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The second electron shell may contain eight electrons. This shell contains another spherical s orbital and three “dumbbell” shaped p orbitals, each of which can hold two electrons, as shown in [link] . After the 1 s orbital is filled, the second electron shell is filled, first filling its 2 s orbital and then its three p orbitals. When filling the p orbitals, each takes a single electron; once each p orbital has an electron, a second may be added. Lithium (Li) contains three electrons that occupy the first and second shells. Two electrons fill the 1 s orbital, and the third electron then fills the 2 s orbital. Its electron configuration    is 1 s 2 2 s 1 . Neon (Ne), on the other hand, has a total of ten electrons: two are in its innermost 1 s orbital and eight fill its second shell (two each in the 2 s and three p orbitals); thus, it is an inert gas and energetically stable as a single atom that will rarely form a chemical bond with other atoms. Larger elements have additional orbitals, making up the third electron shell. While the concepts of electron shells and orbitals are closely related, orbitals provide a more accurate depiction of the electron configuration of an atom because the orbital model specifies the different shapes and special orientations of all the places that electrons may occupy.

Video clip

Electron Orbital animation.

Watch this visual animation to see the spatial arrangement of the p and s orbitals.

Potassium has an atomic number of 19. What is its electron configuration?

  1. shells 1 and 2 are full, and shell 3 has nine electrons
  2. shells 1, 2 and 3 are full and shell 4 has three electrons
  3. shells 1, 2 and 3 are full and shell 4 has one electron
  4. shells 1, 2 and 3 are full and no other electrons are present

C

Chemical reactions and molecules

All elements are most stable when their outermost shell is filled with electrons according to the octet rule. This is because it is energetically favorable for atoms to be in that configuration and it makes them stable. However, since not all elements have enough electrons to fill their outermost shells, atoms form chemical bonds with other atoms thereby obtaining the electrons they need to attain a stable electron configuration. When two or more atoms chemically bond with each other, the resultant chemical structure is a molecule. The familiar water molecule, H 2 O, consists of two hydrogen atoms and one oxygen atom; these bond together to form water, as illustrated in [link] . Atoms can form molecules by donating, accepting, or sharing electrons to fill their outer shells.

In the first image, an oxygen atom is shown with six valence electrons. Four of these valence electrons form pairs at the top and right sides of the valence shell. The other two electrons are alone on the bottom and left sides. A hydrogen atom sits next to each the lone electron of the oxygen. Each hydrogen has only one valence electron. An arrow indicates that a reaction takes place. After the reaction, in the second image, each unpaired electron in the oxygen joins an electron from one of the hydrogen atoms so that the valence rings are now connected together. The bond that forms between oxygen and hydrogen can also be represented by a dash.
Two or more atoms may bond with each other to form a molecule. When two hydrogens and an oxygen share electrons via covalent bonds, a water molecule is formed.

Chemical reactions occur when two or more atoms bond together to form molecules or when bonded atoms are broken apart. The substances used in the beginning of a chemical reaction are called the reactants (usually found on the left side of a chemical equation), and the substances found at the end of the reaction are known as the products (usually found on the right side of a chemical equation). An arrow is typically drawn between the reactants and products to indicate the direction of the chemical reaction; this direction is not always a “one-way street.” For the creation of the water molecule shown above, the chemical equation would be:

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Source:  OpenStax, Chemistry of life: bis2a modules 2.0 to 2.3 (including appendix i and ii). OpenStax CNX. Jun 15, 2015 Download for free at https://legacy.cnx.org/content/col11826/1.1
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