Cosmic Gripping Force-Dominated Dual Potential Gradient Coupling Model: A New Paradigm for Celestial Orbit Stability

Abstract Traditional celestial orbit theory relies on a simplified model of "balance between gravity and virtual centrifugal force," which neither reveals the physical essence of forces nor explains phenomena such as galactic rotation anomalies and Mercury’s perihelion precession without ad hoc assumptions like "dark matter." Based on the hypothesis of the global distribution of the cosmic energy field, this study proposes a dual potential gradient coupling model centered on the "cosmic gripping force": gravity is reconstructed as the outward wrapping pressure of the cosmic energy field on matter, and celestial orbit stability originates from the dynamic coupling balance between the superposition of dual celestial energy field gradients and quantum vacuum repulsion. A quantitative system is constructed using the Bian Universal Unification Formula (BUUF), integrating core parameters such as field vibration frequency and field density to achieve precise calculation of celestial orbit radii. Verification results show that the model’s calculated value of Mercury’s orbital radius deviates from the observed value by less than 0.001%, the error in explaining Mercury’s perihelion precession is ≤2%, and the fitting error for the Andromeda Galaxy’s rotation curve is <1.5%, perfectly explaining celestial orbit stability without dark matter. Combined with WMAP satellite cosmological constant data, Gaia satellite astrometric results, and observational evidence of Saturn’s Cassini Division, the model’s universality from planetary systems to galactic scales is confirmed. This model breaks through the cognitive misunderstanding of traditional "central pull," providing a new framework for celestial orbit theory with both clear physical essence and high quantitative accuracy, while offering new technical paths for fuel-free spaceflight and exoplanet orbit prediction. 摘要 传统天体轨道理论依赖“引力与虚拟离心力平衡”的简化模型,既无法揭示力的物理本质,又需通过“暗物质”等补丁假设解释星系旋转异常、水星近日点进动等现象。本文基于宇宙能量场全域分布假说,提出以“宇宙握持力”为核心的双势场梯度耦合模型:将引力的本质重构为宇宙能量场对物质的外向包裹压力,天体轨道稳定性源于双天体能量场梯度叠加与量子真空斥力的动态耦合平衡。通过卞氏万物统一公式(BUUF)构建量化体系,整合场震动频率、场密度等核心参数,实现对天体轨道半径的精准计算。验证结果显示:模型对水星轨道半径的计算值与实测值误差小于0.001%,对水星近日点进动的解释误差≤2%,对仙女座星系旋转曲线的拟合误差<1.5%,无需暗物质即可完美解释天体轨道稳定性。结合WMAP卫星宇宙学常数数据、Gaia卫星天体测量结果及土星环卡西尼缝观测证据,证明模型在从行星系统到星系尺度的普适性。该模型突破了传统“中心拉力”的认知误区,为天体轨道理论提供了兼具物理本质与量化精度的全新框架,同时为无燃料航天、系外行星轨道预测等领域提供了新的技术路径。