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Example Questions
Example Question #5 : Inhibitors
__________ inhibitors bind to the active site and __________ inhibitors alter the binding affinity of substrate and catalyst.
Competitive . . . noncompetitive
Noncompetitive . . . competitive
Competitive . . . competitive
Noncompetitive . . . noncompetitive
Competitive . . . competitive
There are two main types of inhibitors. Competitive inhibitors bind to the active site of the catalyst and prevent substrate from binding. This phenomenon causes a decreasing in the binding affinity of substrate and catalyst. However, competitive inhibitors can be overcome by adding excess substrates. The substrates will dissociate the competitive inhibitor and carry out the reaction; therefore, the reaction can still be carried out at a faster rate and the maximum rate of reaction is not altered.
Noncompetitive inhibitors bind to the catalyst at an allosteric site. They alter the conformation of the active site and prevent substrate binding. They cannot be overcome by addition of excess substrate; therefore, they lower the maximum rate of reaction.
Example Question #1 : Reaction Equilibrium
Consider the following reaction.
A researcher adds equal volumes of substance A and substance B together. What is the ratio of concentration of C to concentration of D at equilibrium?
Cannot be determined from the given information
To solve this question we need to use the definition of equilibrium constant. The equilibrium constant, , for this reaction is
For a given value, the concentration of C and D would be the same. The stoichiometric coefficients of C and D are both 1; therefore, the amount of C and D produced would be the same and would depend on the limiting reagent. We do not know what the limiting reagent is (it could be A or B) and cannot determine the absolute concentrations of C and D; however, we can determine the relative concentrations. The concentration of C and D are the same and the ratio is 1:1.
Example Question #2 : Reaction Equilibrium
The reaction quotient of a reaction is twice as much as its equilibrium constant. What can you conclude about this reaction?
The forward reaction is occurring at a faster rate
Both forward and reverse reactions are occurring at a faster rate
The reverse reaction is occurring at a faster rate
Both forward and reverse reactions are occurring at a slower rate
The forward reaction is occurring at a faster rate
The reaction quotient, , is calculated the same way as equilibrium constant; however, the concentrations used are derived from a nonequilbrium state. Consider the reaction below.
If this reaction is NOT in equilibrium, then the reaction quotient is defined as
If it’s at equilibrium then equilibrium constant is defined as
Note that reaction quotient cannot be calculated when reaction is in equilibrium.
The question states that the reaction quotient is twice as much as the equilibrium constant. Since we can calculate reaction quotient, this reaction is not in equilbrium. The numerator for is higher than the numerator of (because reaction quotient is higher). There are more products created than reactants in the current nonequilbrium state and, therefore, the forward reaction is happening faster than the reverse reaction.
Example Question #3 : Reaction Equilibrium
Which of the following is true about equilibrium?
I. Enzymes increase the equilibrium constant
II. Equilibrium constant is only dependent on temperature
III. At equilibrium, there are no new products produced
I only
I and III
II and III
II only
II only
Chemical equilibrium is the state during which the rate of forward reaction equals the rate of reverse reaction. Equilibrium properties of a reaction determine how much products is produced. It’s important to remember that enzymes alter the rate of a reaction; however, they DO NOT alter the equilibrium. This means that enzymes speed up a reaction; however, they do not increase the amount of products produced.
ONLY increasing or decreasing temperature will alter equilibrium constant. Other factors such as concentration, volume, and pressure do not change it. Changing these other factors might shift the reaction left or right to bring the reaction back to equilibrium; however, it does not change the equilibrium constant. This means that these other factors can change the individual concentration of reactants and products at equilibrium, but they will not change the ratio of products to reactants.
As mentioned, at equilibrium the rates of forward and reverse reactions are equal. This means that new products and reactants are constantly being produced; however, there is no net production of these molecules.
Example Question #4 : Reaction Equilibrium
According to Le Chatelier’s principle, the reaction will shift to the right (towards the products) when the __________ is less than __________.
reaction quotient . . . activation energy
equilibrium constant . . . reaction quotient
reaction quotient . . . equilibrium constant
equilibrium constant . . . activation energy
reaction quotient . . . equilibrium constant
Le Chatelier’s principle states that a chemical system will respond to changes in the environment and maintain equilibrium by changing the direction of reaction. A reaction will shift to the right if the ratio of concentration of products to reactants goes down and will shift to the left if the ratio goes up. Reaction quotient, , characterizes the state of a reaction in a nonequilbrium state. It is calculated the same way as equilibrium constant.
The question is asking about a shift to the right. Reaction shifts to the right (and approaches equilbrium) when the nonequilbrium reaction has more reactants than products. This occurs when the ratio of products to reactants () is lower than the ratio of products to reactants at equilibrium ().
Example Question #4 : Equilibrium Constant And Reaction Quotient
What is the value of the equilibrium constant for the following reaction?
There is not enough information to answer this question
Hess's Law allows us to combine the two given equation to create the equation that we need. Hess's Law also tells us that when combining equilibrium constants, the value is the product of K1 and K2.
Remark: a common misconception in this type of problem is to find the sum of the values. This use of Hess's Law is only valid for thermodynamic values.
Example Question #1 : Le Chatelier's Principle
Ammonia is created using the Haber-Bosch process:
A reaction vessel is used to combine the nitrogen and hydrogen gas. The reaction proceeds until the vessel is at equilibrium.
What would you predict to happen if the pressure of the vessel increases?
Changing the pressure will not alter the equilibrium
The system will shift to the left
More ammonia would be created
More nitrogen gas would be created
More ammonia would be created
According to Le Chatelier's principle, a change in pressure will cause a shift in order to counteract the pressure change. When the pressure of a vessel is increased, the side of the reaction with fewer gas molecules will be preferred in order to minimize contact between gas molecules. For this reaction, there are four gas molecules on the left side and two gas molecules on the right side. As a result, the products side will be preferred and more ammonia will be created.
Example Question #1 : Le Chatelier's Principle
Ammonia is created using the Haber-Bosch process:
A reaction vessel is used to combine the nitrogen and hydrogen gas until the vessel is at equilibrium.
What will happen to the system if ammonia is removed from the vessel?
The amount of hydrogen gas will increase
The equilibrium will shift to the left
The equilibrium will not shift
The equilibirum will shift to the right
The equilibirum will shift to the right
When a system is at equilibrium, it is possible to predict how a system will respond to sudden changes using Le Chatelier's principle. In this scenario, ammonia has been removed from the system. This will cause the reaction to produce more ammonia, and proceed to the right in order to reestablish equilibrium.
Example Question #5 : Reaction Equilibrium
Based on the given information, under what conditions should this reaction be carried out to promote the most formation of product?
High pressure, high temperature, in a vacuum
High pressure, low temperature, under a lamp
The reaction will proceed as written regardless of conditions because it is spontaneous
Low temperature, low pressure, in a semi-lit area
Low pressure, high temperature, in the dark
High pressure, low temperature, under a lamp
High pressure will favor the side of the reaction with fewer moles of gas, which in this case is the product side.
The reaction is exothermic, meaning that it generates heat. By removing heat from the reaction, we are constantly stressing the system towards the product side.
Finally, the reaction should occur under a lamp. This is due to the hv symbol above the double arrows, which signifies that light promotes the reaction. Note: had the hv symbol been below the double arrows, the reaction should have occurred in the dark.
Example Question #6 : Reaction Equilibrium
A saturated aqueous solution of calcium hydroxide is prepared. Given the information above, how will adding of affect the solubility and the of the solution?
The solubility will decrease; the will decrease
The solubility will increase; the will increase
The solubility will decrease; the will remain unchanged.
The solubility will increase; the will remain unchanged
The solubility will remain unchanged; the will remain unchanged
The solubility will decrease; the will remain unchanged.
Adding contributes ions into the solution, driving the reaction to the left, and decreasing the solubility of the calcium hydroxide. This is known as the common-ion effect. The remains unchanged. This is due to the fact that only a change in temperature can bring about a change in an equilibrium constant.
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