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Objectives  When you complete this presentation, you will be able to …  distinguish between the melting points and boiling points of molecular compounds.

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Presentation on theme: "Objectives  When you complete this presentation, you will be able to …  distinguish between the melting points and boiling points of molecular compounds."— Presentation transcript:

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2 Objectives  When you complete this presentation, you will be able to …  distinguish between the melting points and boiling points of molecular compounds and ionic compounds.  describe the information provided by a molecular formula.

3 Introduction  Molecular compounds are like the combinations we can make from a Tinker-Toy set:  There are a certain number of hub pieces that are different colors.  There are a certain number of connecting pieces.  Likewise, we have limits on the number and kinds of …  atoms that we can use to make molecular compounds  bonds that we can use to join the atoms together

4 Molecules and Compounds  Matter in nature takes on many forms.  Noble gases exist as individual atoms.  They are monoatomic.  They have very low melting points and boiling points.  We just learned about ionic compounds and metallic compounds.  They exist as ions in a crystalline structure.  They have high melting points and boiling points.  We will now learn about a different kind of matter that is much more varied in its properties.  This kind of matter is called a molecular compound.

5 Molecules and Compounds  Molecular compounds are bound together by sharing electrons between atoms.  The bond formed is called a covalent bond.  The neutral compounds formed with covalent bonds are called molecules.  Molecules formed from two atoms are called diatomic molecules.  HCl H2H2 O2O2

6 Molecules and Compounds  All of the molecules of a given molecular compound are all the same.  All of the molecules in water are H 2 O.  All of the molecules in carbon dioxide are CO 2.  Ionic compounds are not the same as molecular compounds.  For example, there is no such thing as a CaCl 2 molecule.  In general, molecular compounds tend to have relatively lower melting points and boiling points that ionic compounds.  This mean that covalent bonds are weaker than ionic bonds.

7 Molecular Formulas  A molecular formula is the chemical formula of a molecular compound.  The molecular formula tells us exactly how many of each type of atom a molecule contains.  Each molecule of water, H 2 O, contains two hydrogen atoms and one oxygen atom.  Each molecule of glucose, C 6 H 12 O 6, contains six carbon atoms, twelve hydrogen atoms, and 6 oxygen atoms.  A molecular formula has the total number of atoms in a molecule – it is not a lowest whole number ratio.

8 Molecular Formulas  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.

9 Molecular Formulas  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  For example: the molecular formula for ammonia, NH 3, does not show the distribution of atoms in space.

10  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  For example: the molecular formula for ammonia, NH 3, does not show the distribution of atoms in space. Molecular Formulas NH 3 Molecular formula

11  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  For example: the molecular formula for ammonia, NH 3, does not show the distribution of atoms in space. Molecular Formulas H−N−H H. − NH 3 Molecular formula Structural formula

12  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  For example: the molecular formula for ammonia, NH 3, does not show the distribution of atoms in space. Molecular Formulas H−N−H H. − NH 3 Molecular formula Structural formula Perspective drawing

13  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  For example: the molecular formula for ammonia, NH 3, does not show the distribution of atoms in space. Molecular Formulas H−N−H H. − NH 3 Molecular formula Structural formula Perspective drawing Space-filling molecular model

14  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  For example: the molecular formula for ammonia, NH 3, does not show the distribution of atoms in space. Molecular Formulas H−N−H H. − NH 3 Molecular formula Structural formula Perspective drawing Space-filling molecular model Ball-and-stick molecular model

15  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  We can look at other molecules to see the three dimensional arrangement of atoms vs. the molecular formulas. Molecular Formulas

16  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  We can look at other molecules to see the three dimensional arrangement of atoms vs. the molecular formulas. Molecular Formulas Water (H 2 O)

17  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  We can look at other molecules to see the three dimensional arrangement of atoms vs. the molecular formulas. Molecular Formulas Water (H 2 O)

18  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  We can look at other molecules to see the three dimensional arrangement of atoms vs. the molecular formulas. Molecular Formulas Water (H 2 O) HH − − O

19  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  We can look at other molecules to see the three dimensional arrangement of atoms vs. the molecular formulas. Molecular Formulas Water (H 2 O)Carbon dioxide (CO 2 ) HH − − O

20  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  We can look at other molecules to see the three dimensional arrangement of atoms vs. the molecular formulas. Molecular Formulas Water (H 2 O)Carbon dioxide (CO 2 ) HH − − O

21  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  We can look at other molecules to see the three dimensional arrangement of atoms vs. the molecular formulas. Molecular Formulas Water (H 2 O)Carbon dioxide (CO 2 ) HH − − O O=C=O

22  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  We can look at other molecules to see the three dimensional arrangement of atoms vs. the molecular formulas. Molecular Formulas Water (H 2 O)Carbon dioxide (CO 2 )Ethanol (C 2 H 6 O) HH − − O O=C=O

23  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  We can look at other molecules to see the three dimensional arrangement of atoms vs. the molecular formulas. Molecular Formulas Water (H 2 O)Carbon dioxide (CO 2 )Ethanol (C 2 H 6 O) HH − − O O=C=O

24  A molecular formula does not tell us anything about the actual three-dimensional structure of the compound.  We can look at other molecules to see the three dimensional arrangement of atoms vs. the molecular formulas. Molecular Formulas Water (H 2 O)Carbon dioxide (CO 2 )Ethanol (C 2 H 6 O) HH − − O O=C=O CH 3 OH − − CH 2

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