1 / 24

Chemical Bonding Lewis Structures

Chemical Bonding Lewis Structures. Forming Chemical Bonds. According to the Lewis model an atom may lose or gain enough electrons to acquire a filled valence shell and become an ion. An ionic bond is the result of the force of attraction between a cation and an anion.

enrico
Télécharger la présentation

Chemical Bonding Lewis Structures

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Chemical BondingLewis Structures

  2. Forming Chemical Bonds • According to the Lewis model • an atom may lose or gain enough electrons to acquire a filled valence shell and become an ion. An ionic bond is the result of the force of attraction between a cation and an anion. • an atom may share electrons with one or more other atoms to acquire a filled valence shell. A covalentbond is the result of the force of attraction between two atoms that share one or more pairs of electrons. Material from karentimberlake.com and H. Stephen Stoker

  3. Ionic CompoundsVsCovalent(Molecules) Compounds

  4. Ionic Compounds • Made up of a metal and a non-metal • Have a difference in electronegativity of more than 1.7 (Figure 20 pg. 161) • Formed from ions • Electrons are transferred

  5. Covalent Molecules • Made up of two non-metals • Have a difference in electronegativity of less than 1.7 (Figure 20 pg. 161) • Ions are not formed • Electrons are shared

  6. Bond Polarity: Nonpolar Nonpolar covalent bond • Electrons are shared between atoms with the same electronegativity values. • Difference = 0 • Examples: N2 Br2

  7. Bond Polarity: Polar Polar covalent bond • Electrons are shared between different nonmetal atoms Examples: O-Cl O-S N-Cl

  8. Chemical Bonding: The Covalent Bond Model • Fig. 5.12 (a) In the nonpolar covalent bond present, there is a symmetrical distribution of electron density. (b) In the polar covalent bond present, electron density is displaced because of its electronegativity.

  9. Valence electrons for Elements Recall that the valence electrons for the elements can be determined based on the elements position on the periodic table. Lewis Dot Symbol

  10. Lewis Structures • Find your element on the periodic table. • Determine the number of valence electrons. • This is how many electrons you will draw.

  11. Lewis Structures • Find out which group (column) your element is in. • This will tell you the number of valence electrons your element has. • You will only draw the valence electrons. www.chem4kids.com

  12. Lewis Structures • Write the element symbol. • Carbon is in the 4th group, so it has 4 valence electrons. • Starting at the right, draw 4 electrons, or dots, counter-clockwise around the element symbol. C

  13. Lewis Structures • Check your work. • Using your periodic table, check that Carbon is in the 4th group. • You should have 4 total electrons, or dots, drawn in for Carbon. C

  14. Lewis Structures On your worksheet, try these elements on your own: • H • P • Ca • Ar • Cl • Al C

  15. Lewis Structures On your worksheet, try these elements on your own: • H • P • Ca • Ar • Cl • Al H

  16. Lewis Structures On your worksheet, try these elements on your own: • H • P • Ca • Ar • Cl • Al P

  17. Lewis Structures On your worksheet, try these elements on your own: • H • P • Ca • Ar • Cl • Al Ca

  18. Lewis Structures On your worksheet, try these elements on your own: • H • P • Ca • Ar • Cl • Al Ar

  19. Lewis Structures On your worksheet, try these elements on your own: • H • P • Ca • Ar • Cl • Al Cl

  20. Lewis Structures On your worksheet, try these elements on your own: • H • P • Ca • Ar • Cl • Al Al

  21. H a l o g e n s F , B r , C l , I C a l c o g e n s O , S N i t r o g e n N , P C a r b o n C , S i Valence electrons and number of bonds  Number of bonds elements prefers depending on the number of valence electrons. In general - # C o v a l e n t B o n d s* F a m i l y  X 1 bond often  2 bond often O  3 bond often N  4 bond always C The above chart is a guide on the number of bonds formed by these atoms.

  22. . . Lewis Structure, Octet Rule Guidelines When compounds are formed they tend to follow the Octet Rule. Octet Rule: Atoms will share electrons (e-) until it is surrounded by eight valence electrons. Rules of the (VSEPR) game- i) The Octet Rule works mostly for second period elements. Many exceptions especially with 3rd period elements (d-orbitals) ii) H prefers 2 e- (electron deficient) iii) :C: N: :O: :F: 4 unpaired 3unpaired 2unpaired 1unpaired up = unpaired e- 4 bonds 3 bonds 2 bonds 1 bond O=C=O NN O = O F - F iv) H & F are terminal in the structural formula (Never central) . . . . . .

  23. N O O Cl H O O H Se O O F H C H H H O O H C C O H H O S O H H O Atomic Connectivity The atomic arrangement for a molecule is usually given. CH2ClFHNO3CH3COOH H2Se H2SO4 O3 In general when there is a single central atom in the molecule, CH2ClF, SeCl2, O3 (CO2, NH3, PO43-), the central atom is the first atom in the chemical formula. Except when the first atom in the chemical formula is Hydrogen (H) or fluorine (F). In which case the central atom is the second atom in the chemical formula. Find the central atom for the following: 1) H2O a) H b) O 2) PCl3 a) P b) Cl 3) SO3 a) S b) O 4) CO32- a) C b) O 5) BeH2 a) Be b) H 6) IO3- a) I b) O

  24. Lewis Structures

More Related