Lewis Structures & VSEPR

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Presentation transcript:

Lewis Structures & VSEPR

Lewis Structure Lewis Structures – shows how the _______________ are arranged among the atoms of a molecule There are rules for Lewis Structures that are based on the formation of a _______________ Atoms want to achieve a _______________ configuration

Octet & Duet Rules Octet Rule – atoms want to have _______________ valence electrons Duet Rule – H is the exception. It wants to be like He & is stable with only _______________ valence electrons

Steps for drawing Lewis Structures Sketch a simple structure with a central atom and all attached atoms Add up all of the valence electrons for each individual atom If you are drawing a Lewis structure for a negative ion add that many electrons to create the charge If you are drawing a Lewis structure for a positive ion subtract that many electrons to create the charge

Steps for drawing Lewis Structures Subtract 2 electrons for each bond drawn Complete the octet on the central atom & subtract those electrons Complete the octet on the surrounding atoms & subtract those electrons Get your final number If 0  you are done! If +  add that many electrons to the central atom If -  need to form multiple bonds to take away that many electrons

Bond Types ____________ bonds () – single covalent bond ____________ bonds () – occur when multiple bonds are formed Single bond – sigma Double bond – 1 sigma & 1 pi Triple bond – 1 sigma & 2 pi

Bond length & Strength As the number of bonds increases, the bond length ____________ The shorter the bond, the ____________ the bond

Examples CCl4

Examples HF

Examples NH3

Examples NO+

Exceptions to the octet rule Sometimes the central atom violates the octet rule and has more or less than 8 valence electrons Keep using the same rules to draw Lewis Structures

Examples SF4

Examples ICl3

Examples XeF4

Examples ICl-

Resonance When more than one Lewis Structure can be written for a particular molecule _______________ – all possible Lewis structures that could be formed The actual structure is the _______________ of all of the structures You MUST show all structures!

Examples SO3

Examples NO2-

Examples NO3-

Formal Charge Formal charges can be used in 1 of 2 ways… Suggest where the __________ are Help select the most __________ structure from a set of resonance structures

1 - Suggest where the charges are Formal charge =

Example Calculate the formal charge on each element in the carbonate ion CO3 2-

2 - Help select the most plausible structure from a set of resonance structures When choosing the most likely resonance structure Most likely – All formal charges are __________ Next likely – All formal charges add up to __________ Next likely – Formal charges are closest to __________ Next likely – __________ charge is on most electronegative atom

Example Which of the following resonance structures is most likely for CH2O and why?

Another Example Which is the most likely structure for N2O?

VSEPR Theory VSEPR Theory ________________________ The structure around a given atom is determined by minimizing the _______________ The electrons and elements bonded to the central atom want to be _______________ as possible

VSEPR Steps Draw the Lewis structure for the molecule Count the total number of things that are around the central atom to determine the electron pair geometry Imagine that the lone pairs of electrons are invisible and describe the molecular shape

2 Electron Pairs If there are 2 things attached to the central atom, the shape is linear Bond angle = 180°

3 Electron Pairs If there are 3 electron pairs the shape will be trigonal planar Bond angle = 120°

3 electron pairs Now imagine that you have 3 electron pairs, but one is just a lone pair (invisible) what would it look like then?

4 electron pairs If there are 4 electron pairs, the shape will be tetrahedral Bond angle = 109.5°

4 electron pairs What if 1 of the electron pairs is a lone pair (invisible)? What would it look like then? Trigonal Pyramidal

4 electron pairs What if there are 2 lone pairs (invisible)? What would it look like then? bent

5 electron pairs If there are 5 electron pairs the shape will be Trigonal Bipyramidal Bond angles = 90º & 120º

5 electron pairs What is there is 1 lone pair (invisible) Seesaw

5 electron pairs What is there are 2 lone pairs (invisible) T-shaped

6 electron pairs If there are 6 electron pairs the shape will be octahedral Bond angle = 90°

6 electron pairs What if there is 1 lone pair (invisible)? Square pyramidal

6 electron pairs What if there are 2 lone pairs (invisible) Square planar