流场剪切的多个电流片系统中磁场重联的演化．结果表明，Kelvin－Helmholtz不稳定性使多电流片系统的磁场重联过程明显加快；相邻电流片之间的距离越近，两者相互作用越强，重联增长率越大；在三电流片系统中，超Alfven速度强流场导致外侧两个电流片中出现强烈的磁场重联，并引发中心电流片的磁场重联．行星际磁场北向时，也可能发生磁层亚暴．  相似文献   

北极涛动低空大气环流特征及其与太阳活动的联系          下载免费PDF全文

曲维政  李艳芳  李春  杜凌  黄菲 《地球物理学报》2014,57(5):1377-1386

通过北极涛动AO正负位相时期北半球1000 hPa月平均位势高度、位势高度距平和气温月距平图对比分析可知,北极区域异常增暖时期对应着AO负位相时期,而北极区域异常偏冷时期对应着AO正位相时期,说明北极区域气温异常变化是决定AO异常变化的重要因子.逐次滤波法分析可知,冬季1月北极涛动现象表现出十分清楚的与太阳活动密切联系的准110a世纪周期和准22a年代际周期,具体表现为：（1）冬季1月北极涛动现象具有十分清楚的与太阳活动密切联系的准110a世纪周期.准110a世纪周期对于北极涛动指数的方差贡献率达到44.4%,是冬季1月北极涛动现象最显著的世纪际变化特征.（2）谱分析结果表明,滤除准110a世纪周期变化以后的1月北极涛动指数具有显著的22a周期,其方差贡献率达到18.5%,乃仅次于准110a世纪周期之后北极涛动指数年代际变化重要特征.对比分析表明,太阳活动尤其是太阳磁场磁性指数变化与1月北极涛动22a周期变化呈密切的反相关关系,二者变化趋势基本相反,即多数情况当太阳磁性指数MI由最低值转为上升以后都可引起北极涛动AO由最高值转为下降;当太阳磁性指数MI由最高值转为下降以后都可引起北极涛动AO由最低值转为上升.综上所述,北极涛动的准110a世纪周期变化、22a年代际周期变化对于北极涛动方差贡献率达到62.9%,标志着太阳活动是北极涛动的重要驱动因子.  相似文献   

行星际磁场By分量对地球磁层顶场向电流调制   总被引：5，自引：2，他引：5       下载免费PDF全文

曹晋滨  马志伟  路立  周国成  刘振兴 《地球物理学报》2003,46(2):156-161

采用三维可压缩MHD数值模拟研究了行星际磁场By分量的变化对磁层顶重联区场向电流大小和分布的影响. 行星际磁场通过模拟区x=-Lx处左边界条件By来影响重联过程，从而改变重联区的场向电流. 研究结果表明边界条件By的突然改变，能使重联区场向电流迅速增加，甚至达到增大一个量级的水平.By本身的存在(即不为零)也会使场向电流维持在一个较高的水平. 由于行星际磁场By分量不为零，而形成模拟区磁场By不对称分布，这种不对称分布是场向电流不对称分布产生的主要原因. 这些结果是与Orsted卫星最新观测结果和地 面观测结果相符合的，它表明行星际磁场By分量对地球空间场向电流有较大的调制作用.  相似文献   

太阳活动Hallstatt周期及太阳活动周强弱变化的预测     

刘复刚  王建  鲍锟山  李广文  王治良 《地球物理学进展》2014,(4)

基于之前创建的行星会合指数运动学方程,发现太阳质心具有平均准22年向太阳系质心靠近(有时近似重合)的轨道运动周期.在整个太阳系角动量守恒的前提下,推出太阳自转角动量和太阳绕转角动量之和守恒.二者角动量转换造成太阳自转角动量变化和太阳绕转角动量变化具有互为反向的准22年变化规律.太阳自转角速度变化(dω/dt)图像与太阳黑子磁性指数图像具有一致对应关系,这种对应关系可以从物理机制上对太阳活动周相位变化和太阳活动强弱变化进行解释,这为预测太阳活动提供了一种有效方法.本研究为太阳活动替代性指标指代的双世纪周期和2403年哈尔斯塔(Hallstatt)周期规律找到了理论根据.  相似文献   

太阳活动千年尺度的准周期性波动          下载免费PDF全文

周广岩  韩延本  尹志强  马利华  韩永刚 《地球物理学进展》2007,22(2):446-450

2004年，Solanki等人利用树木年轮中δ14C含量变化重建的太阳黑子数序列研究太阳活动的论文被Nature发表，该黑子序列自1895年起向历史时期延伸了11400年.本文采用最大熵谱分析方法和小波变换方法分析了这一重建的太阳黑子序列，重点讨论太阳活动在千年尺度上的周期性波动.结果表明，太阳活动的长期变化中存在接近千年和略大于两千年的准周期信号，以及可能存在约7千年的波动，得到了这些准周期分量的参数.这些准周期分量的周期长度和振幅是随着时间变化的，文中给出了它们的时变图象并讨论了它们的时变特征.  相似文献   

火山活动对北半球平流层气候异常变化的影响   总被引：8，自引：0，他引：8       下载免费PDF全文

曲维政  黄菲  赵进平  邓声贵  杜凌  刘应辰 《地球物理学进展》2006,21(2):650-659

文中利用逐次滤波法滤除北半球平流层70 hPa约15~22 km高空大气温度异常变化中太阳活动的影响之后,进一步分析了火山活动的气候效应,分析结果表明,火山活动能引起平流层较大幅度增温,对于北半球70hPa高空气候异常变化的影响超过了总方差的30%;火山活动影响最显著的高度是平流层70 hPa约15~22 km高空,由此高度向上或向下,火山活动的影响都逐渐减小;火山活动引起平流层大气升温的同时还将引起对流层大气降温,其分界线大致位于对流层顶300 hPa附近;强火山爆发如皮纳图博火山爆发、阿贡火山爆发和堪察加北楮缅奴等火山爆发是引起未来两年左右平流层中下层温度异常变化最重要的因素,其方差贡献率超过百分之五十三！;火山喷发高度越高,引起平流层增温效应的层次也越高;北半球大气温度异常变化对南半球火山活动响应的滞后时间比北半球火山活动长. 平流层高空气候异常变化还具有显著的22年变化周期,分析认为是大气温度场对太阳磁场磁性周期22年异常变化的响应,其方差贡献率超过9%.  相似文献   

Comparative outline of the region of interaction of the solar wind with the Ionosphere of Venus and Mars     

H. Prez-de-Tejada 《Journal of Atmospheric and Solar》2005,67(17-18):1786

The general features of the region of interaction of the solar wind with the ionosphere of Venus and Mars are compared using data obtained with the Mariner 5 and the Pioneer Venus Orbiter (PVO) spacecraft for Venus and with the Phobos II, the Mars Global Surveyor (MGS) and the Mars Express spacecraft for Mars. Despite the overall weak intrinsic global magnetic field that is present in both planets there are significant differences in the manner in which the interplanetary magnetic field accumulates and is organized around and within their ionosphere. Such differences are unrelated to the crustal magnetic field remnants inferred from the MGS measurements around Mars. In fact, while in Venus and Mars there is a region in which the magnetic field becomes enhanced as it piles up in their plasma environment it is shown that such a region exhibits different regimes with respect to changes in the ion composition measured outside and within the ionosphere. At Venus the region of enhanced magnetic field intensity occurs in general above the ionopause which represents the boundary across which there is a change in the ion composition with dominant solar wind protons above and planetary O⁺ ions below. At Mars the region of enhanced magnetic field is located below a magnetic pileup boundary across which there is also a comparable change in the ion composition (solar wind protons above and planetary O⁺ ions below). It is argued that this difference in the relative position of the region of enhanced magnetic field with respect to that of a plasma boundary that separates different ion populations results from the peculiar response of the ionosphere of each planet to the oncoming solar wind dynamic pressure. While at Venus the peak ionospheric thermal pressure is in general sufficient to withhold the incident solar wind kinetic pressure there is a different response in Mars where the peak ionospheric thermal pressure is in general not large enough to deviate the solar wind. In this latter case the ionosphere is unable to force the solar wind to move around the ionosphere and as a result the oncoming electron population can reach low altitudes where it is influenced by neutral atmospheric particles (the solar wind proton population is replaced at the magnetic pileup boundary which marks the upper extent of the region where the interplanetary magnetic field becomes enhanced). Peculiar conditions are expected near the magnetic polar regions and over the terminator plane where the solar wind is directed along the sides of the planet.  相似文献   

Solar polar magnetic field     

E. E. Benevolenskaya 《Geomagnetism and Aeronomy》2013,53(7):891-895

The solar polar magnetic field has attracted the attention of researchers since the polar magnetic field reversal was revealed in the middle of the last century (Babcock and Livingston, 1958). The polar magnetic field has regularly reversed because the magnetic flux is transported from the sunspot formation zone owing to differential rotation, meridional circulation, and turbulent diffusion. However, modeling of these processes leads to ambiguous conclusions, as a result of which it is sometimes unclear whether a transport model is actual. Thus, according to the last Hinode data, the problem of a standard transport model (Shiota et al., 2012) consists in that a decrease in the polar magnetic flux in the Southern Hemisphere lags behind such a decrease in the flux in the Northern Hemisphere (from 2008 to June 2012). On the other hand, Svalgaard and Kamide (2012) consider that the asymmetry in the sign reversal simply results from the asymmetry in the emerging flux in the sunspot formation region. A detailed study of the polar magnetic flux evolution according to the Solar Dynamics Observatory (SDO) data for May 2010–December 2012 is illustrated in the present work. Helioseismic & Magnetic Imager (HMI) magnetic data in the form of a magnetic field component along the line of sight (the time resolution is 720 s) are used here. The magnetic fluxes in sunspot formation regions and at high latitudes have been compared.  相似文献   

基于SWARM双星观测的场向电流的经度变化          下载免费PDF全文

王慧  郑志超  Hermann Luehr 《地球物理学报》2019,62(2):447-461

本文利用SWARM A和C双星高精度的矢量磁场数据研究了不同季节高纬地区场向电流(FACs)随地磁经度和地方时的变化情况.研究发现:在南北半球,FACs存在明显的经度变化,南半球FACs的变化强度大约是北半球的1.2～3.2倍.利用潮汐谱分析法我们发现FACs中占主导的非迁移潮汐分量为DW2和D0.在春秋和夏季半球,DW2波更为明显.D0波可用太阳光照的经度变化来解释,向阳侧靠近磁极的经度带比远离磁极的经度带有更强的太阳光照射.DW2波则与地磁场强度和地磁倾角等因素有关.全球电离层与热层模型计算的FACs中D0波占主导,且中性风和对流电场对D0波的贡献几乎相当.  相似文献   

Nonzonal structure of the response of the global field of the Earth’s atmospheric temperature to solar activity     

A.?A.?KrivolutskyEmail author  A.?V.?Dement’eva 《Geomagnetism and Aeronomy》2017,57(1):107-112

The work describes the results of calculations obtained with the Atmospheric Research Model (ARM) general circulation model. The temperature response of the troposphere and middle atmosphere to variations in UV solar radiation were found to have a large-scale wave structure when planetary waves at the lower model boundary were taken into account. In the present paper, the results from the processing of global temperature fields with three databases (ERA-20C, NOAA-CIRES 20th Century Reanalysis, v2, and NCEP/NCAR Reanalysis I) are provided. Analysis of the differences of the mean monthly temperature global fields (January and July) between the maxima and minima of three solar activity cycles (21, 22, and 23 cycles) also demonstrated their nonzonal structure. It was shown that the amplitude of this difference in January in the stratosphere (10 hPa) can be 7–29 K in the Northern Hemisphere. In July, this effect is prominent in Southern Hemisphere. In the troposphere (500 hPa), a nonzonal temperature effect is present in both the Northern and Southern Hemispheres; the amplitude of the effects amounts to approximately 5–12 K. In conclusion, we discuss that the mechanism of solar energy impact on atmospheric temperature discovered by numerical modeling is supported after reanalysis data processing.  相似文献   

冬季太阳11年周期活动对大气环流的影响   总被引：2，自引：0，他引：2       下载免费PDF全文

刘毅  陆春晖 《地球物理学报》2010,53(6):1269-1277

利用气象场的再分析资料和太阳辐射活动资料,对太阳11年周期活动影响北半球冬季(11月~3月)大气环流的过程进行了统计分析和动力学诊断.根据赤道平流层纬向风准两年振荡(QBO)的东、西风状态对太阳活动效应进行了分类讨论,结果表明：东风态QBO时,太阳活动效应主要集中在赤道平流层中、高层和南半球平流层,强太阳活动时增强的紫外辐射加热了赤道地区的臭氧层,造成平流层低纬明显增温,同时加强了南半球的Brewer-Dobson(B-D)环流,引起南极高纬平流层温度增加;而北半球中高纬的环流主要受行星波的影响,太阳活动影响很小.西风态QBO时,太阳活动效应在北半球更为重要,初冬时强太阳活动除了加热赤道地区臭氧层外,还抑制了北半球的B-D环流,造成赤道平流层温度增加和纬向风梯度在垂直方向的变化,从而改变了对流层两支行星波波导的强度;冬末时在太阳活动调制下,行星波向极波导增强,B-D环流逐渐恢复,造成北半球极地平流层明显增温,同时伴随着赤道区域温度的下降.  相似文献   

Spatial pattern of photospheric granules in a sunspot neighborhood     

Ernesto R. Rodríguez Flores  Rafael Gmez Díaz  Ramn E. Rodríguez Taboada 《Journal of Atmospheric and Solar》2005,67(17-18):1728

Based on high-resolution (0.3 arcsec) observations, we studied the behavior of solar granulation in the neighborhood of a sunspot. The bright granules’ spatial distribution and the granules’ surface density as a function of distance from the center of the sunspot umbra were determined.Bright granules distribute delimiting cells of dimensions in the mesogranular scale. The mean diameter of these cells does not show significant variation with the variation of the magnetic field of the sunspot. The granules’ surface density does not show significant variation with distance to the sunspot umbra. Both results point to a very weak, if any, influence of the sunspot magnetic field at distances greater than 20 arcsec.  相似文献   

Stratospheric ozone response to a solar proton event: Hemispheric asymmetries     

Kaichi Maeda  Donald F. Heath 《Pure and Applied Geophysics》1980,119(1):1-8

Ozone depression in the polar stratosphere during the energetic solar proton event on 4 August 1972 was observed by the backscattered ultraviolet (BUV) experiment on the Nimbus 4 satellite. Distinct asymmetries in the columnar ozone content, the amount of ozone depressions and their temporal variations above 4 mb level (38 km) were observed between the two hemispheres. The ozone destroying solar particles precipitate rather symmetrically into the two polar atmospheres due to the geomagnetic dipole field These asymmetries can be therefore ascribed to the differences mainly in dynamics and partly in the solar illumination and the vertical temperature structure between the summer and the winter polar atmospheres. The polar stratosphere is less disturbed and warmer in the summer hemisphere than the winter hemisphere since the propagation of planetary wave from the troposphere is inhibited by the wind system in the upper troposphere, and the air is heated by the prolonged solar insolation. Correspondingly, the temporal variations of stratospheric ozone depletion and its recovery appear to be smooth functions of time in the (northern) summer hemisphere and the undisturbed ozone amount is slighily, less than that of its counterpart. On the other hand, the tempotal variation of the upper stratospheric ozone in the winter polar atmosphere (southern hemisphere) indicates large amplitudes and irregularities due to the disturbances produced by upward propagating waves which prevail in the polar winter atmosphere. These characteristic differences between the two polar atmospheres are also evident in the vertical distributions of temperature and wind observed by balloons and rocker soundings.  相似文献