The Effect of Tide on the Global Climate Change

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The Effect of Tide on the Global Climate Change

The differential rotation between the solid and fluid spheres caused by tidal force could explain the 1500 to 1800-year cycle of the world's temperature. Strong tide increases the vertical and horizontal mixing of water in the oceans, drawing the cold Pacific water from the depths to the surface and the warm water from the west to the east, where it cools or warms the atmosphere above, absorbs or releases CO2 to decrease or increase greenhouse effect and to make La Nina or El Nino occur in the global. The moon's declination and obliquity of the ecliptic affect the tidal intensity. The exchange of tidal energy and tide-generating force caused by the sun, moon and major planets makes the earth's layers rotate in different speeds. The differenti-al rotation between solid and fluid of the earth is the basic reason for El Nino and global climate change.     

Strong Tides in 1964 and 1982

The differential rotation between solid and fluid caused by tidal force can explain a 1500 to 1800-year cycle of the climate change. Strong tide increases the vertical and horizontal mixing of water in ocean by drawing the cold Pacific water from the depths to the surface (or by making the warm water flow from the West Pacific to the East as well as from the North to the South). It cools or warms the atmosphere above and makes La Nina or El Nino occur in the whole world. Astronomical data have shown that strong tide is often associated with El Nino events. Volcanic activities at submarine are also controlled by strong tide. Volcanic activities can also draw warm water from the depths to the surface in the Pacific and volcanic ash can keep out sunlight, which is the most important external forcing factor for El Nino. If volcanic ash reaches into the stratosphere, finer aerosols will spread throughout the globe during a few months and will float in it for one to three years to weaken the sun's direct radiation to the areas. It is one of the factors to postpone EI Nino just like the process of solar eclipse.     

Strong Tides in 1964 and 1982

1StrongtideandastronomicalconditionsPartial solar eclipse occurred 4 times in 1964, 1982 and 2000 respectively. Time interval is about 3 Saros periods (one Saros period is 18 years and 10.33～11.33 days). Total lunar eclipse occurred 2 times in 1964 and 2000 respectively and 3 times in 1982. However, there was no lunar eclipse in 1966, 1984 and 2002. It seems that they had similar astro-nomical conditions and the best was in 1982. The studies about the effect of tide on the global climate…     

The Latest Research Progress on El Ninod

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The Latest Research Progress on El Nino

Cold water in the deep Pacific can be drawn up to the surface (or west warm water drifts eastwards) because strong tide increases the mixing of seawater both in vertical and horizontal. In this way greenhouse effect is decreased or in-creased by means of absorbing (or releasing) CO2. Therefore, La Nina cold event (or El Nino warm event) may occur, which is caused by wanning - up or cooling - down air above the ocean. Volcanic action at sea bottom is also controlled by strong tide.     

The Latest Research Progress on El Nino

Cold water in the deep Pacific can be drawn up to the surface (or west warm water drifts eastwards ) because strong tide increases the mixing of seawater both in vertical and horizontal. In this way greenhouse effect is decreased or increased by means of absorbing (or releasing) CO2. Therefore, La Nina cold event (or El Nino warm event) may occur,which is caused by wanning - up or cooling - down air above the ocean. Volcanic action at sea bottom is also controlled by strong tide.     

Impact of the El Nino on the Variability of the Antarctic Sea Ice Extent

1　IntroductionManymeteorologistsandoceanographerspaidmuchattentiontothestudyofthemechanismofENSOformanyyears,suchasBjerknes(1 966) ,Wyrtki(1 975) ,McCreary(1 983 ) ,Philander(1 984) ,ZhangandChao(1 993 )andMcCPhaden(1 998)havemadegreatdevelopmentinthestudyofENSO .Especiallyinthe 1 990’s,withtheincreasingofthedatainthedeepocean ,thesomeonearguedthattheENSOepisodehadcloserelation shipwiththeeasterntransportationoftheanomalousseasurfacetemperatureinthewestPacific(LiandMu 1 999;Huang 2…     

陕西石泉井不同频带水位对气压和固体潮的响应特征

为揭示陕西石泉井不同频带水位对气压和固体潮的响应特征,采用频谱分析、相干函数和时移分析方法,对石泉井2015-11-01~2016-02-29的井水位、气压和理论重力固体潮等进行深入分析。结果表明,低频带（f＜0.5 cpd）井水位对气压响应较为一般且波动较大,对固体潮响应很差;中频带（0.5~8 cpd）井水位对固体潮响应很好,同时,对气压成分中的K1、S2和S3频点有较好的响应;高频带（f＞8 cpd）井水位与气压和固体潮的相干性均较差,这可能由于该频带井水位的信噪比较低和气压能量较弱等因素所致。此外,在全频带内,随着气压周期的增大,井水位的滞后时间也相应从1 min增至720 min;在中低频带的某些频点或频段,井水位对气压响应的时移存在超前和异常波动现象。
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The Relation between Tectonic Movement and Climatic Change

Climate and tectonics are two interactive factors in the earth's system. They are controlled by astronomical cycles. It has been unheeded for a long time that large-scale material motion caused by global climatic change is one of the powers for tectonic movement. Tectonic movement makes the distributional pattern of continent and ocean change and makes global climate type change strongly in large scale. It is a good example that the change of the sea-ice around Antarctic Continent and in the Drake Passage has the switch process for global climatic changes. Tide makes the oceanic crust of the East Pacific Ocean and the West Pacific Ocean rise or fall 60 cm oppositely. Before and after El Nino events,the oceanic level of the East Pacific Ocean and the West Pacific Ocean may rise or fall 40 cm oppositely. Because of isostasy, oceanic crust may fall or rise 13 or 20 cm. They are the reasons why El Nino events are interrelated with the earthquakes and volcanoes. This is so called seesaw phenomenon of oceanic crust.     

The Relation between Tectonic Movement and Climatic Change

1SeesawphenomenonofoceaniccrustSince 1996, Yoshino etal.(2002) have been us-ing the space geodetic techniques to observe crustal deformation at four sites in Tokyo metropolitan area. It is called Keystone project (KSP). At the end of June in 2000, volcanic and seismic events star-ted at Izu islands, south of Tokyo. Following the ev-ent, extraordinary crustal deformation was observed not only around the Izu islands, but also at the Key-stone network, where the closest site is over 100…     

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Analyzing the influences of two types of El Nino on Tropical Cyclone Genesis with a modified genesis potential index

To understand the impacts of large-scale circulation during the evolution of El Nino cycle on tropical cyclones(TC) is important and useful for TC forecast.Based on best-track data from the Joint Typhoon Warning Center and reanalysis data from National Centers for Environmental Prediction for the period 1975-2014,we investigated the influences of two types of El Nino,the eastern Pacific El Nino(EP-El Nino) and central Pacific El Nino(CP-E1 Nino),on global TC genesis.We also examined how various environmental factors contribute to these influences using a modified genesis potential index(MGPI).The composites reproduced for two types of El Nino,from their developing to decaying phases,were able to qualitatively replicate observed cyclogenesis in several basins except for the Arabian Sea.Certain factors of MGPI with more influence than others in various regions are identified.Over the western North Pacific,five variables were all important in the two El Nino types during developing summer(July-August-September) and fall(OctoberNovember-December),and decaying spring(April-May-June) and summer.In the eastern Pacific,vertical shear and relative vorticity are the crucial factors for the two types of El Nino during developing and decaying summers.In the Atlantic,vertical shear,potential intensity and relative humidity are important for the opposite variation of EP-and CP-E1 Ninos during decaying summers.In the Southern Hemisphere,the five variables have varying contributions to TC genesis variation during peak season(January-February-March) for the two types of El Nino.In the Bay of Bengal,relative vorticity,humidity and omega may be responsible for clearly reduced TC genesis during developing fall for the two types and slightly suppressed TC cyclogenesis during EP-El Nino decaying spring.In the Arabian Sea,the EP-El Nino generates a slightly positive anomaly of TC genesis during developing falls and decaying springs,but the MGPI failed to capture this variation.     

构造形变、气象灾害与地球轨道的关系

黄赤交角和月亮赤纬角决定了地球应力场的主应力方向 ,据此研究了构造形变与气象灾害的关系。地球化学给出臭氧减少的原因 ,而地球物理则提供了臭氧的分布规律。臭氧洞是两种机制综合作用的结果。研究表明 ,能量交换和引潮力造成地球各圈层差异旋转 ,是臭氧洞和厄尔尼诺等气象灾害产生的根本原因。     

Impact of El Nino on Large—scale Circulation of Southeast Asian Summer Monsoon

Multi-year SST and NCEP/NCAR reanalyzed wind data were employed to study the impacts of El Nino on the Southeast Asian summer monsoon(SEASM),It was found that the impacts of El Nino on the SEASM differed distinctly from those on the East Asian Summer monsoon (EASM) and the Indian summer monsoon(ISM).Composite analysis indicated that the “gear point“of coupling between the Indo-mosoon circulation and the Pacific-Walker circulation was located in the western margins of Southeast Asia when the developing stage of El Nino events covered the boreal summer.The anomalous circulations in the lower and upper troposphere and divergent circulation are all favorable for the strengthening of the SEASM during this period.Following the evolution of El Nino,the “gear point“ of the two cells shifted eastward to the central Pacific when the mature or decaying period of El Nino events covered the boreal summer.The anomalous circulations are favorable for the weakening of the SEASM ,The anomalous indexes of intenstity of SEASM accord well with the above resultsl.Additionally,the difference of SSTA patterns in the tropical In-do-Pacific OCean between the two stages of the El Nino may play an important role.     

青岛台站重力固体潮和海潮负荷特征研究

选取青岛台站2012-01~2013-02 gPhone重力仪连续观测资料进行预处理和调和分析,获得其重力潮汐参数,并选取8个全球海潮模型对O1、K1和M2潮波进行海潮负荷改正。结果表明：1）8个主要潮波调和分析的振幅因子标准差均在2.6%之内,与理论潮汐模型值的差异也在3.0%之内;2）利用海潮模型对O1、K1和M2潮波进行改正能有效地降低残差矢量,观测残差负荷改正的有效性大致分布在30%~75%,全球海潮模型对青岛台站主要潮波的海潮负荷改正差别不大。     

基于谱-有限元法的SNERI地球模型固体潮形变计算

基于谱-有限元法计算一个球型、非自转、完全弹性、各向同性(SNERI)的地球固体潮形变,其中地球固体部分潮汐形变的弱解用哈密顿变分原理给出,液核部分的弱解采用静态中性分层的流体近似。计算过程中把SNERI地球进行等间距球层剖分,球面上对解函数和试探函数采用球谐展开,径向上采用线性插值。比较数值计算结果与同质地球模型的解析解结果得出,1 km径向等距剖分即可获得10~(-8)精度量级的低阶Love数。基于PREM地球模型的计算结果表明,谱-有限元法计算的固体潮2～3阶Love数与Runge-Kutta法的计算值差异在10~(-4)量级;与武汉台超导重力仪8个主潮波的实测重力潮汐因子相比,本方法计算的理论重力潮汐因子相差平均约0.15%。研究结果说明,谱-有限元法具有较好的收敛性与较高的计算精度,比传统Runge-Kutta法更适用于高精度地计算复杂地球模型的固体潮形变。     

太行山山前断裂带倾斜潮汐因子动态组合分析

利用Venedikov调和分析方法计算太行山山前断裂带地倾斜观测台站2002~2017年EW和NS分量的固体潮潮汐因子,获取潮汐因子异常与动态组合的3种特征量（扩容膨胀、剪切应变、介质的各向异性）时间序列,并分析其与太行山山前断裂带附近中等地震的关系。结果表明：1）断裂带上地倾斜潮汐因子受海潮负荷影响较小,潮汐因子并未因纬度的改变而表现出明显的规律性变化,其差异可能是因为受地壳横向不均匀变化的影响;2）地倾斜固体潮潮汐因子动态组合特征量与观测站点周边350 km范围内发生的ML4.0以上地震有较好的对应关系。     

Estimates of global M_2 internal tide energy fluxes using TOPEX/POSEIDON altimeter data

TOPEX/POSEIDON altimeter data from October 1992 to June 2002 are used to calculate the global barotropic M2 tidal currents using long-term tidal harmonic analysis. The tides calculated agree well with ADCP data obtained from the South China Sea (SCS). The maximum tide velocities along the semi-major axis and semi-minor axis can be computed from the tidal ellipse. The global distribution of M2 internal tide vertical energy flux from the sea bottom is calculated based on a linear internal wave generation model. The global vertical energy flux of M2 internal tide is 0.96 TW, with 0.36 TW in the Pacific, 0.31 TW in the Atlantic and 0.29 TW in the Indian Ocean, obtained in this study. The total horizontal energy flux of M2 internal tide radiating into the open ocean from the lateral boundaries is 0.13 TW, with 0.06 TW in the Pacific, 0.04TW in the Atlantic, and 0.03 TW in the Indian Ocean. The result shows that the principal lunar semi-diurnal tide M2 provides enough energy to maintain the large-scale thermohaline circulation of the ocean.     

海潮负荷地心运动对GPS坐标时间序列周期信号的影响分析

分别采用地球系统质心（center of mass of the whole earth system, CM）和固体地球质心（center of mass of the solid earth, CE）框架的海潮负荷(ocean tide loading, OTL)改正计算132个全球站的静态精密单点定位PPP坐标,分析海潮负荷引起的地心运动对GPS坐标时间序列的影响。结果表明：1）海潮负荷地心运动在水平和垂直方向上引起的坐标差异分别为0.7 mm和1.3 mm,海潮负荷地心运动对坐标时间序列的影响具有显著的区域分布特征;2）在CM-OTL和CE-OTL中,海潮负荷效应引起的周期信号明显减小,海潮负荷改正所属框架与GPS轨道所属框架的不一致将引入GPS交点年信号、14 d、9 d信号;3）利用IGS精密轨道进行PPP计算时,应采用CE框架进行海潮负荷改正。