1 the structure and bonding of io 3 - an example of the use of lewis structures and vsepr theory...
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The Structure and Bonding of
IO3-
An example of the use of Lewis Structures and VSEPR Theory
Lecturer: Dr. Andreas LemmererLecturer: Dr. Andreas Lemmerer
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What type of compound is IO3- ?
• According to IUPAC Nomenclature, it is a Polyatomic Ion. • Polyatomic ions contain more than one kind of atom.• In particular, it is a oxyanion that contains a nonmetal (I) and
oxygen.• Oxyanions (polyatomic anions containing oxygen) are named
with -ite or –ate as a base ending, depending on the number of oxygen atoms bonded to the nonmetal.
• IO3- has one atom of iodine and three atoms of oxygen.
• Since iodine is a halogen and hence in the VIIA Group, the oxyanion with three O atoms is given the -ate ending and hence it’s name is IODATE.
• cf. Group VA and VIA oxyanions with the -ate ending have four oxygen atoms (phosphate (PO4
3-) , and group IVA oxyanions have three oxygen atoms (carbonate CO3
2-)
IUPAC NomenclatureIUPAC Nomenclature
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Structure and Bonding of IO3-Structure and Bonding of IO3-
To determine the structure and the bonding of the iodate anion, we To determine the structure and the bonding of the iodate anion, we will make use of the OCTET RULE:will make use of the OCTET RULE:
Atoms in the second period are limited to eight valence electrons, Atoms in the second period are limited to eight valence electrons, and there are exceptions to the octet rule for atoms in the higher and there are exceptions to the octet rule for atoms in the higher periods, i.e. atoms from the 3rd period onwards can accommodate periods, i.e. atoms from the 3rd period onwards can accommodate more than an octet.more than an octet.
Note that O is in the second period and I is in the fifth period.Note that O is in the second period and I is in the fifth period.
The Octet Rule: The Octet Rule: Atoms tend to Atoms tend to gain, lose, or share electrons until gain, lose, or share electrons until they are surrounded by eight valence electrons.they are surrounded by eight valence electrons.Or:Or:In compound formation an atom gains or loses electrons, or shares In compound formation an atom gains or loses electrons, or shares pairs of electrons, until its valence shell has eight electrons.pairs of electrons, until its valence shell has eight electrons.
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Lewis StructuresLewis Structures- Lewis structures are representations of molecules showing all
electrons, bonding and nonbonding.
- Electron pairs shared between atoms are shown as a line “-” andElectron pairs shared between atoms are shown as a line “-” and
valence electrons around the atom as dots “•”.valence electrons around the atom as dots “•”.
- There is a sequence of five steps required to get to the correct - There is a sequence of five steps required to get to the correct Lewis Structure of a compound.Lewis Structure of a compound.
Cl Cl H FH O
H
H N H
HCH
H
H
H
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Writing Lewis Structure for IO3-Writing Lewis Structure for IO3-
1. Find the sum of valence electrons of all atoms in the polyatomic ion or molecule. If it is an anion, add one
electron for each negative charge.
If it is a cation, subtract one electron for each positive charge.
IO3-
7 + 3(6) + 1 = 26
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Writing Lewis StructuresWriting Lewis Structures
2. The central atom is the least electronegative element that isn’t hydrogen.
Connect the outer atoms to it by single bonds.
Keep track of the electrons:
26 6 = 20
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Writing Lewis StructuresWriting Lewis Structures
3. Fill the octets of the outer atoms.
Keep track of the electrons:
26 6 = 20 18 = 2
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Writing Lewis StructuresWriting Lewis Structures
4. Fill the octet of the central atom.
Keep track of the electrons:
26 6 = 20 18 = 2 2 = 0
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Writing Lewis StructuresWriting Lewis Structures
• Then assign formal charges.For each atom, count the electrons in lone pairs and half the
electrons it shares with other atoms.Subtract that from the number of valence electrons for that
atom: The difference is its formal charge.
• The best Lewis structure……is the one with the fewest charges.…puts a negative charge on the most electronegative atom.
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5. Arrange the pairs of electrons until the formal charges are at a minimum, taking into account the net charge on the compound.
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Resonance of IO3-Resonance of IO3-
• One Lewis structure cannot accurately depict an anion such as iodate.
• We use multiple structures, resonance structures, to describe the molecule.
• The electrons are not localized, but rather are delocalized.
Experimental Observation: All three I-O bonds are approximately equivalent, Experimental Observation: All three I-O bonds are approximately equivalent, about 1.8 about 1.8 Å. I-O is about 2.2 Å. I-O is about 2.2 Å Å and I=O 1.7 and I=O 1.7 Å.Å.
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• What Determines the Shape of a Molecule?
• Simply put, electron pairs, whether they are bonding or nonbonding, repel each other.
• By assuming the electron pairs are placed as far as possible from each other, we can predict the shape of the molecule.
non-bonding electronsnon-bonding electrons
bonding electronsbonding electrons
The Shape of the Iodate AnionThe Shape of the Iodate Anion
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• We can refer to the electron pairs (bonding/non-bonding) as electron domains.
• In a double or triple bond, all electrons shared between those two atoms are on the same side of the central atom; therefore, they count as one electron domain.
• This molecule has four electron domains, i.e. 4 areas of electron-density around I.
Electron DomainsElectron Domains
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is based on the main idea that “The best arrangement of a given number of electron domains is the one that minimizes the repulsions among them.”
Valence Shell Electron Pair RepulsionVSEPR Theory
Valence Shell Electron Pair RepulsionVSEPR Theory
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• Non-bonding e-pairs are physically larger than bonding pairs.
• Therefore, their repulsions are greater; this tends to decrease bond angles in a molecule. The final geometry or shape of the molecule depends on the relative number of bonding and non-bonding domains.
Bonding vs Non-bonding domainsBonding vs Non-bonding domains
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• There are three molecular geometries according to VSEPR Theory:Tetrahedral, if all are bonding pairsTrigonal pyramidal if one is a nonbonding pairBent if there are two nonbonding pairs
Tetrahedral Electron DomainTetrahedral Electron Domain
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Finally, the Shape:Finally, the Shape:
Trigonal Pyramidal:Trigonal Pyramidal:••••I
O OO
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Tetrahedral Electron Domain
• There are three molecular geometries:Tetrahedral, if all are bonding pairsTrigonal pyramidal if one is a nonbonding pairBent if there are two nonbonding pairs
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Trigonal Bipyramidal Electron Domain
• There are two distinct positions in this geometry:AxialEquatorial
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Trigonal Bipyramidal Electron Domain
Lower-energy conformations result from having nonbonding electron pairs in equatorial, rather than axial, positions in this geometry.
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Trigonal Bipyramidal Electron Domain
• There are four distinct molecular geometries in this domain:Trigonal bipyramidalSeesaw T-shapedLinear
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Octahedral Electron Domain
• All positions are equivalent in the octahedral domain.
• There are three molecular geometries:OctahedralSquare pyramidalSquare planar