Generalized Four-momentum for Continuously Distributed Materials

Sergey G. Fedosin
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Abstract

A four-dimensional differential Euler-Lagrange equation for continuously distributed materials is derived based on the principle of least action, and instead of Lagrangian, this equation contains the Lagrangian density. This makes it possible to determine the density of generalized four-momentum in covariant form as derivative of the Lagrangian density with respect to four-velocity of typical particles of a system taken with opposite sign, and then calculate the generalized four-momentum itself. It is shown that the generalized four-momentum of all typical particles of a system is an integral four-vector and therefore should be considered as a special type of four-vectors. The presented expression for generalized four-momentum exactly corresponds to the Legendre transformation connecting the Lagrangian and Hamiltonian. The obtained formulas are used to calculate generalized four-momentum of stationary and moving relativistic uniform systems for the Lagrangian with particles and vector fields, including electromagnetic and gravitational fields, acceleration field and pressure field. It turns out that the generalized four-momentum of a moving system depends on the total mass of particles, on the Lorentz factor and on the velocity of the systems center of momentum. Besides, an additional contribution is made by the scalar potentials of the acceleration field and the pressure field at the center of system. The direction of the generalized four-momentum coincides with the direction of four-velocity of the system under consideration, while the generalized four-momentum is part of the relativistic four-momentum of the system.
连续分布材料的广义四动量
根据最小作用原理推导出连续分布材料的四维微分欧拉-拉格朗日方程,该方程包含拉格朗日密度,而不是拉格朗日。这使得确定广义四动量不变量形式的密度成为可能,即拉格朗日密度相对于系统中典型粒子的四速度取相反符号的导数,然后计算广义四动量本身。结果表明,系统中所有典型粒子的广义四动量是一个积分四矢量,因此应被视为一种特殊的四矢量。所提出的广义四动量表达式正好对应于连接拉格朗日和哈密顿的勒让德变换。所得到的公式用于计算带有粒子和矢量场(包括电磁场和引力场、加速度场和压力场)的拉格朗日静止和运动相对论均匀系统的广义四动量。事实证明,运动系统的广义四动量取决于粒子的总质量、洛伦兹因子和系统动量中心的速度。此外,系统中心的加速度场和压力场的标量势也有额外贡献。广义四动量的方向与系统的速度方向一致,而广义四动量是系统相对论四动量的一部分。
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