One of the main difficulties which appeared in Classical Mechanics was its unconsistency with the electromagnetic phenomena, notably the problem of magnetic induction in a moving circuit. This unconsistency has been amplified by the negative result of the MichelsonMorley experiment whose aim was measuring the translation velocity of the Earth in the aether. In order to cure these problems, A. Einstein succeeded in establishing new basis for Mechanics by setting three new postulates:

• Time is a relative notion and each observer possesses its own time.

• The speed of light is isotropic and does not depend on the state of motion of the observer.

• being an inertial frame moving with a constant velocity according to another frame, the coordinate transformation between these two inertial frames is given by the Lorentz formula [4].

A straightforward consequence of these new principles was the fusion of space and time in one entity called “Space-Time”, which was performed by H. Minkowski ([5]). In this new 4-space, time and space components are completely symmetric, as it is shown by the following series of equalities relating space-time components of the same event between the two frames:

and

where is the Lorentz factor, and the sign appears in Equation (2) because the velocity of.

Physical interpretation of these relations becomes more obvious by adopting the point of view of Special Relativity: Analysis of physical phenomena does not depend on the motion of the observer(s). Observer O in frame and observer O’ in frame have completely a symmetric role. It is worth stressing that Einstein’s postulates and Minkowski’s 4-space lead to a new physical concept, the Relativistic Invariance one, which have important consequences in the foundations of Modern Physics.

Thanks to a new mathematical entity, the 4-vector introduced by Minkowski, one can set many fundamental invariants, among them:

• The square of the space-time interval, , from which one can deduce automatically the relation of clock retardation [6].

• The square of the energy-momentum 4-vector,.

Applying this last relation to a massive particle at rest, the Einstein breakthrough formula emerges, , which represents a new symmetry, the equivalence between Energy and Mass [7]; symmetry which does not exist in Newton Mechanics.

In his seminal paper, A.Einstein was motivated by showing that the two standard views of the induction phenomenon (Lenz-Faraday law) were really the same one. Departing from the Relativity principles, he achieved merging the two different processes and he found again the standard results of the Maxwell’s equations: any variable electric field generates a magnetic field, and reciprocally. So, a complete symmetry is established between the electric and magnetic fields, despite the absence (temporary?) of magnetic charges. This physical property is clearly reflected in the relativistic formalism with the introduction of a new entity, the electromagnetic tensor ¹, which is an antisymmetric tensor whose six components are respectively those of the electric and magnetic fields. Doing some calculations with this new tensor like the following,

(indices are varying from 0 to 3), allows to find again the standard Maxwell-Faraday equations: .

At the classical level, the Relativity Theory introduces new aspects of symmetry in fields where symmetry was not conjectured: Space and Time, Electric and Magnetic fields and the Mass-Energy equivalence. Furthermore, its mathematical formulation includes, in a simple and direct way, the symmetry properties of the physical processes [8].

The importance of Symmetry in NRQM leads to a wide use of Group Theory methods when describing quantum systems, from the simple hydrogen atom to complicated molecular structure [9]. This feature is related to the mathematical structure of Quantum Mechanics itself: any physical quantity which can be measured, or observable, is represented by a hermitean operator acting on a Hilbert space built from state vectors or kets; the last ones represent the physical states of the system and form an algebraic vector space [10]. How ordinary QM has been made relativistic? Before answering this question, it is fair to recall how Special Relativity has been firstly introduced in Quantum Physics.

In his doctoral thesis (Paris, 1924), the french physicist L. de Broglie generalized the important notion of wave-particle duality (first introduced by A. Einstein for the Photon in 1905 [11]) by extending it to massive relativistic particles [12]. Departing from the hypothesis that each material corpuscle has an internal vibration whose frequency is given by the Planck-Einstein relation, , and supposing that this vibration is in phase with a “phase wave” propagating at the speed (²), De Broglie inferred the expression of the particle wave-length:

which is identical to the photon wave-length given by the Planck-Einstein relation,. This famous relation, which has been confirmed by the experimental discovery of the electron diffraction (Davisson and Germer, 1927), links together the two main aspects of matter, wave and/or particle. Thus, a new symmetry at the level of the elementary particles has been revealed, as a consequence of the Einstein-De Broglie relations. Then, the wave nature of any quantum system has been exploited very deeply to set fundamental equations: the non-relativistic Schrodinger equation [13], and the relativistic Klein-Gordon one [14].

In the years 1927-1928, the British physicist P. Dirac succeeded in formulating a relativistic wave equation for the electron characterized both by its simplicity and its ingenuity [15].

where is the 4-momentum of the particle and are the Dirac matrices with.

The Dirac equation has a linear evolution according to time, like the Schrodinger equation and, furthermore, it reveals a perfect similarity among space and time components. Thus, it has the great advantage to be relativistic invariant. Applied to the known massive particles (at this epoch there were only electrons and protons), Dirac equation leads to fascinating results:

• The value of the spin, , is deduced automatically with a gyromagnetic factor of the electron, , which agrees with the experimental measurements.

• There appear negative-energy states for the electron• , as with the Klein-Gordon equation. But, according to the fermionic nature of the electron, these states are interpreted as an electron with positive electric charge, or an anti-electron called also a positron [16]. This particle has been discovered by Anderson in 1933 [17], which marks the beginning of the Antimatter Era.

• Thanks to the relativistic Dirac equation a new symmetry is born:

As shown in the preceding sections, Relativity Theory introduces fundamental tools for apprehending new physical processes. These are essentially:

• Relativistic Conservation Laws, like the conservations of the total energy-momentum (including the mass) and of the total angular momentum (including the spin of the particles).

• Relativistic Covariance. It is a new principle which stipulates that the description of any quantum process must have the same analytical form, independently of the reference frame in which the process is observed; the best example being the computation of the transition probabilities between different quantum states.

• According to these new principles, E. Wigner wrote a paper devoted to the representations of the Lorentz Group [20] which constitutes a new breakthrough in Relativistic Quantum Physics (including QFT). He applied techniques of Group Theory to the Hilbert space describing a quantum system obeying Relativity principles; and he succeeded to derive two Relativistic Invariants (RI), independently of the internal dynamics of the physical system. The two RI are respectively the mass of the quantum system (already found since the introduction of the Minkowski 4- space) and its intrinsic angular momentum or its quantized spin.

An immediate consequence of these RI is related to the massless particles which move at the speed of light c like photons, gravitons and even neutrinos if their masses are neglected: the projection of the spin of a massless particle along its momentum or helicity, , has only two values,. It could be seen that the massless quantum state with is the mirror image of the other state with and vice-versa. This intuitive symmetry will be tested experimentally and important features will be deduced.

• It is quite remarkable that Wigner’s achievement completes the seminal work of Dirac: by means of the relativistic formulation of the quantum principles, the intrinsic angular momentum of a particle, or its spin, emerges directly. Spin is an essential ingredient for describing atoms, nuclei and particles; and it is worth noticing that, thanks to the existence of the spin, Pauli formulated his famous Exclusion Principle which explains the stability of atoms and molecules.

• Other important symmetries in Subatomic Physics are the Discrete Symmetries whose experimental tests are still a challenge for Nuclear and Particle Physics. These are:

1) Charge Conjugation, C, which transforms any particle with charge q into its antiparticle with charge by keeping its mass and its spin unchanged (it is a consequence of the relavistic Dirac equation).

2) Parity, P, (or mirror symmetry) which transforms the vectors into.

3) Time Reversal, T, which transforms and spin, and exchanges both initial and final states.

It is usually argued that a quantum system is invariant by one of these three symmetries, , if its hamiltonian H, which governs its evolution in time, keeps the same form after applying on the physical system. Mathematically, it leads to

The two symmetries, P and T, are already used in NRQM, especially for establishing selection rules [21]; but their relativistic aspect becomes more crucial in Particle Physics which deals with energetic particles like electrons or neutrinos whose velocities are often very close to the speed of light.

• In this context, sophisticated experiments have been performed in order to test the validity of these symmetries, as suggested by theorists T. D. Lee and C. N. Yang in 1956 in order to solve the “puzzle” [22]. An historical experiment analyzing electron angular distributions from nuclear decay [23], followed by another one studying weak decay of the muon, [24], proved in an undoubtful way that both Parity and Charge Conjugation are violated in weak interactions: whatever the initial decaying particle is, the neutrino is a left-handed particle, while the anti-neutrino is a right-handed one (³ ). But the combined operation, CP or PC, is still a good symmetry [25]. This hypothesis was true until the experimental discovery of Cronin et al. (1964) which shown the breakdown of CP symmetry in the neutral meson system, , made out by a pair of particle-antiparticle evolving differently with time [26].

• After the failure of the Discrete Symmetries, a main question arose [27]:

Discrete symmetries being only approximate, is there any fundamental law which could relate a particle or a system of particles to their corresponding antiparticles?

The answer to this crucial question comes again from Relativistic QFT, thanks to the CPT theorem [28] which states the following: “Assuming Lorentz Invariance of the interactions among particles, physical laws are invariant by the product of the three discrete symmetries C, P and T taken in any order: CPT, TPC, TCP, ...”.

This theorem concerns any local interaction described in the Minkowski 4-space, like Strong, Electromagnetic and Weak interactions, and does not depend on the fact that any discrete symmetry is conserved or violated. It leads to important physical consequences which are still valid on the experimental side:

• The equality of mass of any particle (X) with its antiparticles [29].

• The total lifetimes of are identical.

• The intrinsic magnetic moments of are opposite in sign but they have the same absolute value.

• Inverse reaction with antiparticles:

Reaction (2) has the same probability of occurrence than reaction (1), even if symmetry CP or T is violated.

Gauge field theories and their applications to Particle Physics represent today the heart of Modern Physics and of all the activities turning around them, both theoretical and experimental. It requires a huge literature to describe them and, in this paragraph, emphasis will be put on the basic principles and the original ideas which guided their development.

• According to their physical properties (mass, charge, spin) and to their mutual interactions, particles are classified into specific families called multiplets. An evident example is the proton-neutron system which forms a doublet with regard to the strong interaction. Thus, it is said that the relativistic proton-neutron interaction is invariant by the symmetry group.

After the discovery of many particle families, new quantum numbers arose like strangeness, charm, beauty..., and their classification become an urgent problem for Theoretical Physics. Despite their differences, particles present several common aspects and notably symmetry properties which lead to the use of Group Theory techniques.

Finally, two important families emerged: quarks and leptons, and their interactions are described by gauge fields.