atomic orbitals

(noun)

The physical region in space around the nucleus where an electron has a probability of being.

Related Terms

(noun)

the physical region or space where an electron may be present or found, with a probability calculated from the precise mathematical form of the orbital.

Related Terms

Examples of atomic orbitals in the following topics:

  • Linear Combination of Atomic Orbitals (LCAO)

    • An LCAO approximation is a quantum superposition of atomic orbitals, used to calculate molecular orbitals in quantum chemistry.
    • It is possible to combine the known orbitals of constituent atoms in a molecule to describe its electron orbitals.
    • A linear combination of atomic orbitals, or LCAO, is a quantum superposition of atomic orbitals and a technique for calculating molecular orbitals in quantum chemistry.
    • Essentially, n atomic orbitals combine to form n molecular orbitals.
    • Predict which orbitals can mix to form a molecular orbital based on orbital symmetry, and how many molecular orbitals will be produced from the interaction of one or more atomic orbitals

  • Single Covalent Bonds

    • An atomic orbital is defined as the probability of finding an electron in an area around an atom's nucleus.
    • Covalent bonding occurs when two atomic orbitals come together in close proximity and their electron densities overlap.
    • Regardless of the atomic orbital type, sigma bonds can occur as long as the orbitals directly overlap between the nuclei of the atoms.
    • The shapes of the first five atomic orbitals are shown in order: 1s, 2s, and the three 2p orbitals.
    • These are all possible overlaps between different types of atomic orbitals that result in the formation of a sigma bond between two atoms.

  • Atomic and Molecular Orbitals

    • A more detailed model of covalent bonding requires a consideration of valence shell atomic orbitals.
    • Just as the valence electrons of atoms occupy atomic orbitals (AO), the shared electron pairs of covalently bonded atoms may be thought of as occupying molecular orbitals (MO).
    • It is convenient to approximate molecular orbitals by combining or mixing two or more atomic orbitals.
    • In general, this mixing of n atomic orbitals always generates n molecular orbitals.
    • The notation used for molecular orbitals parallels that used for atomic orbitals.

  • sp2 Hybridization

    • The two carbon atoms form a sigma bond in the molecule by overlapping two sp2 orbitals.
    • Notice again how the three atomic orbitals yield the same number of hybrid orbitals.
    • The p-orbitals that are unused by the carbon atoms in the hybridization overlap to form the C=C.
    • The atomic s- and p-orbitals in boron's outer shell mix to form three equivalent hybrid orbitals.
    • These particular orbitals are called sp2 hybrids, meaning that this set of orbitals derives from one s- orbital and two p-orbitals of the free atom.

  • Hybridization in Molecules Containing Double and Triple Bonds

    • In chemistry, hybridization is the concept of mixing atomic orbitals to form new hybrid orbitals suitable for describing bonding properties.
    • The hybrids are named for the atomic orbitals involved in the hybridization.
    • In methane (CH4) for example, a set of sp3 orbitals forms by mixing one s- and three p-orbitals on the carbon atom.
    • When the two O-atoms are brought up to opposite sides of the carbon atom in carbon dioxide, one of the p orbitals on each oxygen forms a pi bond with one of the carbon p-orbitals.
    • The sp hybridized orbitals are used to overlap with the 1s hydrogen orbitals and the other carbon atom.

  • The Building-Up (Aufbau) Principle

    • The Aufbau principle determines an atom's electron configuration by adding electrons to atomic orbitals following a defined set of rules.
    • The rule is based on the total number of nodes in the atomic orbital, n + ℓ, which is related to the energy.
    • It models atomic orbitals as "boxes" of fixed energy into which at most two electrons can be placed.
    • However, the energy of an electron in an atomic orbital depends on the energies of all the other electrons of the atom.
    • The likely location of an electron around the nucleus of an atom is called an orbital.

  • The Phase of Orbitals

    • Two atomic orbitals can overlap in two ways depending on their phase relationship.
    • This molecular orbital is called the bonding orbital and its energy is lower than that of the original atomic orbitals.
    • In this anti-bonding molecular orbital with energy much higher than the original atomic orbitals, any electrons present are located in lobes pointing away from the central internuclear axis.
    • The in-phase combination of the s orbitals from the two hydrogen atoms provides a bonding orbital that is filled, whereas the out-of-phase combination provides an anti-bonding orbital that remains unfilled.
    • If two parallel p-orbitals experience sideways overlap on adjacent atoms in a molecule, then a double or triple bond can develop.

  • sp Hybridization

    • Atoms that exhibit sp hybridization have sp orbitals that are linearly oriented; two sp orbitals will be at 180 degrees to each other.
    • When atomic orbitals hybridize, the valence electrons occupy the newly created orbitals.
    • The number of atomic orbitals combined always equals the number of hybrid orbitals formed.
    • The electronic differences in an isolated Be atom and in the bonded Be atom can be illustrated using an orbital energy-level diagram.
    • Hybridization of an s orbital and a p orbital of the same atom produces two sp hybrid orbitals.

  • sp3 Hybridization

    • In a tetravalent molecule, four outer atoms are bonded to a central atom.
    • In the ground state of the free carbon atom, there are two unpaired electrons in separate 2p orbitals.
    • The simplest of these is ethane (C2H6), in which an sp3 orbital on each of the two carbon atoms joins (overlaps) to form a carbon-carbon bond; then, the remaining carbon sp3 orbital overlaps with six hydrogen 1s orbitals to form the ethane molecule.
    • If lone electron pairs are present on the central atom, thet can occupy one or more of the sp3 orbitals.
    • In the water molecule, the oxygen atom can form four sp3 orbitals.

  • Double and Triple Covalent Bonds

    • Double and triple bonds can be explained by orbital hybridization, or the 'mixing' of atomic orbitals to form new hybrid orbitals.
    • Pi, or $\pi$, bonds occur when there is overlap between unhybridized p orbitals of two adjacent atoms.
    • From the perspective of the carbon atoms, each has three sp2 hybrid orbitals and one unhybridized p orbital.
    • As the carbon atoms approach each other, their orbitals overlap and form a bond.
    • Each carbon has two sp hybrid orbitals, and one of them overlaps with its corresponding one from the other carbon atom to form an sp-sp sigma bond.