HBrO2 (bromous acid) has one hydrogen atom, one bromine atom, and two oxygen atoms.
In HBrO2 Lewis structure, there is one single bond and one double bond around the bromine atom, with two oxygen atoms attached to it. The oxygen atom with a single bond is attached with one hydrogen atom, on both oxygen and bromine atoms, there are two lone pairs.
Alternative method: Lewis structure of HBrO2
Rough sketch
- First, determine the total number of valence electrons
In the periodic table, hydrogen lies in group 1, bromine lies in group 17, and oxygen lies in group 16.
Hence, hydrogen has one valence electron, bromine has seven valence electrons, and oxygen has six valence electrons.
Since HBrO2 has one hydrogen atom, one bromine atom, and two oxygen atoms, so…
Valence electrons of one hydrogen atom = 1 × 1 = 1
Valence electrons of one bromine atom = 7 × 1 = 7
Valence electrons of two oxygen atoms = 6 × 2 = 12
And the total valence electrons = 1 + 7 + 12 = 20
Learn how to find: Hydrogen valence electrons, Bromine valence electrons, and Oxygen valence electrons
- Second, find the total electron pairs
We have a total of 20 valence electrons. And when we divide this value by two, we get the value of total electron pairs.
Total electron pairs = total valence electrons ÷ 2
So the total electron pairs = 20 ÷ 2 = 10
- Third, determine the central atom
Here hydrogen can not be the central atom. Because the central atom is bonded with at least two other atoms, and hydrogen has only one electron in its last shell, so it can not make more than one bond.
Now we have to choose the central atom from bromine and oxygen. Place the least electronegative atom at the center.
Since bromine is less electronegative than oxygen, assume that the central atom is bromine.
Therefore, place bromine in the center and hydrogen and oxygen on either side.
- And finally, draw the rough sketch
Lone pair
Here, we have a total of 10 electron pairs. And three bonds are already marked. So we have to only mark the remaining seven electron pairs as lone pairs on the sketch.
Also remember that hydrogen is a period 1 element, so it can not keep more than 2 electrons in its last shell. Bromine is a period 4 element, so it can keep more than 8 electrons in its last shell. And oxygen is a period 2 element, so it can not keep more than 8 electrons in its last shell.
Always start to mark the lone pairs from outside atoms. Here, the outside atoms are oxygens and hydrogen. But no need to mark on hydrogen, because hydrogen already has two electrons.
So for left oxygen, there are three lone pairs, and for right oxygen and bromine, there are two lone pairs.
Mark the lone pairs on the sketch as follows:
Formal charge
Use the following formula to calculate the formal charges on atoms:
Formal charge = valence electrons – nonbonding electrons – ½ bonding electrons
For hydrogen atom, formal charge = 1 – 0 – ½ (2) = 0
For bromine atom, formal charge = 7 – 4 – ½ (4) = +1
For left oxygen atom, formal charge = 6 – 6 – ½ (2) = -1
For right oxygen atom, formal charge = 6 – 4 – ½ (4) = 0
Here, both bromine and oxygen atoms have charges, so mark them on the sketch as follows:
The above structure is not a stable Lewis structure because both bromine and oxygen atoms have charges. Therefore, reduce the charges (as below) by converting lone pairs to bonds.
Convert a lone pair of the left oxygen atom to make a new Br — O bond with the bromine atom as follows:
Final structure
The final structure of HBrO2 includes a central bromine atom linked to two oxygen atoms, one of which is further bonded to a hydrogen atom. In this configuration, the bromine atom satisfies the octet rule by forming a double covalent bond with one oxygen atom, a single covalent bond with the hydroxyl (OH) group, and retaining two lone pairs. Within this layout, the double-bonded oxygen atom maintains two lone pairs, while the oxygen atom in the hydroxyl group reaches a stable octet by forming two single bonds and retaining two lone pairs. The hydrogen atom fulfills its stable duet through its single bond. This arrangement represents the most stable state for the molecule because it results in a formal charge of zero for every atom involved. Accordingly, this specific electronic distribution serves as the definitive and most accurate Lewis representation of bromous acid.
Next: HBrO3 Lewis structure
External links
- https://brainly.com/question/7273171
- https://study.com/academy/answer/draw-the-lewis-structure-for-hbro2-and-assign-formal-charges-to-each-atom.html
- https://www.numerade.com/ask/question/draw-the-structure-of-bromous-acid-hbro2-optimize-formal-charges-03059/
- https://www.chegg.com/homework-help/questions-and-answers/draw-structure-bromous-acid-hbro2hbro2-optimize-formal-charges-draw-structure-bromous-acid-q60366858
Deep
Learnool.com was founded by Deep Rana, who is a mechanical engineer by profession and a blogger by passion. He has a good conceptual knowledge on different educational topics and he provides the same on this website. He loves to learn something new everyday and believes that the best utilization of free time is developing a new skill.