A biochemical reaction is at equilibrium at 300 K, with equilibrium constant Keg = 1.5. We then %3D add in some more reactants, so that the reactant concentration is doubled (i.e. Q =Keg). A. Determine AG for the reaction, in units of 1. Before the additional reactants were added. 2. After the additional reactants were added. В. If the reaction is done at constant pressure, it releases an enthalpy of AH = -2.1 After the additional reactants were added, what is the change in entropy AS of mol the reaction? C. Suppose we changed the temperature at the same time the additional reactants are addea, so that the reaction stays at equilibrium. Would we need to raise or lower the temperature of the reaction for this to be the case? You do not need to calculate any values here, you should explain your reasoning in words.

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A biochemical reaction is at equilibrium at 300 K, with equilibrium constant Keq = 1.5. We then add in some more reactants, so that the reactant concentration is doubled (i.e. Q =Keg). %3D A. Determine AG for the reaction, in units of mol 1. Before the additional reactants were added. 2. After the additional reactants were added. B. If the reaction is done at constant pressure, it releases an enthalpy of AH = -2.1 After the additional reactants were added, what is the change in entropy AS of mol the reaction? C. addea, so that the reaction stays at cquilibrium. Would we need to raise or lower the temperature of the reaction for this to be the case? You do not need to calculate any values here, you should explain your reasoning in words. Suppose we changed the temperature at the same time the additional reactants are