Quantum physics, What is Quantum physics, theory and definition
Quantum physics definition is the branch of study which deals with the matter and energy. Quantum physics examines the energy that it comes in the form of the packets that are tending to be called quanta. 2quanta are made in such way that they can act as wave and particles. In the quanta form waves seems to be acting as particles and the particles seem to be acting as waves. They have the indifferent behavior in the form of the quanta. Quantum physics deals with the working of the particles and how they are arranged in their orbits. It is the study of the particles in nature that are ‘bound up to make matter. it also study the force with which all the metals and particles are united together. Quantum physics deal with the forces with which all the matters and the particles. Different particles are arranged in their orbits according to the physical properties of the forces that are responsible for their binding. Different particles and matter pertains a heavy amount of the energy which is omitted or absorbed during their chemical reaction in the electromagnetic fields. The particles are electrical charged either weak or strong in their relative fields.
Quantum field theory definition
Quantum field theory is depicted as the theoretical in quantum physics which focuses on the combination of the classical field theory and the super relativity. It is said to be used for the combination of the elements of the quantum Mechanics and the super relativity. It focuses on the behavior of the sub-particles in the formation of the atom and matters. This theory exists as the body of physical principles for determining the physical nature and the reactivity of the molecules. In electrodynamics we study the interaction and the relativity of the electrically charged particles that combine to form atoms and molecules. The study area of this field covers the motion of the particles that are electrically charged. Quantum chromo dynamics deals with the study of the forces that interacts between the particles and atoms of a matter. This also represent the study of the quarks that are involved in the interaction of the different forces, it is phenomena of the particle-physics in which creation of the sub-atomic molecules or atoms or created or destroyed through high energy collisions of the charged particles. Quantum field theory is also rooted in other branches of the physics to understand the relativity of the particles or molecules. Quantum filed theory predicts the electromagnetic effect on the charged particles and atoms. Emission and the absorption of the particles is achieved through the electric and magnetic forces. In electromagnetic field these forces can create disturbance. They can create same disturbance as the ripples on the lake or identified as the disturbance in water. Light and the other electromagnetic radiation are often identified from the charged photons when they are detected as charge free electric particles. Some particles can create disturbance in their own quantized fields such as the electrons will do the same.
Gauge theories in quantum physics
Radioactive beta decay is carried through the weak forces that exist in the nature. Different theories put these weak forces responsible for the radioactive rays decay. Atomic nuclei are constituted through the union and the attraction of the strong forces that binds together different molecules and particles in an atom. Strong forces are responsible for the binding of particles. Gravitational forces also interact and exist on the same principle. Each of the particles that are responsible for its own motion exchanges the forces that are responsible for the binding of the different particles. The properties of the different particles and the binding forces can be identified through the gauge theories. Some forces in the electromagnetic and gravitational fields operate on the large distance from the particles that are placed far apart from each other. Different particles are exchanged in the electromagnetic fields and the gravitational fields.
Quantum chromo dynamics field theory
The distance between the atomic nuclei should be shorter than the size of the operating nuclei and molecules. If the distance between the atomic nuclei will be larger than their size the forces cannot operate in the electromagnetic and gravitational fields. In the electromagnetic fields the effects of the different forces on the particles and molecules can be identified. The interaction of the bond particles such as neutron or protons ad their attraction is also detected through the modern field theory about the effect of the forces in the electromagnetic and gravitational field. The weak forces between the charged particles can be of shorter range and can attract only smaller particles.
Unified field theory
The study of the binding forces either weak or strong is based on the principles of the quantum field theory in quantum physics. A single unified theory is introduced as the theoretical frame work that is designed to study the motion of the particles and matter on the effect of the forces that are used to bind or replace them in the electromagnetic and gravitational fields. According to the single unified theory the forces that are acting upon the particles and matter must be originated from the same place. The origin of the particles will be arranged according to their mathematical symmetry. All the forces and the particles in the electromagnetic fields differ on the base of their physical properties that are identified on their deep studies. Different particles and the substances interact according to their physical properties in the electromagnetic and gravitational fields.
Electroweak theory in quantum physics
The electromagnetic or lector weak theory identifies the physical properties of the weak forces existing in the electromagnetic field. The theory is based on the experimental frame work in order to identify the properties of the substances. The theory somehow is grounded on the speculative ideas about the weak forces. The area of the theory can be somehow extended to identify the physical properties of the strong forces that attract and act upon the different particles and matter. Spontaneous symmetry of the particles and the substances can be identified through the single electroweak theory.