Lewis Dot Structure Generator

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Lewis structure of sulfate ion is drawn in this tutorial step by step. Total valence electrons concept is used to draw the lewis structure of SO42-. In lewis structure of sulfate ion, there should be charges on several atoms due to -2 charge.

Electron Distributions Into Shells for the First Three Periods. A chemical element is identified by the number of protons in its nucleus, and it must collect an equal number of electrons if it is to be electrically neutral. Search by Structure or Substructure. Upload a structure file or draw using a molecule editor.


Sulfate ion | sulfate ion | SO42-

Sulfate ion is one of the oxyanion of sulfur. Sulfur is at +6 oxidation state in SO42-. Also, sulfate ion has a -2 charge.


Lewis structure of SO42-

There are two S=O bonds and two S-O bonds in sulfate ion lewis structure. Sulfur atom is the center atom and four oxygen atoms are located around sulfur atom. There are no lone pairs in the last shell of sulfur atom.


Steps of drawing lewis structure of SO42-

Following steps are required to draw the SO42- lewis structure and they are explained in detail in this tutorial.

Lewis dot structure generator atoms
  1. Find total number of electrons of the valance shells of sulfur and oxygen atoms
  2. Total electrons pairs
  3. Center atom selection
  4. Put lone pairs on atoms
  5. Check the stability and minimize charges on atoms by converting lone pairs to bonds.
Lewis Dot Structure Generator

Drawing correct lewis structure is important to draw resonance structures correctly


Total number of electrons of the valance shells of SO42-

Both Sulfur and oxygen atoms are located at VIA group in the periodic table. So, oxygen and sulfur atoms have six electrons in their valence shell.


  • Total valence electrons given by sulfur atom = 6

There are four oxygen atoms in SO42- ion, Therefore

  • Total valence electrons given by oxygen atoms = 6 *4 = 24

There are -2 charge on SO42- ion. Therefore there are two more electrons which comes from outside to contribute to the total valence electrons.


  • Total valence electrons = 6 + 24 + 2 = 32

Total valence electrons pairs

Total valance electrons pairs = σ bonds + π bonds + lone pairs at valence shells

Total electron pairs are determined by dividing the number total valence electrons by two. For, SO42- ion, Total pairs of electrons are 16.


Center atom of SO32- ion

To be the center atom, ability of having greater valance is important. Therefore sulfur has the more chance to be the center atom (See the figure) because sulfur can show valance of 6. Maximum valnce of oxygen is two. So, now we can build a sketch of SO42- ion.


Lone pairs on atoms

  • There are already four S-O bonds in the above sketch. Therefore only twelve (16-4 = 12) valence electrons pairs are remaining.
  • First, mark those twelve valence electrons pairs as lone pairs on outside atoms (on oxygen atoms). One oxygen atom will take three lone pairs following the octal rule (oxygen atom cannot keep more than eight electrons in its valence shell).
  • For four oxygen atoms, twelve electrons pairs are spent. Now all electron pairs are spent. There is no electron pairs to mark on sulfur atom.

Charges on atoms

After, marking electron pairs on atoms, we should mark charges of each atom. Each oxygen atom will get a -1 charge and sulfur atom get a +2 charge. The overall charge of ion is ( -1*4 + (+2) ) = -2.


Check the stability and minimize charges on atoms by converting lone pairs to bonds

When charges exist everywhere (on atoms) in the ion or molecule, that structure is not stable. We should try to reduce charges on atoms as much as possible. Now, we are going to learn how these facts will affect on sulfate ion.

  • Oxygen atoms should hold negative charges because electronegativity of oxygen is higher than sulfur. Otherwise, we can say, ability of holding negative charges is great in oxygen atoms than sulfur atoms.
  • The drawn structure is not a stable one because all atoms have charges.
  • Now, we should try to minimize charges by converting lone pair or pairs to bonds. So convert one lone pair of one oxygen atom to make a new S-O bond.
  • Now there is a double bond between sulfur atom and one oxygen atom. Now, there are three S-O single bonds between sulfur atom and other three oxygen atoms.

You see charges of atoms are reduced. Now, there is no charge in one oxygen atom and charge of sulfur atom is reduced from +2 to +1. So we have an stable ion than out previous one.


Can I reduce charges of atoms furthermore?

You should know, sulfur can keep more than eight electrons in its last shell. Therefore we can convert one more lone pair of another oxygen atom to a bond.

Structure

In new structure, charges of atoms are reduced than previous structure. Now there are no any charge on sulfur atom and two oxygen atom. Also, only two oxygen atoms have -1 negative charges. Now you understand this structure of SO42- is more stable than previous structures. So, this structure has more chance to be the lewis structure of SO42- ion.

Lewis Dot Structure Generator Ch4


Lewis structure of SO42- (sulfate) ion



Lewis Dot Structure Generator Atoms

Questions

Lewis Dot Structure Generator


the total number of electrons in the valence shells of all atoms in the ion SO42- is?

There are 32 electrons in valence shells of all atoms in the ion SO42- ion.



Is number of lone pairs similar in S2O332- and SO432- lewis structures?

Yes. Compare both lewis structures. Otherwise, we can think an oxygen atom of sulfate ion is replaced by a sulfur atom. Because both sulfur and oxygen belongs to group 6, their valence electrons in last shell is similar.



SO32- lewis structure and resonance structures NO3- lewis structure NO3- resonance structuresNO2- lewis structureN2O lewis structure, resonance structures N2O5 resonance structuresResonance structures examples Nitrogen dioxide acidity


Related lewis structures

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Lewis Dot Structure Generator Free

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