
INDEX VOLUME II
NEW PARADIGM IN PHYSICS 1

INTRODUCTION TO VOLUME II1
I.0. Rotational Dynamics
I.1 Criteria of Classic Mechanics
I.2 Brief summary of the theory
I.3 Description of volume II

CHAPTERS

6- BEHAVIOR LAWS OF BODIES WITH AXIAL SYMMETRY.
6.0 Structure of mechanical knowledge
6.1 First Law
6.2 Second Law
6.3 Third Law
6.4 Fourth Law
6.5 Fifth Law
6.6 Sixth Law
6.7 Seventh Law
6.8 Eight Law
6.9 Ninth Law
6.10 Tenth Law
6.11 Laws of rotational dynamics
6.12 Other laws
7- COMMENTS CONCERNING THE LAWS
7.0 Dynamic interactions
7.0.0 Intrinsic Angular Momentum Concept
7.0.1 Inertia of Bodies
7.1 Generalization
7.2 Conservative Fields
7.3 Sequential Interaction
7.4 Commutative algebra
7.5 Reinterpretation of behaviors.
7.6 Chaotic movement
7.7 Inconsistency of the fictitious forces
7.8 Consistency with Kepler’s laws of planetary motion
7.8.0 Coherence: Flat orbit
7.8.1 Analysis
7.9 Consistency with Classical Mechanics
7.10 Assumptions
7.11 Comparisons
7.12 Dynamic criteria
7.12.0 Assessment
7.12.1 Assumption reiteration: three punctual masses
7.13 Other considerations
7.13.0 Central force
7.13.1 Harmonic oscillator
7.13.2 New Mathematical Formulations
7.13.3 New simulations

8- SCIENTIFIC CONSIDERATIONS
8.0 Generalization of a new concept of Rotational Mechanics
8.1 Inferences
8.1.0 Dark matter
8.1.1 Dark energy
8.2 Imago Universi
8.2.0 Application to Celestial Mechanics
8.2.1 Evolution of cosmology
8.2.2 Orbiting and rotation
8.2.3. Dynamic balance of celestial bodies
8.2.4 Other hypotheses and examples.
8.2.5. Interpretation of Celestial Mechanics
8.2.6 Review of the science of the universe
8.3 Atomic structure
8.3.0 Spin
8.3.1 Precession of charged particle
8.3.2 Quantum field theory
8.3.3 Quantization
8.3.4 Angular momenta coupling in Atomic physics
8.4 Lorentz force.
8.4.0 Detection chambers
8.4.1 Analogy
8.5 Other functions
8.5.0 Scientific applications
8.6 Natural growth

9-TECHNOLOGICAL APPLICATIONS
9.0 Dynamic interaction confinement
9.0.0 Dynamic
9.0.1 Methods for achieving fusion
9.0.2 Models of experimental reactors
9.0.3 Plasma dynamics
9.0.4 Gyrokinetic theory
9.0.5 Dynamic interactions
9.0.6 Double confinement
9.1 Dynamic anomalies in the Pioneer space probes
9.1.0 Justification
9.1.1 Rotational dynamics fields
9.1.2 Dynamic anomalies observed
9.2 Atmospheric vortex phenomena
9.2.0 Dynamic behavior
9.2.1 Equations of rotational dynamics
9.2.3 Electrodynamics and other phenomena
9.2.4 Statistical tendency
9.2.5 Models for making predictions in atmospheric physics.
9.3 Dynamic lever and energy conservation
9.4 Steering of mobiles and other devices
9.5 Flight simulator
9.6 The gyroscope
9.7 Other technological applications

10- BOOMERANG
10.0 History
10.1 What is a boomerang?
10.2 Traditional explanations
10.3 The boomerang’s path
10.4 Why does the boomerang not fall?
10.5 Lift forces
10.6 Physical-mathematical model: why does it return?
10.7 The boomerang tilt
10.8 Experimental tests
10.9 Paradigmatic example

11- THE PENDULUM, THE TOP AND THE BALL
11.0 Conical Pendulum of Dynamic Interactions
11.0.1 Analysis of experimental results
11.0.2 Experimental tests
11.0.3 Dynamic Interactions hypothesis
11.1 The spinning top
11.2 Balls
11.2.0 Effects on ping-pong balls
11.2.1 Effects on golf balls
11.2.2 The Jabulani

12- PROJECTILES, ROCKETS, PLANES & OTHER EXAM.
12.0 Projectiles and rockets
12.1 Aeroplanes: Roll Coupling
12.2 Helicopters and Autogyros
12.3 Epostracism
12.4 Bouncing bombs
12.5 Cylinder subject to two rotations
12.6 Rolling coin
12.7 Euler’s disk
12.8 Bicycle and motorbike
12.9 Other examples
12.9.0 The equilibrist’s foot
12.9.1 Hula hoop rings
12.9.2 Rings with washers
12.9.3 Other examples
12.10 Results assessment

13- COMMENTS TO THE THEORY OF RELATIVITY
13.0 The Relativity of Motion
13.0.1 Absolute rotation
13.1 Logical deductions from the Theory of Dynamic Interactions
13.1.0 Revisions of Mechanics
13.1.1 Explanation of the planetary orbit
13.1.2 Final stages
13.3 Coordinate transformation
13.4 Other references
13.5 Mathematical model

14- ANALYSIS & SALVENTS OF CLASSICAL MECHANICS
14.0 The structure of knowledge
14.0.0 Rotational dynamics of solid rigid bodies
14.0.1 A new paradigm: Contents of the work
14.1 Identifying confusion and limitations
14.2 Concurrence of orbiting and rotation movements
14.3 Generalisation of the mechanics
14.4 Justification
14.4.0 Discrepancies between models
14.4.1 A surprising rotational dynamics

15- INNOVATIONS AND CONCLUSIONS
15.0 Renovating proposals
15.1 Investigation project
15.2 Conclusions
15.2.0 Summary of conclusions
15.3 Tribute

ACKNOWLEDGEMENTS
ANNEXES
I- BIBLIOGRAPHY CONSULTED BY THE AUTHOR
II- BIBLIOGRAPHY AND REFERENCES TO TDI
III- INDEX VOLUME I
ABOUT THE AUTHOR
THANK YOU