Chemical bonds holding atoms together within molecules have bond energies of 150-500 kJ/mol.  Hydrogen bonding intermolecular attractions between molecules are normally in the 10-25 kJ/mol range, while London dispersion forces and dipole-dipole interactions are typically near 5 kJ/mol.

1. For a temperature of 298 K, calculate the fraction of molecules that have a kinetic energy greater than 200 kJ/mol.
2. For a temperature of 298 K, calculate the fraction of molecules that have a kinetic energy greater than 15 kJ/mol.
3. For a temperature of 1000K, calculate the fraction of molecules that have a kinetic energy greater than 15 kJ/mol
4. For a temperature or 298 K, calculate the fraction of molecules that have a kinetic energy greater than 5 kJ/mol.
5. Determine the ratio of the fraction of molecules with at least 5 kJ/mol of kinetic energy to the fraction having 15kJ/mol.  Explain the significance of your answer.
6. Determine the ratio of the fraction of molecules at 1000 K with at least 15 kJ/mol of kinetic energy to the fraction at 298 K having at least 15kJ/mol.  Explain the significance of your answer.
7. Tabulate all your results clearly

Show the hydrogen bonding intermolecular forces between two acetic acid molecules by showing all bonds in each of the molecules, by showing the important partial charges that occur and by showing and explaining the specific hydrogen bonding interactions that occur between these molecules.

Three prominent COX-2 inhibitors (Vioxx, Celebrex, and Bextra) have structures published on PubChem that can be accessed through the course medlinks page.  Draw the structures of each of these three molecules and show, using arrows, the specific atoms that can serve as either hydrogen bond donors or acceptors.