对高层大气模式的研究

本文根据最近关于大气热力学参数的知識,討論了現代大气結构的模式。用基本靜力学方程由上向下进行数值积分的方法,由大气密度的卫星观测资料計算了热大气层中的分子溫度随高度的分布。从大气分子溫度的誤差估算表明,积分根本不能由下而上进行,相反地,由上而下的数值积分法可以大大減小計算誤差。用由下而上的逐层逼近法,根据大气密度的卫星观測资料,計算了大气动力溫度随高度的分布,在这种运算中,并未对在热大气层中溫度随高度的垂直分布趋向做任何約束性的假定,只假設在120公里以上,大气处于扩散平衡状态,同时在小高度区間△z內,溫度和高度的关系是线性的。計算結果証明,在热大气层中并未出現等溫区,溫度随高度的加大有上升的趋势。     

計算有效速度的“积分法”

在現代的地震勘探中,主要是利用地震波的运动学特点,来勘探地壳的地貭构造的. 地震勘探結果的精确度,在很大程度上与平均速度的选择有关。目前,在我国的很多地区內,深探井較少,速度资料主要还要依靠有效速度的計算来获得.显然,如何根据反射波时距曲綫准确地計算有效速度,仍然是現代地震勘探中的一个重要課題.     

Gtz逆轉效应中I_(3112 )的有效散射高度上升过程的跳跃性及逆轉方法B解的不唯一性

本文探討了Gotz逆轉效应中,单色天頂散射光强I_3112（?）的有效散射高度h_E的上升过程。首先从理論上証明:h_E并非沿高度連續的上升,而是跳跃上升的。然后用实际观測数据的計算,証实了理論結果。由此并指出,由于h_E的跳跃,那么在应用逆轉效应,建立測定大气臭氧垂直分布方法时,如果将大气分层較多,那么可能在臭氧层中下部所得的結果,是不唯一的。基于上述結果,进一步研究了方法B,发現目前国际上通用的,由Ramanathan与Davo所給出的逆轉方法B的解是不唯的。这些解之間有着亘大的差异。因此以該方法計算出的各层臭氧含量,并不能肯定大气臭氧的垂直分布情况。     

太阳γ及β_γ黑子磁埸区大耀斑的地磁效应

本文研究了1938-1958年间,太阳γ及βγ黑子磁場区的3級与3~+級大耀斑的地磁效应。用相关及迴归分析法,計算了太阳赤緯、日軸方位角及耀斑的日面經緯度等因素对于磁扰的彭响。根据分析結果,繪出了日面地磁扰动等值图。利用水手2号飞船上量譜仪測出的太阳风速度和相应的地磁A_p指数,算出了相关关系,并用此和上述日面地磁扰动等值图配合,推算了在耀斑发生以后,太阳风的径向分量沿地球軌道的分布。参考文內各相应的曲线,可以約略估計出耀斑发生后地磁A_p指数的大小。     

短論——太阳活动对地磁場影响的南北不对称性

苏联Р.Γ.阿芬尼娜研究急始型磁暴的十一年出現頻数分布吋,发現1944-1959这两个太阳黑子活动周期內,急始型磁暴的頻数分布曲线与太阳北半球黑子面积的十一年变化曲线相似。     

磁暴主相期间外辐射带结构的变化

本文利用相对論带电粒子的两个寝渐不变量,討論了磁暴主相期間外輻射带中心結构的变化。作者认为磁暴主相是由“磁暴带”环电流所产生。“磁暴带”假設位于外輻射带中心之外,它是太阳等离子体穿入磁层后形成的。本文对初始能量W=20Kev和W=1Mev的电子分別进行了計算。 結果表明,在磁暴主相期間电子向外漂移,其赤道投擲角減小,但镜点离地面距离增高。因此,主相时所观測到的极光,并不是由于地磁場的平緩下降使小投擲角电子注入大气层而形成的。此外,計数率降低的主要原因是由于力管截面膨胀造成的粒子密度減小以及电子減速,而电子減速与投擲角有关,由此决定了电子通量沿磁力线分布的变化。以上結果与探险者6号（Explorer Ⅵ）的观測一致。     

磁铁温度系数及感应系数的测定

測定磁棒磁矩的溫度系数时,用了一个电流綫圈以抵消磁矩变化的影响,因而簡化了計算工作。測定磁棒的綫膨胀系数时,利用現有設备及一个比較簡单的装置,得到了相当准确的結果。測定磁棒感应系数使用的螺綫管（納尔逊法）中磁場的均勻性,在纵方向及横方向都作了核算,因而对它們的影响,能进一步加以估計。綫圈及其他磁强計附加装置也还准确而簡单易制。     

带电粒子穿入地磁場的一种机制（一）

自从辛格用輻射带內电性粒子运动所形成的电流环,成功地解释磁暴主相形成的机制以来,这些带电粒子的来源就成为磁暴主相理論的一个重要問題。本文以两度空間双曲线磁場,对带电粒子的軌道进行初步計算表明:由于貭子和电子的反射方向不同,在中性点附近可以形成由东向西的极化电場。在这个电場的作用下,带电粒子的飘移运动可以通过中性点穿入地磁层而被捕获。据初步估計,我們的計算与帕克尔等的理論結果相符,并可以解释磁暴主相。     

磁暴期間外輻射带結构的变化

本文根据磁矩守恆的条件,利用刘維定理（Liouville's theorem）,討論了磁暴期間在赤道平面外輻射带內,带电粒子的空間分布及能量分布的变化。結果表明:当主相时,粒子密度及通量的峯值变小而且位置向外移动。此結果与探測事实相符。能譜分布也有显著的变化,不論垂直能量或是平行能量,当主相时能量分布的峯值向低能量的方向偏移;急始时向高能量的方向偏移。对投擲角及鏡点高度作了計算,发現当急始时投擲角变大,而鏡点高度下降;主相吋投擲角变小,镜点高度上升。由此可以訊为,在主相期間緩慢的磁場下降,不能使外輻射带內粒子侵入上层大气。相反,在急始时則可能有一部分粒子会侵入上层大气。根据所得結果,基本上可以解释目前的观測現象。     

地球的密度

一.引言地球的密度是一個經典的問題。在十九世紀的時候,這個問題似乎已經相當圆滿地解决了,但是五十多年來,地球物理研究的結果,使這個問題又重新轉入了一個新階段;特別是關於地球內部的密度分佈,前人的計算,須要基本的修正。這     

磁暴与大地震的跨越式关系探讨

研究磁暴与磁暴、磁暴与月相、磁暴与大地震、大地震与大地震之间的跨越式关系，它们与日、月、地三体相对位置变化有关。论证１９８８年１１月３０日磁暴与其后发生的磁暴和大地震的跨越式关系具明显的有序性，其中多数为月球的朔望月、交点月的公倍数，后者还表现为相邻的素数数列。看来，一些磁暴与地震在成因上有密切联系     

Variations in the quasi-static electric field in the near-Earth’s atmosphere during geomagnetic storms in November 2004

The effects of the geomagnetic storms of November 8 and 10, 2004, in variations in the strength and power spectra of the electric field in the near-Earth’s atmosphere in Kamchatka were studied, together with the meteorological and geophysical phenomena observed simultaneously. A sequence of strong solar flares was shown to cause an anomalous increase in air temperature and humidity. This resulted in the excitation of anomalously strong thunderstorm processes in the atmosphere during the storm of November 8 and made it impossible to distinguish the effects associated with cosmic rays on this background. During the storm of November 10, on the background of weak variations in meteorological parameters, an increase in the strength and intensity of power spectra of the electric field on the day before the storm of November 10 was detected; it was followed by an attenuation of these parameters on the date of the storm. These effects were supposed to be associated with the action of cosmic rays on currents of the global electric circuit. It was shown that the influence of the Forbush effect of galactic cosmic rays in the power spectrum of the electric field first of all shows as the amplification of the component with the period T ～ 48 h; in variations in humidity, the effect shows as the amplification of the component with T ～ 24 h. Cause-and-effect relationships between variations in the electric field strength and the horizontal component of the geomagnetic field were shown to be absent both under the conditions of “fair weather” and during the storm of November 10. A diurnal negative-difference atmospheric pressure was detected on the second day after the geomagnetic storms of November 8 and 10.     

Variations in the critical frequency of the ionospheric F-region during magnetic storms in 2008–2012 at auroral latitudes

Fifty-one magnetic storms occurred during the last solar half-cycle of transition from the epoch minimum to the epoch maximum are considered. Ionospheric (foF2) and magnetic (X component) data from Sodankyla observatory, Finland, were used for the analysis, as well as values of the ΣKp indices of magnetic activity. The dependence of variations in the critical frequency foF2 was studied before, during, and after each storm. It has been revealed that a major effect (ME) takes place for all of the storms analyzed. It consists in the following: the first maximum in foF2 values occurs several days before the onset of the active phase of a storm, then foF2 attains its minimum during the active phase, and the second maximum occurred after the active phase. Five principals, the most frequent types of variation in foF2 during a storm, have been revealed. However, special cases (30%) in which an ME exists but shifts rightward several days along the time axis are observable. Ionospheric “memory” (inertia) from 8–9 h to 2 days has been revealed. It has been ascertained that the occurrence of the first ME maximum can be considered a magnetic storm precursor. Such a precursor potentially can be used for forecasting the beginning of magnetic storm development, which is important for space weather problems.     

甘肃嘉峪关、瓜州地电场日变化与地电暴差异机理分析

通过甘肃省嘉峪关台地磁场观测资料,研究嘉峪关台、瓜州台磁静日地电场日变化的时频特征波;由地电场分钟值观测数据的时序叠加残差方法,研究嘉峪关、瓜州山的地电暴变化。结果表明:(1)两台地电场静日变化以两次起伏变化为主,无相位差,但两台之间日变幅差异较大;(2)地电场分量变化与地磁场正交分量变化显著相关;地电场与地磁场日变波形不同,极值时间有差异。2个台存在很明显的高频成分,在去除了高频变化后,其优势周期也相同,从大到小依次为12 h、8 h、24 h。地磁场H分量因存在磁暴影响,故高频变化较多,在去除了磁暴影响后,其优势周期从大到小依次为24 h、12 h、8 h;(3)当电磁暴扰动剧烈时,两台可以较清晰地记录到地电暴的完整变化。在发生电磁暴时,地电场与地磁场的相关性明显降低,且不同台、不同测向之间的变化幅度也不尽相同。两台东分量E_Y暴日的日变幅较静日明显增大,磁暴期间Y分量变化率与地电场东分量E_Y观测数据显著相关,由此说明:两台日变幅的不同与台站台址电导率有关,太阳风引起的电离层活动是引起了地电场日变化主因。引起电暴的原因可能不同于引起日变化的原因,主要是两台之间及不同测向之间的浅、深层电阻率和地质构造等诸多因素的结果。     

Assessment of Impact of Storm on Point Source Pollutant Transport in Estuary by Dissolved Tracer Modeling

A continuously discharged dissolved conservative tracer was simulated with the Chesapeake Bay Estuary Model Package to study pollutant transport in the estuary in response to point source loads and the impact of the November, 1985 storm. A visualization technology is applied to show 3-dimensional concentration variations in a continuous daily time sequence. The differential responses of daily net transport during storms versus inter-storm periods can be observed from an MPEG movie. It may take 2–3 months for a tracer to travel from the fall-line to the mouth of a river during relatively dry seasons, only 2 weeks in some medium storms, and less than 5 days in a big storm. Plots of daily concentrations from eleven selected locations in the estuary provide quantitative information on the response of tracer concentration to flows. The magnitude and time of tracer peaks related with different weather events in these locations reflect the combined effects of flows from various directions to these locations. The lower tributaries (which are closer to the Bay mouth) are affected more than the upper tributaries by a source discharged at a mid-tributary. A storm can transport materials more effectively to the Bay and affect adjacent tributaries more severely.     

The ionosphere of Europe and North America before the magnetic storm of October 28, 2003

The X17 solar flare occurred on October 28, 2003, and was followed by the X10 flare on October 29. These flares caused very strong geomagnetic storms (Halloween storms). The aim of the present study is to compare the variations in two main ionospheric parameters (foF2 and hmF2) at two chains of ionosondes located in Europe and North America for the period October 23–28, 2003. This interval began immediately before the storm of October 28 and includes its commencement. Another task of the work is to detect ionospheric precursors of the storm or substorm expansion phase. An analysis is based on SPIDR data. The main results are as follows. The positive peak of δfoF2 (where δ is the difference between disturbed and quiet values) is observed several hours before the magnetic storm or substorm commencement. This peak can serve as a disturbance precursor. The amplitude of δfoF2 values varies from 20 to 100% of the foF2 values. The elements of similarity in the variations in the δfoF2 values at two chains are as follows: (a) the above δfoF2 peak is as a rule observed simultaneously at two chains before the disturbance; (b) the δfoF2 variations are similar at all midlatitude (or, correspondingly, high-latitude) ionosondes of the chain. The differences in the δfoF2 values are as follows: (a) the effect of the main phase and the phase of strong storm recovery at one chain differs from such an effect at another chain; (b) the manifestation of disturbances at high-latitude stations of the chain differ from the manifestations at midlatitude stations. The δhmF2 variations are approximately opposite to the δfoF2 variations, and the δhmF2 values lie in the interval 15–25% of the hmF2 values. The performed study is useful and significant in studying the problems of the space weather, especially in a short-term prediction of ionospheric disturbances caused by magnetospheric storms or substorms.     

宇宙线小波分析在大地磁暴预报中的应用

利用Morlet小波变换方法对北京宇宙线台站的地面宇宙线强度在地磁暴前后的变化特征进行分析,得到:1)在平静期,北京宇宙线数据存在准24h周期性的特征,且通过分析周期为12h的Morlet小波"模",发现值稳定,且小于0.6;2)以90天为时间窗口,对2004年7月地磁暴前后的小波频谱变化进行详细分析,发现当发生大地磁暴时,宇宙线的静日准24h周期被打破,其他周期的波动开始增强.进一步研究发现,周期12h的波动在大地磁暴数小时到1天左右会出现显著增强,这一现象在2001、2002和2004年期间的大地磁暴前得到验证.3)Morlet小波"模"数据的急速增大是发生地磁暴的先兆特征,当小波模变化达到一定的阈值就可能发生大磁暴.本文分析了周期为12h时小波的模数据,对强地磁暴事件进行统计,选定阈值0.6,并通过2003年的6次大地磁暴进行预报验证,结果表明该方法不仅能够对大地磁暴事件进行预报,而且提前量满足预报需求,为基于宇宙线实测数据预报地磁暴方法提供了重要基础.     

Extended main phase of some sudden commencement great geomagnetic storms with double SSCs

Hourly equatorial Dst (H) values for a few sudden commencement great geomagnetic storms recorded during the solar cycle 22 are plotted for 72 h of storm time and critically examined. Magnetic records taken at selected low latitude Indian stations are also scrutinised for finer details like SSCs, SIs and other fluctuations. Unusually prolonged main phases lasting more than 20 h characterize the two great storms of 13 March 1989 and 24 March 1991. A second SSC/SI pair, occurring some hours after the first main SSC, has also been identified in these storms. Only the great storm of 28 October 1991, with two SSCs and a main phase duration of 21 h, could be studied in conjunction with simultaneous interplanetary data, including Bz changes. Double negative Bz changes correlate well with the extended and enhanced main phase of this storm. Successive magnetic clouds preceded by interplanetary shock waves could generate such great magnetic storms in association with southward IMF changes.     

The superdense plasma sheet in the magnetosphere during high-speed-stream-driven storms: Plasma transport timescales

The superdense plasma sheet in the Earth's magnetosphere is studied via a superposition of multispacecraft data collected during 124 high-speed-stream-driven storms. The storm onsets tend to occur after the passage of the IMF sector reversal and before the passage of the stream interface, and the storms continue on for days during the passage of the high-speed stream. The superdense phase of the plasma sheet is found to be a common feature of high-speed-stream-driven storms, commencing before the onset of the storm and persisting for about 1 day into the storm. A separate phenomenon, the extra-hot phase of the plasma sheet, commences at storm onset and persists for several days during the storm. The superdense plasma sheet originates from the high-density compressed slow and fast solar wind of the corotating interaction region on the leading edge of the high-speed stream. Tracking the motion of this dense plasma into and through the magnetosphere, plasma transport times are estimated. Transport from the nightside of the dipole to the dayside requires about 10 h. The occurrences of both the superdense plasma sheet and the extra-hot plasma sheet have broad implications for the physics of geomagnetic storms.     

Indicators of an increase in the flux of relativistic electrons in geostationary orbit during geomagnetic storms

The relation of the fluxes of relativistic electrons in geostationary orbit during magnetic storms to the state of the magnetosphere and variations in the solar wind parameters is studied based on the GOES satellite data (1996–2000). It has been established that, in ～52–65% of all storms, the fluxes of electrons with energies higher than 0.6 and 2 MeV during the storm recovery phase are more than twice as high as the electron fluxes before a storm. It has been indicated that the probability of such cases is closely related to the prestorm level of fluxes and to a decrease in fluxes during the storm main phase. It has been found that the solar wind velocity on the day of the storm main phase and the geomagnetic activity indices at the beginning of the storm recovery phase are also among the best indicators of occurrence of storms with increased fluxes at the storm recovery phase.