Spin is the measure of the angle of the particle. The angle determines whether the particle is a scalar or a vector. Spin zero indicates a positive scalar; Spin 1/2 is pi/2 angle and indicates a positive vector; spin 1 is pi degrees and indicates a negative scalar; spin 3/2 indicates a negative vector.
Physics Particles are Quaternions containing a scalar and vector parts, the unit quaternion is described as:
cos(Angle) + v sin(Angle).
Quantities in Physics are in general Quaternion, e.g. Gravitatioanl Energy W=-mu/r + cP.
Bosons and Fermions represent pure scalars and Vectors with angle being multiples of pi or spin. spin is symbolic of 180 degrees spin zero is zero degrees. spin 1/2 is 90 degrees etc. When angles are not multiples of pi/2 the quantity is a Quaternion and contains a scalar (Boson) and Vector (Fermion).
Protons are composite particles made of quarks held together by strong nuclear forces, while electrons are fundamental particles with spin. The spin of a proton is due to the motion of its quarks, rather than an intrinsic property like the spin of an electron.
The theoretical Higgs boson would have zero spin. The neutral and charged pions also have zero spin. Two entangled particles, each with spin opposite to each other, would be a quantum state with zero net spin. Atoms may also have zero spin, if they are in what is known as S-states (e.g. the ground state of hydrogen).
A spin of 2 indicates that the particle behaves as if it has intrinsic angular momentum equal to 2, in units of the reduced Planck constant ħ. Spin is a fundamental property of particles in quantum mechanics and affects their behavior in various ways. For example, particles with integer spin are bosons and follow Bose-Einstein statistics.
A quantum state with zero spin is a state where the angular momentum of the system is zero. This means that the system has no intrinsic angular momentum or spin. In other words, it has a spin quantum number of 0.
They have different masses, electrical charge, dimensions, life time, spin etc.
This theorem of quantum physics says something about integer-spin particles and half-integer spin particles. For more information see the article I've associated with this answer.
Those are the 'quarks'.
In particle physics, fermions are particles with a half-integer spin, such as protons and electrons.
Spin-1/3 particles in quantum mechanics are a type of elementary particle that have a specific intrinsic angular momentum, or "spin," value of 1/2. This means they can have two possible spin states: spin up and spin down. These spin-1/3 particles differ from other spin values, such as spin-0 or spin-1 particles, in that they follow different rules and behaviors in quantum mechanics. For example, spin-1/3 particles obey Fermi-Dirac statistics, which dictate how identical particles with half-integer spin values behave in quantum systems. Overall, the unique properties of spin-1/3 particles play a crucial role in understanding the behavior of matter at the quantum level and are fundamental to many aspects of modern physics.
Spin-1 particles are described using the Pauli matrices, which are mathematical tools used to represent the spin of particles in quantum mechanics. The Pauli matrices help us understand the properties and behavior of spin-1 particles.
Spin 1/2 particles are a type of subatomic particle that have a property called spin, which is a fundamental characteristic of particles in quantum mechanics. These particles exhibit behaviors such as being able to have two possible spin states, either up or down, and can interact with magnetic fields. Spin 1/2 particles are important in understanding the behavior of matter at the smallest scales.
The path of an electron as it orbits the nucleus. If you mean the orbital, then that is the shell, or level that an electron is on. If you mean the spin, then that's a quality that subatomic particles have (nothing to do with spinning, just a name). An electron's spin is 1/2.
The characteristics of sub-atomic particles are charge, mass, and spin. Neutrons are the heaviest, electrons are the lightest (of those 3 particle types), elecrons are negatively charged, neutrons are uncharged, and protons are postively charged. Spin is sometimes used to distinguish between some kinds of particles, but not in this case.
The spin operator affects the behavior of quantum particles by describing their intrinsic angular momentum. It determines the orientation of a particle's spin, which influences its interactions with magnetic fields and other particles.
Spin zero particles have no intrinsic angular momentum, meaning they do not spin on their axis. They are scalar particles, meaning they have no directionality in their properties. They are also bosons, which means they follow Bose-Einstein statistics and can occupy the same quantum state. Examples of spin zero particles include the Higgs boson.
The spin 3/2 particle is significant in particle physics because it represents a type of particle with higher spin compared to most other particles. Its spin property differs from other particles in that it has a more complex angular momentum structure, allowing it to interact in different ways with other particles and fields. This makes spin 3/2 particles important in understanding the fundamental forces and interactions in the universe.
4 and a half spins is the world recited, at least by my knoll age