Name Ch 1a, Problem Set Eight Section
Transcription
Name Ch 1a, Problem Set Eight Section
Name Section Rec TA Side 1 of 5 Ch 1a, Problem Set Eight Due Friday, November 21, 2014 at 4 PM in the Ch1a Box Problems 2 and 3 are designated (P) as “no collaboration” problems. 1. (30 Points, 5 points each) Molecular size is governed by factors including bond lengths and atomic radii. For each pair below, identify which molecule is larger. Briefly explain each decision on the basis of bond lengths, atomic radii, or both. (Note: you do not need exact numbers for this part; make qualitative arguments. You do not need to explain any trends, just cite them; therefore, limit your answer to one sentence.) a. b. c. d. e. f. O2 or O2+ HCl or HF NH3 or PH3 H2CCH2 or HCCH SiBr4 or CCl4 NO or O2 (Hint: you may be able to come up with multiple valid answers and arguments. Any one of those valid arguments will earn full credit.) P 2. (40 Points) Determining the structures of large molecules is often difficult due to free rotations around single bonds. Rotation about double bonds, however, is forbidden. Because of this, examination of the double and triple bonds in some compounds can help provide some understanding about their structure. a. (25 pts) Draw the molecules H2C=C=C=CH2 and H2C=C=C=C=CH2. For each carbon, indicate the hybridization. Label ALL of the approximate bond angles. Draw the molecules graphically showing the basic π molecular orbitals. For example: H H C H C H b. (10 pts) One of these molecules has coplanar H2C groups. Which one does, and why? (Give the physical reason, not simply the rule. Limit your answer to 3 sentences.) c. (5 pts) For the molecule that does not have coplanar H2C groups, what is the angle between the planes of the two H2C groups? Name Section Rec TA P Side 2 of 5 Ch 1a, Problem Set Eight Due Friday, November 21, 2014 at 4 PM in the Ch1a Box 3. (30 Points, 5×5 pts, 2×2.5 pts) The following diagrams illustrate pairs of atomic orbitals approaching each other to form a molecular orbital (shading indicates the relative sign of the wavefunction). Sketch the molecular orbital formed by the atomic orbitals, as shown below (i.e., do not change any of the AOs’ phases or spatial orientation). For antibonding interactions, draw a line for the antibonding node. (Note: If you determine the combination is nonbonding, then you do not need to draw anything: simply write that it is non-bonding.) Finally, indicate the type of molecular orbital (σb, σ*, πb, π*) that results. As an example: σb + a. + b. + c. + d. + e. f. g. + + Name Section Rec TA Side 3 of 5 Ch 1a, Problem Set Eight Due Friday, November 21, 2014 at 4 PM in the Ch1a Box 4. (40 Points) The formula for the conjugated alkene octatetraene is H2C(CH)6CH2. a. (8 pts) Draw the structure of octatetraene, and indicate the hybridization of each carbon atom. Try to draw the molecule (line of carbons) as straight as possible, and make the structure geometrically accurate—that is, the bonding angles you draw should be those predicted by hybridization theory. (Hint: Put a line horizontally through the molecule. When drawn geometrically accurately, the carbons should be equidistant from this line, with half on top and half on the bottom) b. (32 pts, 4 per MO) The resonance structures and basis atomic orbitals for the π molecular orbitals for H2CCHCH2 (allyl radical) are given below. Draw all eight π molecular orbitals for octatetraene in this same fashion. Indicate the phase of the orbitals and show the nodes. (Hint: the nodes will be somewhat symmetric around the E center of the molecule.) Name Section Rec TA Ch 1a, Problem Set Eight Due Friday, November 21, 2014 at 4 PM in the Ch1a Box Side 4 of 5 5. (60 Points) The cycloheptatrienyl radical, C7H7, is cyclic and sometimes found in metal chemistry. a. (10 pts) Draw the seven resonance structures for the cycloheptatrienyl radical. What is the hybridization for the seven carbons? b. (19 pts) There is a graphic device for cyclic π-bonded π MO systems that can be used to order the π molecular orbitals in energy. This is called a Frost circle. It involves inscribing the molecule point-down in a circle. Each vertex then corresponds to a π molecular orbital. For example, benzene gives the following: π* π* π* πb πb πb Draw a similar diagram for the cycloheptatrienyl radical. Label the MOs either πb or π* and fill in the π electrons. (hint: there are three π bonding orbitals) c. (21 pts) We can use the Frost circle from part b. to draw the shape of the π orbitals for our cyclic systems. As with atomic orbitals, as you add nodes to the π MOs, the energy goes up. For our benzene example, we go from zero to three angular nodes in our MOs and they go up in energy. Energy Construct such a diagram for the cycloheptatrienyl radical, showing the nodes and the sign changes for the MOs. You may draw shaded/unshaded circles at each atom rather than continuous orbitals if you find it easier, despite that not really being an MO. (Hint: the easiest way to draw your nodes is with equal angles between the nodes. So, if you had 4 nodes, you could draw them 45° from each other. Then, fill in your phases. Finally, rotate the nodes by 22.5˚ to get the degenerate wavefunction.) d. (10 pts) Use your diagram to predict the bond order (of the π system only) for the cycloheptatrienyl radical, “tropylium ion” (the cycloheptatrienyl cation), and the Name Section Rec TA Side 5 of 5 Ch 1a, Problem Set Eight Due Friday, November 21, 2014 at 4 PM in the Ch1a Box cycloheptatrienyl anion (sorry, no fun name for that one). For example, benzene has a π bond order of 3.