银河系自转曲线的理论计算与实际观测比较
Comparison of Theoretical Calculations and Actual Observations of Galactic Rotation Curve
DOI: 10.12677/MP.2018.83015, PDF,   
作者: 常炳功*:美国纽约州立大学州南部医学中心,神经病学和神经生理药理学系,神经退行性疾病和发现中枢神经系统生物标记实验室,美国 纽约
关键词: 能气场银河系自转曲线Energy Qi Field Galactic Rotation Curve
摘要: 时空阶梯理论揭示,能气场就是暗物质,星体运动变化除了受牛顿引力之外,还受能气场的作用力:F=m(E+v*Q) ,其中,F是能气场力,m是星体质量,E是能量场强度,v是星体的速度,Q是气感应强度。实际观测:在距离银心4 < R < 19 kpc范围内,星体速度在220 km/s左右。而当R > 8.5 kpc时,自转曲线有所抬高。理论计算:在距离银心4 < R < 16 kpc范围内,星体速度在220 km/s左右。而当R > 8.5 kpc时,具体在10 < R < 19 kpc范围内,星体速度从220 km/s上升到235 km/s,自转曲线有所抬高,但是整体上,自转曲线基本上是平坦的,与实际观测基本吻合。
Abstract: Space-time ladder theory reveals that the Energy Qi field is dark matter. In addition to Newtonian gravity, the movement of the star is also affected by the Energy Qi field: F=m(E+v*Q) , where F is the force of Energy Qi field, m is the mass of the stars, E is the energy field strength, v is the speed of the stars, and Q is the Qi induction. Actual observations: In the range of 4 < R < 19 kpc from the galactic center, the star speed is about 220 km/s. However, when R > 8.5 kpc, the rotation curve is raised. Theoretical calculations: In the range of 4 < R < 16 kpc from the galactic center, the star speed is around 220 km/s. When R > 8.5 kpc, specifically, in the range of 10 < R < 19 kpc, the speed of the star rises from 220 km/s to 235 km/s, and the rotation curve rises. However, overall the rotation curve is basically flat, and basically coincides with actual observations.
文章引用:常炳功. 银河系自转曲线的理论计算与实际观测比较[J]. 现代物理, 2018, 8(3): 127-131. https://doi.org/10.12677/MP.2018.83015

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