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Lewis Dot Structures.

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Presentation on theme: "Lewis Dot Structures."— Presentation transcript:

1 Lewis Dot Structures

2 Lewis Dot Diagrams… Gilbert Lewis came up with a different model, and he only showed the valence e- in it. His model is called the Lewis dot diagram He put dots around the symbols so that we can see just the valence electrons for the elements (we can easily see which e- are going to react)

3 The red dots show you the valence electrons in each element’s atoms

4 Lewis Dot Structures

5 See the difference??... Lewis just shows the valence e-
P: 11 N:12 Na Bohr model of Sodium Atom Lewis Structure of Sodium Atom

6 8 is the # most atoms want – it’s stable – like a noble gas
Lewis Dot Structures Lewis dot structures are really simple – they are just the valence e- represented as dots around an element. 2 electrons together is called a lone pair. The # of valence e- is … 8 8 is the # most atoms want – it’s stable – like a noble gas

7 How to draw …

8 Try some … Remember, up to 4 e-, you put separately on each side of the symbol, once you get to 5, you have to start pairing up. 1) Magnesium 2) Nitrogen 3) Flourine 4) Argon Bonding pair N Mg F Ar

9 So what happens when atoms meet?
When 2 atoms move close together, their valence electrons interact, and they form a chemical bond between them if they are a good pair (more stable together than apart) Having a full valence shell is what each element wants! So it will bind with other elements that make that happen!

10 Lewis Diagrams of ions Lewis diagrams make drawing ions, and ionic bonds much less work than Bohr diagrams. For positive ions, one electron dot is removed from the valence shell for each positive charge of the ion. For negative ions, one electron dot is added to each valence shell for each negative charge of the ion. Square brackets are placed around each ion to indicate transfer of electrons (c) McGraw Hill Ryerson 2007 See page 179 2+ • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • Be Cl Cl Be Cl Cl Be Cl Each beryllium has two electrons to transfer away, and each chlorine wants one more electron Since Be2+ wants to donate 2 electrons and each Cl– wants to accept only one, two Cl– ions are necessary Beryllium chloride

11 Lewis Diagrams of covalent bonds
Lewis diagrams of covalent bonds are also very easy. Like Bohr diagrams, valence electrons are drawn to show sharing of electrons. All atoms wish to have a full valence shell (1st orbit=2 e-, 2nd=8e-) The shared pairs of electrons are usually drawn as a straight line H is happy because now it has access to 2e- a full outer shell F is happy now because it has access to 8e- - a full outer shell SHARING IS CARING!! (c) McGraw Hill Ryerson 2007 See page 179

12 Lewis Diagrams of diatomic molecules
Diatomic molecules: 2 of the same element are bonded Eg. Cl2, F2, O2, etc.. Try 2 Oxygens together (remember they both want 8, so how are they going to share?) • • • • • • • • • • • • • • • • • • • • • • • • O O O O O O (c) McGraw Hill Ryerson 2007 Several non-metals join to form diatomic molecules Valence electrons are shared, here in two pairs! This is drawn as a double bond See page 180

13 Things to note… Every electron wants to have a full outer orbit – then they are stable – so… if an electron has it’s 1st orbit full and stable – it will have 2 valence e- if an electron has it’s 2nd , or 3rd orbit full and stable – it will have 8 valence e- (we call that a Stable octet) Everything wants to bind together to get a maximum of 8 valence e- shared between them

14 Ionic Compounds 2+ 2- + O O 1. Mg Mg

15 + + + H F H F N H N H H H H H C H C H H 1.  2.  3. 
Covalent Compounds + H 1. F H F + N H 2. N H H H H + H 3. C H C H H

16 + F F F F  Diatomic Compounds
Remember when it’s a diatomic compound – you draw the 2 lines between them! (Symbolizing the 4 electrons sharing!!)

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