The System of Equations of Interacting Electromagnetic, Scalar Gravitational and Spinor Fields Anatoliy N. SERDYUKOV Francisk Skorina Gomel State University.

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The System of Equations of Interacting Electromagnetic, Scalar Gravitational and Spinor Fields Anatoliy N. SERDYUKOV Francisk Skorina Gomel State University Gomel, Byelorussia

The Classical Particle in the Electromagnetic and Scalar Gravitational Fields (Comparative analysis)

The Classical Particle in the Electromagnetic and Scalar Gravitational Fields (Comparative analysis)

The Classical Particle in the Electromagnetic and Scalar Gravitational Fields (Comparative analysis)

The Classical Particle in the Electromagnetic and Scalar Gravitational Fields (Comparative analysis)

The Classical Particle in the Electromagnetic and Scalar Gravitational Fields (Comparative analysis)

The Gauge-Invariance of Gravitational Field Here  is an arbitrary real constant

The Closed Classical Systems: Particles and Fields

(Comparative analysis)

The Closed Classical Systems: Particles and Fields (Comparative analysis)

The Closed Classical Systems: Particles and Fields (Comparative analysis)

The Closed Classical Systems: Particles and Fields (Comparative analysis)

The Closed Classical Systems: Particles and Fields (Comparative analysis)

The Closed Classical Systems: Particles and Fields (Comparative analysis)

The Closed Classical Systems: Particles and Fields (Comparative analysis)

The Closed Classical Systems: Particles and Fields (Comparative analysis)

Three-dimensional Form of Equations (Comparative analysis)

Three-dimensional Form of Equations (Comparative analysis)

Three-dimensional Form of Equations (Comparative analysis)

Three-dimensional Form of Equations (Comparative analysis)

Newtonian Limit of Relativistic Equations

The Energy-Momentum Tensor: Particles and Fields (Comparative analysis)

The Energy-Momentum Tensor: Particles and Fields (Comparative analysis)

The Energy-Momentum Tensor: Particles and Fields (Comparative analysis)

Once more about the Gauge-Invariance of Gravitational Field

The System of Gauge-Invariant Equations

The Extended System of Charge Particles, Electromagnetic and Gravitational Fields

To take into account the presence of gravitation field of system (in the frame of scalar model of gravitation) it is necessary to ensure the next transformation law of complete Lagrangian at gauge transformation  '  =  of gravitation potential.

The Extended System of Charge Particles, Electromagnetic and Gravitational Fields

The movement equations of classical particles

The Extended System of Charge Particles, Electromagnetic and Gravitational Fields The movement equations of classical particles

The Extended System of Charge Particles, Electromagnetic and Gravitational Fields The movement equations of classical particles

The Extended System of Charge Particles, Electromagnetic and Gravitational Fields The movement equations of classical particles

The Extended System of Charge Particles, Electromagnetic and Gravitational Fields The movement equations of classical particles

The Extended System of Charge Particles, Electromagnetic and Gravitational Fields The movement equations of classical particles

The Extended System of Charge Particles, Electromagnetic and Gravitational Fields The movement equations of classical particles

The Extended System of Charge Particles, Electromagnetic and Gravitational Fields The movement equations of classical particles

The Extended System of Charge Particles, Electromagnetic and Gravitational Fields The equations of interacting electromagnetic and gravitational fields

The Extended System of Charge Particles, Electromagnetic and Gravitational Fields Three-dimensional form of field equations

The System of Equations of Interacting Electromagnetic, Scalar Gravitational and Spinor Fields