11.5 Q & K
LO 6.2 I can, given a
manipulation of a chemical reaction or set of reactions (e.g., reversal
of reaction or additions of two reactions), determine the effects of that manipulation of Q or K.
LO 6.4 I can, given a set of initial conditions (concentrations or partial pressures) and the equilibrium constant, K, use the tendency of Q to approach K to predict and justify the prediction as to whether the reaction will proceed toward products or reactants as equilibrium is approached.
LO 6.10 I can connect LeChatelier's principle of the comparison of Q to K by explaining the effects of the stress on Q and K.
Groundwork for
LO 6.6 I can, given a set of initial conditions (concentrations or partial pressures)
LO 6.11 I can generate or use a particulate representation of an acid (strong or weak or polyprotic) and strong base to explain the species that will have large versus small concentrations at equilibrium.
LO 6.4 I can, given a set of initial conditions (concentrations or partial pressures) and the equilibrium constant, K, use the tendency of Q to approach K to predict and justify the prediction as to whether the reaction will proceed toward products or reactants as equilibrium is approached.
LO 6.10 I can connect LeChatelier's principle of the comparison of Q to K by explaining the effects of the stress on Q and K.
Groundwork for
LO 6.6 I can, given a set of initial conditions (concentrations or partial pressures)
LO 6.11 I can generate or use a particulate representation of an acid (strong or weak or polyprotic) and strong base to explain the species that will have large versus small concentrations at equilibrium.
|
|
11.6 Equilibrium Calculations
LO 6.4 I can, given a set of
initial conditions (concentrations or partial pressures) and the
equilibrium constant, K, use the tendency of Q to approach K to predict
and justify the prediction as to whether the reaction will proceed
toward products or reactants as equilibrium is approached.
LO 6.5 I can, given data (tabular, graphical, etc.) from which the state of a system at equilibrium can be obtained, calculate the equilibrium constant, K.
LO 6.6 I can, given a set of initial conditions (concentrations or partial pressures) and the equilibrium constant, K, use stoichiometric relatioships and hte law of mass action (Q equals K at equilibrium) to determine qualitatively and/or quantitatively the conditions at equilibrium for a system involving a single reversible reaction.
LO 6.7 I am able, for a reversible reaction that has a large or small K, to determine which chemical species will have a very large versus very small concentrations at equilibrium.
LO 6.5 I can, given data (tabular, graphical, etc.) from which the state of a system at equilibrium can be obtained, calculate the equilibrium constant, K.
LO 6.6 I can, given a set of initial conditions (concentrations or partial pressures) and the equilibrium constant, K, use stoichiometric relatioships and hte law of mass action (Q equals K at equilibrium) to determine qualitatively and/or quantitatively the conditions at equilibrium for a system involving a single reversible reaction.
LO 6.7 I am able, for a reversible reaction that has a large or small K, to determine which chemical species will have a very large versus very small concentrations at equilibrium.
|
11.7 Free Energy & Equilibrium
LO 6.25 I can express the equilibrium constant in terms of delta G and RT and use this relationship to estimate the magnitude of K and, consequently, the thermodynamic favorability of the process.
|
Quiz #2: Sect. 9.4-9.6