Organic Models 10

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Experiment Organic Models 10 Introduction Organic chemistry is the study of carbon containing compounds. Hydrocarbons are compounds composed of hydrogen and carbon. Depending upon the number of carbon atoms, there may be many possibilities for the structures of these compounds. Linear Cyclic Aliphatic Hydrocarbons Hydrocarbons are classified as either aliphatic or aromatic. Aliphatic compounds are broken down by bond types: Alkanes (single bonds), Alkenes (double bonds) and Alkynes (triple bonds). The molecular formula for these hydrocarbons is determined by the following formulas: Alkane (CnH2n+2 ), Alkene (CnH2n), Alkyne ( CnH2n-2). 1 It is possible to get more than one structure for the same molecular formula. These structures are called isomers. A structural isomer is one in which the attachments of the atoms are different than another structure of the same molecular formula. A stereoisomer is one that has the same attachment but a different spatial relationship between the atoms (mirror images). In this lab, you will build organic models and study the effects of bonding in each compound. Equipment and Materials Organic Model Kit Procedure Obtain an organic model kit. Part I – Valence Bond Theory Construct with a molecular model kit and draw the following hydrocarbons: Alkane CnH2n+2 Alkene CnH2n Alkyne CnH2n-2 C2H6 C2H4 C2H2 For each: State the electron geometry about the carbon atoms (linear, trigonal planar, tetrahedral). State the expected bond angles. State the expected hybridization of carbon (sp, sp2, sp3). 2 Use partial orbital diagrams to show how the atomic orbitals of oxygen lead to hybridization. Example: O2 2p _↑↓_ _↑_ _↑_ 2p _↑_ → sp2 _↑↓_ _↑↓_ _↑_ 2s _↑↓_ O Atom Ground-State O Atom Hybridized Molecular Oxygen: O=O Part II – Isomers a) Build and draw the possible structural isomers of the following hydrocarbons: C4H10 (2 isomers) C5H12 (3 isomers) b) Build and draw the possible stereoisomers (2 isomers or enantiomers) of the following: CHIBrCl 3 .

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