“Orbit” and “orbital” are terms commonly used in astronomy and quantum mechanics, respectively. Here are five key differences between orbit and orbital:
Definition:
Orbit:
Definition: An orbit is the curved path that an object, such as a planet, satellite, or celestial body, follows around another object due to gravitational attraction. Orbits are typically associated with celestial bodies moving in space under the influence of gravity.
Orbital:
Definition: An orbital, in the context of quantum mechanics, refers to the region within an atom where an electron is likely to be found. It is a mathematical description of the probability distribution of an electron’s location around the nucleus.
Scale:
Orbit:
Scale: Orbits are typically on a macroscopic scale, involving large celestial bodies like planets, moons, and satellites. The gravitational forces between massive objects determine their orbits.
Orbital:
Scale: Orbitals are on a microscopic scale, describing the behaviour of subatomic particles, specifically electrons, within an atom. Quantum mechanics governs the behaviour of particles at this scale.
 Nature of Object:
Orbit:
Nature of Object: Orbits are associated with the motion of objects in space, such as planets orbiting a star or moons orbiting a planet. The objects in orbits have mass and experience gravitational forces.
Orbital:
Nature of Object: Orbitals are related to the behaviour of electrons around a nucleus within an atom. Electrons are particles with both wave-like and particle-like properties, and orbitals describe their probable locations.