Lewis symbol

(noun)

Formalism in which the valence electrons of an atom are represented as dots.

Related Terms

  • Lewis Symbols for Atoms
  • Lewis structure
  • group
  • Noble Gases

Examples of Lewis symbol in the following topics:

  • Writing Lewis Symbols for Atoms

    • The Lewis symbol for an atom depicts its valence electrons as dots around the symbol for the element.
    • In order to write the Lewis symbol for an atom, you must first determine the number of valence electrons for that element.
    • Lewis symbols for the elements depict the number of valence electrons as dots.
    • Once you can draw a Lewis symbol for an atom, you can use the knowledge of Lewis symbols to create Lewis structures for molecules.
    • In the Lewis symbol, the electrons are depicted as two lone pair dots.
  • Representing Valence Electrons in Lewis Symbols

    • Lewis symbols use dots to visually represent the valence electrons of an atom.
    • Lewis symbols (also known as Lewis dot diagrams or electron dot diagrams) are diagrams that represent the valence electrons of an atom.
    • These Lewis symbols and Lewis structures help visualize the valence electrons of atoms and molecules, whether they exist as lone pairs or within bonds.
    • Electrons that are not in the valence level are not shown in the Lewis symbol.
    • Lewis symbols for atoms are combined to write Lewis structures for compounds or molecules with bonds between atoms.
  • Introduction to Lewis Structures for Covalent Molecules

    • The Lewis formalism used for the H2 molecule is H:H or H—H.
    • The former, known as a 'Lewis dot diagram,' indicates a pair of shared electrons between the atomic symbols, while the latter, known as a 'Lewis structure,' uses a dash to indicate the pair of shared electrons that form a covalent bond.
    • The resulting molecule that is formed is F2, and its Lewis structure is F—F.
    • We have looked at how to determine Lewis structures for simple molecules.
    • The Lewis structure for carbon dioxide, CO2, is a good example of this.
  • Lewis Acid and Base Molecules

    • Lewis bases are electron-pair donors, whereas Lewis acids are electron-pair acceptors.
    • A Lewis acid is defined as an electron-pair acceptor, whereas a Lewis base is an electron-pair donor.
    • A Lewis base, therefore, is any species that donates a pair of electrons to a Lewis acid.
    • Under the Lewis definition, hydroxide acts as the Lewis base, donating its electron pair to H+.
    • We first look at the Bronsted-Lowry theory, and then describe Lewis acids and bases according to the Lewis Theory.
  • Metal Cations that Act as Lewis Acids

    • Transition metals can act as Lewis acids by accepting electron pairs from donor Lewis bases to form complex ions.
    • The modern-day definition of a Lewis acid, as given by IUPAC, is a molecular entity—and corresponding chemical species—that is an electron-pair acceptor and therefore able to react with a Lewis base to form a Lewis adduct; this is accomplished by sharing the electron pair furnished by the Lewis base.
    • However, metal ions such as Na+, Mg2+, and Ce3+ often form Lewis adducts upon reacting with a Lewis base.
    • Ligands create a complex when forming coordinate bonds with transition metals ions; the transition metal ion acts as a Lewis acid, and the ligand acts as a Lewis base.
    • Usually, metal complexes can only serve as Lewis acids after dissociating from a more weakly bound Lewis base, often water.
  • Lewis Structures for Polyatomic Ions

    • The Lewis structure of an ion is placed in brackets and its charge is written as a superscript outside of the brackets, on the upper right.
    • The total number of electrons represented in a Lewis structure is equal to the sum of the numbers of valence electrons in each individual atom.
    • Non-valence electrons are not represented in Lewis structures.
    • Lewis structures for polyatomic ions are drawn by the same methods that we have already learned.
    • When counting electrons, negative ions should have extra electrons placed in their Lewis structures; positive ions should have fewer electrons than an uncharged molecule.
  • Formal Charge and Lewis Structure

    • In particular, chemists use Lewis structures (also known as Lewis dot diagrams, electron dot diagrams, or electron structures) to represent covalent compounds.
    • Non-valence electrons are not represented when drawing the Lewis structures.
    • In the Lewis structure, carbon should be double-bonded to both oxygen atoms.
    • Lewis structures can also be drawn for ions.
    • Sometimes multiple Lewis structures can be drawn to represent the same compound.
  • Physical Properties of Covalent Molecules

    • First described by Gilbert Lewis, a covalent bond occurs when electrons of different atoms are shared between the two atoms.
    • The Lewis bonding theory can explain many properties of compounds.
    • Lewis bonding theory states that these atoms will share their valence electrons, effectively allowing each atom to create its own octet.
    • Lewis theory also accounts for bond length; the stronger the bond and the more electrons shared, the shorter the bond length is.
    • However, the Lewis theory of covalent bonding does not account for some observations of compounds in nature.
  • Trihalides: Boron-Halogen Compounds

    • Trihalides adopt a planar trigonal structure and are Lewis acids.
    • The trihalides form planar trigonal structures and are Lewis acids because they readily form adducts with electron-pair donors, which are called Lewis bases.
    • All three lighter boron trihalides, BX3 (X = F, Cl, Br), form stable adducts with common Lewis bases.
    • Such measurements have revealed the following sequence for the Lewis acidity: BF3 < BCl3 < BBr3 (in other words, BBr3 is the strongest Lewis acid).
    • BF3 is commonly referred to as "electron deficient" because of its exothermic reactivity toward Lewis bases.
  • Acid-Base Reactions

    • Lewis bases are also Brønsted bases; however, many Lewis acids, such as BF3, AlCl3 and Mg2+, are not Brønsted acids.
    • As shown at the top of the following drawing, coordinate covalent bonding of a phosphorous Lewis base to a boron Lewis acid creates a complex in which the formal charge of boron is negative and that of phosphorous is positive.
    • Carbocations are also Lewis acids, as the reverse reaction demonstrates.
    • A terminology related to the Lewis acid-base nomenclature is often used by organic chemists.
    • Here the term electrophile corresponds to a Lewis acid, and nucleophile corresponds to a Lewis base.
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