Everything about Molecular Formula totally explained
A
chemical formula is an easy way of expressing information about the
atoms that constitute a particular
chemical compound. A chemical formula is also a short way of showing how a chemical reaction occurs. For
molecular compounds it's also known as the
molecular formula, and identifies each constituent
element by its
chemical symbol and indicates the number of atoms of each element found in each discrete
molecule of that compound. If a molecule contains more than one atom of a particular element, this quantity is indicated using a
subscript after the chemical symbol (although 19th-century books often used superscripts). For
ionic compounds and other non-molecular substances, the subscripts indicate the ratio of elements in the
empirical formula.
This system for writing chemical formulas was invented by the 19th-century Swedish chemist
Jons Jakob Berzelius.
Molecular and structural formula
For example
methane, a simple molecule consisting of one
carbon atom bonded to four
hydrogen atoms, has the chemical formula:
» CH
4
and
glucose with six carbon atoms, twelve hydrogen atoms and six
oxygen atoms has the chemical formula:
» C
6H
12O
6.
A chemical formula supplies information about the types and spatial arrangement of
bonds in the chemical, though it doesn't necessarily specify the exact
isomer. For example
ethane consists of two carbon atoms single-bonded to each other, with each carbon atom having three hydrogen atoms bonded to it. Its chemical formula can be rendered as CH
3CH
3. In
ethylene there's a double bond between the carbon atoms (and thus each carbon only has two hydrogens), therefore the chemical formula may be written: CH
2CH
2, and the fact that there's a double bond between the carbons is implicit because carbon has a valence of four. However, a more explicit and correct method is to write H
2C=CH
2 or less commonly H
2C
::CH
2. The two lines (or two pairs of dots) indicate that a double bond connects the atoms on either side of them.
A triple bond may be expressed with three lines or pairs of dots, and if there may be ambiguity, a single line or pair of dots may be used to indicate a single bond.
Molecules with multiple
functional groups that are the same may be expressed in the following way: (CH
3)
3CH. However, this implies a different structure from other molecules that can be formed using the same atoms (isomers). The formula (CH
3)
3CH implies a chain of three carbon atoms, with the middle carbon atom bonded to another carbon (
see image of 4 carbon "C" atoms),
and the remaining bonds on the carbons all leading to hydrogen atoms (
hydrogen atoms are not shown in image). However, the same number of atoms (10 hydrogens and 4 carbons, or C
4H
10) may be used to make a straight chain: CH
3CH
2CH
2CH
3.
The alkene but-2-ene has two isomers which the chemical formula CH
3CH=CHCH
3 doesn't identify. The relative position of the two methyl groups must be indicated by additional notation denoting whether the methyl groups are on the same side of the double bond (
cis or
Z) or on the opposite sides from each other (
trans or
E).
Polymers
For
polymers, parentheses are placed around the repeating unit. For example, a
hydrocarbon molecule that's described as: CH
3(CH
2)
50CH
3, is a molecule with 50 repeating units. If the number of repeating units is unknown or variable, the letter
n may be used to indicate this: CH
3(CH
2)
nCH
3.
Ions
For
ions, the charge on a particular atom may be denoted with a right-hand superscript. For example Na
+, or Cu
2+. The total charge on a charged molecule or a
polyatomic ion may also be shown in this way. For example: hydronium, H
3O
+ or sulfate, SO
42-.
For more complex ions, brackets [ ] are often used to enclose the ionic formula,
as in [B
12H
12]
2-. Parentheses can be nested inside brackets to indicate a repeating unit, as in [Co(NH
3)
6]
3+. Here (NH
3)
6 indicates that the ion contains six NH
3 groups, and [ ] encloses the entire formula of the ion with charge +3.
Isotopes
Although
isotopes are more relevant to
nuclear chemistry or
stable isotope chemistry than to conventional chemistry, different isotopes may be indicated with a left-hand
superscript in a chemical formula. For example, the phosphate ion containing radioactive phosphorus-32 is
32PO
43-. Also a study involving stable isotope ratios might include the molecule
18O
16O.
A left-hand subscript is sometimes used to indicate redundantly the
atomic number. For example,
8O
2 for dioxygen, and
168O
2 for the most abundant isotopic species of dioxygen. This is convenient when writing equations for
nuclear reactions, in order to show the balance of charge more clearly.
Empirical formula
In
chemistry, the
empirical formula of a chemical is a simple expression of the relative number of each type of atom or ratio of the elements in the compound. Empirical formulas are the standard for ionic compounds, such as CaCl
2, and for macromolecules, such as SiO
2. An empirical formula makes no reference to
isomerism, structure, or absolute number of atoms. The term
empirical refers to the process of
elemental analysis, a technique of
analytical chemistry used to determine the relative percent composition of a pure chemical substance by element.
For example
hexane has a molecular formula of C
6H
14, or structurally CH
3CH
2CH
2CH
2CH
2CH
3, implying that it has a chain structure of 6
carbon atoms, and 14
hydrogen atoms. However, the empirical formula for hexane is C
3H
7. Likewise the empirical formula for
hydrogen peroxide, H
2O
2, is simply HO expressing the 1:1 ratio of component elements.
Trapped atoms
The @ symbol ("at") indicates an atom or molecule trapped inside a cage but not chemically bound to it. This notation became popular in the 1990s with the discovery of
fullerene cages, which can trap atoms such as La to form La@C
60 or La@C
82 for example. A non-fullerene example is [As@Ni
12As
20]
3-, an ion in which one As atom is trapped in a cage formed by the other 32 atoms.
Non-stoichiometric formulas
Main article: Non-stoichiometric compound
Chemical formulas most often use
integers for each element. However, there's a whole class of compounds, called
non-stoichiometric compounds, that can't be represented by small integers. Such a formula might be written using
decimal fractions, as in Fe
0.95O, or it might include a variable part represented by a letter, as in Fe
1–xO, where x is normally much less than 1.
General forms for organic compounds
Chemical formula used for a series of compounds that differ from each other by a constant unit is called
general formula. Such a series is called the
homologous series, while its members are called homologs. The
Hill system is a common convention for writing and sorting formulas.
Hill System
The
Hill system is a system of writing
chemical formulas such that the number of
carbon atoms in a
molecule is indicated first, the number of
hydrogen atoms next, and then the number of all other
chemical elements subsequently, in
alphabetical order. When the formula contains no carbon, all the elements, including hydrogen, are listed alphabetically.
Further Information
Get more info on 'Molecular Formula'.
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