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1.
地球自转长期变化非潮汐机制之一 总被引:2,自引:0,他引:2
地球自转的长期减慢一般归为日月潮汐摩擦,根据古代日月食的记载及珊瑚类生物生长线的研究,可估算地球自转慢为每世纪2.4ms左右的日长变化,但是,潮汐摩擦并不是减速的唯一机制,还要考虑其它非潮汐因素,本试图考虑太阳风和磁层的相互作用,分析地球磁层中的磁力线在背阳面,由于地球自转引起磁力线压缩与稀疏,产生附加磁压力而引起的力矩对地球自转长期变化的影响,结果表明:这一非潮汐变化机制引起的角加速度约为w= 相似文献
2.
太阳风对地球自转可能影响的讨论 总被引:1,自引:0,他引:1
顾震年 《中国科学院上海天文台年刊》1989,(10):23-28
地球自转的长期减速原因一般归结为日-月潮汐摩擦,而非潮汐因素会引起地球自转的加速。本计算了由太阳风引起的地球磁层力矩的上限值,其量级为2.56×10^22cm sec^-2。结果表明:估算非潮汐加速度的量级为·/Ω=0.33×10^22cm sec^-2,它比推算出的·/ΩNT=1.6×10^22cm sec^-2要小。由于造成地球自转变化的非潮汐因素是一个经典而又复杂的问题,所以由太阳风引起的地球磁层的力矩作为非潮汐变化的机制是模棱两可的,但它表明:太阳风力矩可通过太阳风舆到地球并渗透到地核响应地核运动,因此它可以作为本计算的几千年时间尺度的地磁场向西漂移的最可能原因之一。 相似文献
3.
对太阳活动和太阳风影响地球自转的研究现状作了评述。首先了地球自转变化的表示和测定方法,引起地球自转变化的各种扰动源以及自转长期变化中的潮汐效应和非潮汐效应。然后对地球自转变化中的太阳活动周期调制,太阳耀斑可能引起地球自转突然减速以及太阳风能否影响地球自转等问题的国内外研究现状和结果、分析作了谰论性阐述,最后作了简要总结。 相似文献
4.
由地震引起地球内部质量重新分布将影响地球惯量矩的变化,从而引起地球自转速率的变化,即日长的变化。一般说,大地震产生大的附加位移场。它对地球自转特性有较强的影响。本文采用Harvard目录中1977-1994年间的地震有关参数,和根据地震激发地球自转的变化理论及Dahlen和Lam-beck推出有关公式计算了地震引起地球轴向惯量矩的变化。结果表明:由单个地震引起的日长变化要比观测值小几个量级,它的累积效应表现出长期的变化即日长减小,就是地震活动加速地球自转。地震使地球自转能量随时间稳定地增加。并表明,虽地震活动影响日长,但它不是十年尺度变化的主要原因,它可能是地球自转非潮汐加速机制之一 相似文献
5.
月日潮汐摩擦和地球惯量矩变化是日长长期变化的主要原因.在本文中,利用最新的地球物理和古生物钟数据,对过去15亿年以来的月日潮汐摩擦、地球惯量矩变化和日长长期变化等作了数值对比研究.由此得到二个重要结论:一是仅利用地球的自转形变不能解释J2的变化,这说明地球的重力分异现象至今仍存在着;其二是在几亿年前的潮汐摩擦比现在大得多,若取潮汐耗散与距离的立方成反比时,理论结果与由古生物钟得到的回归年日数和朔望月日数数据较为符合。 相似文献
6.
地球自转变化非潮汐项的冰期后地壳反弹解释 总被引:6,自引:0,他引:6
本文采用地球上四个最大的冰帽参数,计算了冰帽的融化对地球转动惯量的影响.根据冰期后地壳反弹理论,由现代天体测量空间技术观测资料分析得到的地球自转变化非潮汐项,估计给出了基于1066B地球模型的下地幔粘性系数为1.35×10(22)≥V(LM)≤1.91×10(22)Pas.结果表明,用冰期后的地壳反弹理论和上述的地球下地幔粘性系数基本可以解释现代空间技术观测得到的地球自转变化中的非潮汐项. 相似文献
7.
简要说明了天文地球动力学范畴内所研究的潮汐现象,包括由日月引潮力引起的固体潮、海洋潮、大气潮和由于地球自转轴的极移引起的极潮,以及这些潮汐对地球自转和地球自转的测量产生的效应。重点阐述中国天文学界在这一领域里的研究成果。这些研究涉及潮汐影响地球自转的机制,也就是各种潮汐效应与极移、自转速率变化和章动的关系,包括构建这类关系的理论模型,分析潮汐对它们的影响,利用中国古代丰富的天象记录计算地球自转的长期减慢,计算弹性或滞弹地球的洛夫数,依据某一地球模型计算潮汐效应或章动序列等等。研究也涉及在测量地球自转参数的不同技术中各种潮汐效应对测量结果产生的影响及其改正,并涉及与潮汐有关的观测方法的优化和数据处理过程的改进。最后介绍了中国学者所发现的脉冲星的周期和周期变率测量中的潮汐效应,尽管它们的量级甚微,但不容忽视。 相似文献
8.
地球自转速率的潮汐变化可由无量纲参数k/Cm)(k和Cm分别为壳幔的有效Love数和有效板转动惯量)来表征。对于一个具有弹性地幔、平衡海潮和核幔不耦合的地球k/Cm=0.944,且与潮波频率无关。海潮的非平衡扰动使k/Cm为复数,且与频率有关。大气对自转速率有效勒夫数的贡献约为△kat=0.0075。同时地幔滞弹性对勒夫数也产生扰动。利用本文得到的理论公式和最新的潮汐数据计算了地球自转速率的潮汐变化,及其有关地球物理机制的影响。 相似文献
9.
本文采用最新的卫星激光测距资料给出的地球二阶力学形状因子长期变化J2和月球平均运动的变化率nm,计算了地球自转变化中的非潮汐影响,并与有关作者的研究结果进行了比较。结果表明,近代空间观测技术能很有效地检测到地球自烨中的非潮汐因素的影响。本文还对地球最大主转动惯量C的长期变化作了估计。 相似文献
10.
杨志根 《中国科学院上海天文台年刊》1996,(17):57-61
本认为目前南极和格陵兰冰帽正处于冰积过程的观点存在较大的不可靠性;在讨论地球自转变化的非潮汐项时,仅考虑南极和格陵兰冰帽的变化是欠合理的;非潮汐项的影响可能主要来自冰期后的地壳反弹。 相似文献
11.
L. S. Marochnik 《Astrophysics and Space Science》1983,89(1):61-75
The solar system's position in the Galaxy is an exclusive one, since the Sun is close to the corotation circle, which is the place where the angular velocity of the galactic differential rotation is equal to that of density waves displaying as spiral arms. Each galaxy contains only one corotation circle; therefore, it is an exceptional place. In the Galaxy, the deviation of the Sun from the corotation is very small — it is equal to ΔR/R ⊙≈0.03, where ΔR=R c ?R ⊙,R c is the corotation distance from the galactic center andR ⊙ is the Sun's distance from the galactic center. The special conditions of the Sun's position in the Galaxy explain the origin of the fundamental cosmogony timescalesT 1≈4.6×109 yr,T 2?108 yr,T 3?106 yr detected by the radioactive decay of various nuclides. The timescaleT 1 (the solar system's ‘lifetime’) is the protosolar cloud lifetime in a space between the galactic spiral arms. The timescaleT 2 is the presolar cloud lifetime in a spiral arm.T 3 is a timescale of hydrodynamical processes of a cloud-wave interaction. The possibility of the natural explanation of the cosmogony timescales by the unified process (on condition that the Sun is near the state of corotation) can become an argument in favour of the fact that the nearness to the corotation is necessary for the formation of systems similar to the Solar system. If the special position of the Sun is not incidental, then the corotation circles of our Galaxy, as well as those of other galaxies, are just regions where situations similar to ours are likely to be found. 相似文献
12.
Yoshio Kubo 《Celestial Mechanics and Dynamical Astronomy》1982,26(1):97-112
Perturbations in the motion of the Moon are computed for the effect by the oblateness of the Earth and for the indirect effect of planets. Based on Delaunay's analytical solution of the main problem, the computations are performed by a method of Fourier series operation. The effect of the oblateness of the Earth is obtained to the second order, partly adopting an analytical evaluation. Both in longitude and latitude are found a few terms whose coefficient differs from the current lunar ephemeris based on Brown's theory by about 0.01. While, concerning the indirect effect of planets, several periodic terms in the current ephemeris seem to have errors reaching 0.05.As for the secular variations of
and due to the figure of the Earth and the indirect effect of planets, the newly-computed values agree within 1/cy with Brown's results reduced to the same values of the parameters. Further, the accelerations in the mean longitude,
and caused by the secular changes in the eccentricity of the Earth's orbite and in the obliquity of the ecliptic are obtained. The comparison with Brown shows an agreement within 0.3/cy2 for the former cause and 0.02/cy2 for the latter. An error is found in the argument of the principal term for the perturbations due to the ecliptic motion in the current ephemeris.Proceedings of the Conference on Analytical Methods and Ephemerides: Theory and Observations of the Moon and Planets. Facultés universitaires Notre Dame de la Paix, Namur, Belgium, 28–31 July, 1980. 相似文献
13.
E. L. Ruskol 《Earth, Moon, and Planets》1973,6(1-2):190-201
It is suggested that the overall early melting of the lunar surface is not necessary for the explanation of facts and that
the structure of highlands is more complicated than a solidified anorthositic ‘plot’. The early heating of the interior of
the Moon up to 1000K is really needed for the subsequent thermal history with the maximum melting 3.5 × 109 yr ago, to give the observed ages for mare basalts. This may be considered as an indication that the Moon during the accumulation
retained a portion of its gravitational energy converted into heat, which may occur only at rapid processes. A rapid (t < 103 yr) accretion of the Moon from the circumterrestrial swarm of small particles would give necessary temperature, but it is
not compatible with the characteristic time 108 yr of the replenishment of this swarm which is the same as the time-scale of the accumulation of the Earth. It is shown that
there were conditions in the circumterrestial swarm for the formation at a first stage of a few large protomoons. Their number
and position is evaluated from the simple formal laws of the growth of satellites in the vicinity of a planet. Such ‘systems’
of protomoons are compared with the observed multiple systems, and the conclusion is reached that there could have been not
more than 2–3 large protomoons with the Earth. The tidal evolution of protomoon orbits was short not only for the present
value of the tidal phase-lag but also for a considerably smaller value.
The coalescence of protomoons into a single Moon had to occur before the formation of the observed relief on the Moon. If
we accept the age 3.9 × 109 yr for the excavation of the Imbrium basin and ascribe the latter to the impact of an Earth satellite, this collision had
to be roughly at 30R, whereR is the radius of the Earth, because the Moon at that time had to be somewhere at this distance. Therefore, the protomoons
had to be orbiting inside 20–25R, and their coalescence had to occur more than 4.0x109 yr ago. The energy release at coalescence is equivalent to several hundred degrees and even 1000 K. The process is very rapid
(of the order of one hour). Therefore, the model is valid for the initial conditions of the Moon. 相似文献
14.
15.
In this paper we first emphasize why it is important to know the successive zonal harmonics of the Sun's figure with high
accuracy: mainly fundamental astrometry, helioseismology, planetary motions and relativistic effects. Then we briefly comment
why the Sun appears oblate, going back to primitive definitions in order to underline some discrepancies in theories and to
emphasize again the relevant hypotheses. We propose a new theoretical approach entirely based on an expansion in terms of
Legendre's functions, including the differential rotation of the Sun at the surface. This permits linking the two first spherical
harmonic coefficients (J
2 and J
4) with the geometric parameters that can be measured on the Sun (equatorial and polar radii). We emphasize the difficulties
in inferring gravitational oblateness from visual measurements of the geometric oblateness, and more generally a dynamical
flattening. Results are given for different observed rotational laws. It is shown that the surface oblateness is surely upper
bounded by 11 milliarcsecond. As a consequence of the observed surface and sub-surface differential rotation laws, we deduce
a measure of the two first gravitational harmonics, the quadrupole and the octopole moment of the Sun: J
2=−(6.13±2.52)×10−7 if all observed data are taken into account, and respectively, J
2=−(6.84±3.75)×10−7 if only sunspot data are considered, and J
2=−(3.49±1.86)×10−7 in the case of helioseismic data alone. The value deduced from all available data for the octopole is: J
4=(2.8±2.1)×10−12. These values are compared to some others found in the literature.
Supplementary material to this paper is available in electronic form at http://dx.doi.org/10.1023/A:1005238718479 相似文献
16.
B. P. Kondratyev 《Solar System Research》2013,47(1):1-10
A two-component theoretical model of the physical libration of the Moon in longitude is constructed with account taken of the viscosity of the core. In the new version, a hydrodynamic problem of motion of a fluid filling a solid rotating shell is solved. It is found that surfaces of equal angular velocity are spherical, and a velocity field of the fluid core of the Moon is described by elementary functions. A distribution of the internal pressure in the core is found. An angular momentum exchange between the fluid core and solid mantle is described by a third-order differential equation with a right-hand side. The roots of a characteristic equation are studied and the stability of rotation is proved. A libration angle as a function of time is found using the derived solution of the differential equation. Limiting cases of infinitely large and infinitely small viscosity are considered and an effect of lag of a libration phase from a phase of action of an external moment of forces is ascertained. This makes it possible to estimate the viscosity and sizes of the lunar fluid core from data of observations. 相似文献
17.
M. V. Samokhin 《Astrophysics and Space Science》1979,62(1):159-183
In order to understand the reason of the existence of the electric field in the magnetosphere, and for the theoretical evaluation of its value, it is necessary to find the solution of the problem of determination of the magnetosphere boundary form in the frameworks of the continuum medium model which takes into account part of the magnetospheric plasma movement in supporting the magnetospheric boundary equilibrium. A number of problems for finding the distribution of the pressure, the density, the magnetic field and the electric field on the particular tangential discontinuity is considered in the case when the form of discontinuity is set (the direct problem) and a number of problems for finding the form of the discontinuity and the distribution of the above-mentioned physical quantities on the discontinuity is considered when the law of the change of the external pressure along the boundary is set (for example, with the help of the approximate Newton equation). The problem which is considered here, which deals with the calculation of the boundary form and with the calculation of the distribution of the corresponding physical quantities on the discontinuity of the 1st kind for the compressible fluid with the magnetic field with field lines which are perpendicular to the plane of the flow in question, concerns the last sort of problems. The comparison of the results of the calculation with the data in the equatorial cross-section of the magnetosphere demonstrates that the calculated form of the boundary, the value of the velocity of the return flow and the value of the electric field on the magnetopause, agree satisfactorily with the observational data. 相似文献
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