Chapter 2 STRUCTURE AND PROPERTIES OF ORGANIC MOLECULES Chapter 2: Structure and Properties of Organic Molecules Helpful web site:

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Presentation transcript:

Chapter 2 STRUCTURE AND PROPERTIES OF ORGANIC MOLECULES Chapter 2: Structure and Properties of Organic Molecules Helpful web site:

LINEAR COMBINATION OF ATOMIC ORBITALS (LCAO) Atomic orbitals can combine via addition or subtraction (hence, linear combination) and form: MOLECULAR ORBITALS, if the starting atomic orbitals belong to different atoms HYBRID ORBITALS, if the starting atomic orbitals belong to the same atom GENERAL RULE: The number of new orbitals (molecular or hybrid) is ALWAYS EQUAL to the number of starting orbitals Chapter 2: Structure and Properties of Organic Molecules

 - and  *- molecular orbitals Chapter 2: Structure and Properties of Organic Molecules

 -BONDS AND  -BONDS  -bonds can form by the combination of: a.Two s-orbitals: b. Two p-orbitals: c. One s- and one p-orbital: Chapter 2: Structure and Properties of Organic Molecules

 -BONDS AND  -BONDS 2.  -bonds form via interaction of p-orbitals only. Chapter 2: Structure and Properties of Organic Molecules

 -BONDS AND  -BONDS IMPORTANT NOTES: 1.s-orbitals, due to their spherical symmetry, cannot participate in the formation of  -orbitals. 2.The first bond between any pair of atoms is ALWAYS a  -bond. 3. Only ONE  -bond can be formed between any pair of two atoms. The rest (if any) are  -bonds. Chapter 2: Structure and Properties of Organic Molecules

PREDICTIONS BASED ON ELECTRONIC STRUCTURE OF CARBON 1.There is one 2s and three 2p orbitals, to form four bonds total. It would be therefore expected that one of the bonds would be different from the other three. 2.The 2s orbital is spherical (non-directional). The 2p orbitals are perpendicular to each other. One would therefore expect that the newly formed bonds would be at a 90o angle. BOTH PREDICTIONS ARE FALSE!!!!! Chapter 2: Structure and Properties of Organic Molecules

HYBRIDIZATION AND MOLECULAR SHAPES o o o methane tetrahedral ethylene planar acetylene linear Chapter 2: Structure and Properties of Organic Molecules o

SEVERAL WAYS TO REPRESENT METHANE Chapter 2: Structure and Properties of Organic Molecules

ETHANE Chapter 2: Structure and Properties of Organic Molecules

ISOMERS 1.Constitutional (structural) isomers. Same molecular formula, but different structures. 2.Stereoisomers. Same molecular formula, same structure, different orientation of atoms or groups in space. Chapter 2: Structure and Properties of Organic Molecules

THE IMPORTANCE OF SHAPE IN INTERMOLECULAR INTERACTIONS Chapter 2: Structure and Properties of Organic Molecules

THE IMPORTANCE OF SHAPE IN INTERMOLECULAR INTERACTIONS Chapter 2: Structure and Properties of Organic Molecules

THE HYDROGEN BOND Chapter 2: Structure and Properties of Organic Molecules

THE HYDROGEN BOND Chapter 2: Structure and Properties of Organic Molecules