Chemical Equilibrium II Magnesium hydroxide. Mg(OH) 2 , is a white, partially soluble solid that is used in many antacids. The chemical equation for the dissolving of Mg(OH) 2 ( s ) in water is Mg(OH) 2 ( s ) ⇌ Mg 2+ ( a q ) + 2 OH − ( a q ) a Describe a simple experimental procedure that you could use to study this solubility equilibrium. In your experiment, how would you determine when the solution process has attained equilibrium? b Write the equilibrium-constant expression for this dissolving of magnesium hydroxide. c Suppose equilibrium has been established in a container of magnesium hydroxide in water, and you decide to add more solid Mg(OH) 2 . What would you expect to observe? What effect will this addition of Mg(OH) 2 have on the concentrations of Mg 2+ ( aq ) and OH − ( aq )? d Say you haw prepared an equilibrium solution of Mg(OH) 2 by adding pure solid Mg(OH) 2 to water. If you know the concentration of OH − ( aq ), can you determine the concentration of Mg 2+ ( aq )? If not, what information do you need that will allow you to determine the answer? e You slowly add OH − from another source (say, NaOH) to an equilibrium mixture of Mg(OH) 2 and water. How do you expect the concentration of the Mg 2+ ( aq ) to change? What might you be able to observe happening to the Mg(OH) 2 ( s ) as you add the OH − ? f Next you remove some, but not all, of the Mg(OH) 2 ( s ) from the mixture. How will this affect the concentrations of the Mg 2+ ( aq ) and OH − ( aq )? g If someone hands you a container of Mg(OH) 2 ( aq ) and there is no solid Mg(OH) 2 present, is this solution at equilibrium? If it is not at equilibrium, what could you add to or remove from the container that would give an equilibrium system? h Consider an individual OH − ( aq ) ion in an Mg(OH) 2 solution at equilibrium. If you could follow this ion over a long period of time, would you expect it always to remain as an OH − ( aq ) ion, or could it change in some way?
Chemical Equilibrium II Magnesium hydroxide. Mg(OH) 2 , is a white, partially soluble solid that is used in many antacids. The chemical equation for the dissolving of Mg(OH) 2 ( s ) in water is Mg(OH) 2 ( s ) ⇌ Mg 2+ ( a q ) + 2 OH − ( a q ) a Describe a simple experimental procedure that you could use to study this solubility equilibrium. In your experiment, how would you determine when the solution process has attained equilibrium? b Write the equilibrium-constant expression for this dissolving of magnesium hydroxide. c Suppose equilibrium has been established in a container of magnesium hydroxide in water, and you decide to add more solid Mg(OH) 2 . What would you expect to observe? What effect will this addition of Mg(OH) 2 have on the concentrations of Mg 2+ ( aq ) and OH − ( aq )? d Say you haw prepared an equilibrium solution of Mg(OH) 2 by adding pure solid Mg(OH) 2 to water. If you know the concentration of OH − ( aq ), can you determine the concentration of Mg 2+ ( aq )? If not, what information do you need that will allow you to determine the answer? e You slowly add OH − from another source (say, NaOH) to an equilibrium mixture of Mg(OH) 2 and water. How do you expect the concentration of the Mg 2+ ( aq ) to change? What might you be able to observe happening to the Mg(OH) 2 ( s ) as you add the OH − ? f Next you remove some, but not all, of the Mg(OH) 2 ( s ) from the mixture. How will this affect the concentrations of the Mg 2+ ( aq ) and OH − ( aq )? g If someone hands you a container of Mg(OH) 2 ( aq ) and there is no solid Mg(OH) 2 present, is this solution at equilibrium? If it is not at equilibrium, what could you add to or remove from the container that would give an equilibrium system? h Consider an individual OH − ( aq ) ion in an Mg(OH) 2 solution at equilibrium. If you could follow this ion over a long period of time, would you expect it always to remain as an OH − ( aq ) ion, or could it change in some way?
Magnesium hydroxide. Mg(OH)2, is a white, partially soluble solid that is used in many antacids. The chemical equation for the dissolving of Mg(OH)2(s) in water is
Mg(OH)
2
(
s
)
⇌
Mg
2+
(
a
q
)
+
2
OH
−
(
a
q
)
a Describe a simple experimental procedure that you could use to study this solubility equilibrium. In your experiment, how would you determine when the solution process has attained equilibrium?
b Write the equilibrium-constant expression for this dissolving of magnesium hydroxide.
c Suppose equilibrium has been established in a container of magnesium hydroxide in water, and you decide to add more solid Mg(OH)2. What would you expect to observe? What effect will this addition of Mg(OH)2 have on the concentrations of Mg2+(aq) and OH−(aq)?
d Say you haw prepared an equilibrium solution of Mg(OH)2 by adding pure solid Mg(OH)2 to water. If you know the concentration of OH−(aq), can you determine the concentration of Mg2+(aq)? If not, what information do you need that will allow you to determine the answer?
e You slowly add OH− from another source (say, NaOH) to an equilibrium mixture of Mg(OH)2 and water. How do you expect the concentration of the Mg2+(aq) to change? What might you be able to observe happening to the Mg(OH)2(s) as you add the OH−?
f Next you remove some, but not all, of the Mg(OH)2(s) from the mixture. How will this affect the concentrations of the Mg2+(aq) and OH−(aq)?
g If someone hands you a container of Mg(OH)2(aq) and there is no solid Mg(OH)2 present, is this solution at equilibrium? If it is not at equilibrium, what could you add to or remove from the container that would give an equilibrium system?
h Consider an individual OH−(aq) ion in an Mg(OH)2 solution at equilibrium. If you could follow this ion over a long period of time, would you expect it always to remain as an OH−(aq) ion, or could it change in some way?
Definition Definition State where the components involved in a reversible reaction, namely reactants and product, do not change concentration any further with time. Chemical equilibrium results when the rate of the forward reaction becomes equal to the rate of the reverse reaction.
A
Predict the major products of the following reaction.
Be sure to use wedge and dash bonds to show the stereochemistry of the products when it's important, for example to distinguish between two different major
products.
+
Cl₂
2
X
Click and drag to start
drawing a structure.
C
app.aktiv.com
Predict reagents needed to complete this E2 elimination reaction.
Br
Problem 17 of 40
H3O+
A
heat
NaH
B
heat
0
D
E
(CH)COK
heat
CH₂ONa
(CH)COH
heat
Done
Please correct answer and don't use hand rating
Chapter 14 Solutions
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