New Long-Term Climate Oscillations

J. Smulsky
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Abstract

The astronomical theory of climate change is based on the solution of differential equations describing Earth’s orbital and rotational motions. The equations are used to calculate the change in insolation over the Earth’s surface. As a result of the author’s solution of the orbital problem, the periods and amplitudes of Earth-orbit variations and their evolution have been refined. Unlike previous studies, the equations of Earth’s rotational motion are solved completely. The Earth’s rotational axis precesses relative to a direction different from the direction of the orbit’s axial precession, and oscillates with periods of half a month, half a year and 18.6 years. Also, its oscillations occur with irregular periods of several tens of thousands of years and more. All these motions lead to oscillations of the obliquity in the range of 14.7° to 32.1°, which prove to be 7 - 8 times larger than obtained by a previous theory. In the same proportion, the Earth’s insolation oscillations increase in amplitude, with insolation extremes occurring in other epochs than those in the previous theory. The amplitudes and the onset times of the extremes correlate with known paleoclimate changes. Thirteen insolation periods of paleoclimate variation over an interval of 200 thousand years are identified. From the insolation evolution calculated over a time interval of 1 million years, 6 climate gradations from very cold to very warm are identified.
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新的长期气候振荡
气候变化的天文学理论是建立在描述地球轨道和自转运动的微分方程的解的基础上的。这些方程式被用来计算地球表面日晒量的变化。由于作者对轨道问题的解决,地球轨道变化的周期和幅度及其演变得到了改进。与以往的研究不同,地球自转的方程得到了完整的解。地球自转轴的进动方向与轨道的轴进动方向不同,周期分别为半个月、半年和18.6年。此外,它的振荡以几万年甚至更长时间的不规则周期发生。所有这些运动导致了在14.7°到32.1°范围内的倾角振荡,这证明了比以前的理论得到的大7 - 8倍。同样的比例,地球的日晒振荡振幅增加,极端日晒发生在其他时期,而不是以前的理论。极端事件的振幅和发生时间与已知的古气候变化有关。确定了20万年间古气候变化的13个日晒期。在100万年的时间间隔内计算日晒演变,确定了从极冷到极暖的6个气候等级。
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