Which of the following is soluble in water? agcl

Answer

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Hint: The solubility of an ionic compound depends on its lattice energy and hydration energy. For solubility, compare both energies for a given compound. The compound is soluble in water if and only if its lattice energy is lesser than its hydration energy.

Complete answer:
The solubility of Silver Chloride can be in two different ways. Firstly it is according to the Fajan Rule which tells us about the polarizing power of any ion . According to this polarizing power of ions depends on charge by radius ratio . For $AgCl$ , $A{g^ + }$ has more polarizing power and thus as a result covalent character is developed in the compound. We can also say $AgCl$ has become non polar in nature. Since water is polar so it will dissolve only polar compounds .Hence $AgCl$ is insoluble in water.
Secondly , the solubility of a compound can be explained on the basis of its lattice energy and hydration energy. In the case of $AgCl$ the attraction between the $AgCl$ molecule itself is greater than attraction between $AgCl$ and water . Thus the hydration enthalpy of the ${\text{ aq}}{\text{. }}AgCl$ is not sufficient to overcome the lattice enthalpy of its ions.
Thus we can say that $AgCl$ is insoluble in water.

Note:
$NaCl$ is soluble in water whereas $AgCl$ don’t .This is explained by Fajan Rule . Also $KCl$ is soluble in water too. The solubility product also helps in knowing the solubility of the given compound. The solubility product of $AgCl$ in water is $1.7{\text{ }} \times {\text{ 1}}{{\text{0}}^{ - 10}}{\text{ mo}}{{\text{l}}^2}{\text{ d}}{{\text{m}}^{ - 6}}$ .

Solubility Product

The Solubility Product Expression

Silver chloride is so insoluble in water (.0.002 g/L) that a saturated solution contains only about 1.3 x 10-5 moles of AgCl per liter of water.

	H2O
AgCl(s)		Ag+(aq)	+	Cl-(aq)

Strict adherence to the rules for writing equilibrium constant expressions for this reaction gives the following result.

(Water isn't included in the equilibrium constant expression because it is neither consumed nor produced in this reaction, even though it is a vital component of the system.)

The [Ag+] and [Cl-] terms represent the concentrations of the Ag+ and Cl- ions in moles per liter when this solution is at equilibrium. The third term

The concentration of solid AgCl can be calculated from its density and the molar mass of AgCl.

This quantity is a constant, however. The number of moles per liter in solid AgCl is the same at the start of the reaction as it is when the reaction reaches equilibrium.

Since the [AgCl] term is a constant, which has no effect on the equilibrium, it is built into the equilibrium constant for the reaction.

[Ag+][Cl-] = Kc x [AgCl]

This equation suggests that the product of the equilibrium concentrations of the Ag+ and Cl- ions in this solution is equal to a constant. Since this constant is proportional to the solubility of the salt, it is called the solubility product equilibrium constant for the reaction, or Ksp.

Ksp = [Ag+][Cl-]

The Ksp expression for a salt is the product of the concentrations of the ions, with each concentration raised to a power equal to the coefficient of that ion in the balanced equation for the solubility equilibrium.

The Relationship Between Ksp And the Solubility of a Salt

Ksp is called the solubility product because it is literally the product of the solubilities of the ions in moles per liter. The solubility product of a salt can therefore be calculated from its solubility, or vice versa.

Photographic films are based on the sensitivity of AgBr to light. When light hits a crystal of AgBr, a small fraction of the Ag+ ions are reduced to silver metal. The rest of the Ag+ ions in these crystals are reduced to silver metal when the film is developed. AgBr crystals that do not absorb light are then removed from the film to "fix" the image.

Example: Let's calculate the solubility of AgBr in water in grams per liter, to see whether AgBr can be removed by simply washing the film.

We start with the balanced equation for the equilibrium.

	H2O
AgBr(s)		Ag+(aq)	+	Br-(aq)

We then write the solubility product expression for this reaction.

Ksp = [Ag+][Br-] = 5.0 x 10-13

One equation can't be solved for two unknowns

[Ag+] = [Br-]

Substituting this equation into the Ksp expression gives the following result.

[Ag+]2 = 5.0 x 10-13

Taking the square root of both sides of this equation gives the equilibrium concentrations of the Ag+ and Br- ions.

[Ag+] = [Br-] = 7.1 x 10-7M

Once we know how many moles of AgBr dissolve in a liter of water, we can calculate the solubility in grams per liter.

The solubility of AgBr in water is only 0.00013 gram per liter. It therefore isn't practical to try to wash the unexposed AgBr off photographic film with water.

Solubility product calculations with 1:1 salts such as AgBr are relatively easy to perform. In order to extend such calculations to compounds with more complex formulas we need to understand the relationship between the solubility of a salt and the concentrations of its ions at equilibrium. We will use the symbol Cs to describe the amount of a salt that dissolves in water.

Practice Problem 2:

Several compounds were studied as possible sources of the fluoride ion for use in toothpaste. Write equations that describe the relationship between the solubility of CaF2 and the equilibrium concentrations of the Ca2+ and F- ions in a saturated solution as a first step toward evaluating its use as a fluoridating agent.

Click here to check your answer to Practice Problem 2

The techniques used in the preceding practice problems are also valid for salts that contain more positive ions than negative ions.

Common Misconceptions About Solubility Product Calculations

Let's focus on one step in Practice Problem 4. We started with the solubility product expression for Ag2S.

Ksp = [Ag+]2[S2-]

We then substituted the relationship between the concentrations of these ions and the solubility of the salt into this equation.

[2 Cs]2[Cs] = 6.3 x 10-50

When they see this for the first time, students often ask: "Why did you double the Ag+ ion concentration and then square it? Aren't you counting this term twice?"

This question results from confusion about the symbols used in the calculation. Remember that the symbol Cs in this equation stands for the solubility of Ag2S in moles per liter. Since we get two Ag+ ions for each Ag2S formula unit that dissolves in water, the Ag+ ion concentration at equilibrium is twice the solubility of the salt, or 2 Cs. We square the Ag+ ion concentration term because the equilibrium constant expression for this reaction is proportional to the product of the concentrations of the three products of the reaction.

Ksp = [Ag+][Ag+][S2-]

It is just more convenient to write this equation in the condensed form.

Ksp = [Ag+]2[S2-]

Another common mistake in solubility product calculations occurs when students are asked to write an equation that describes the relationship between the concentrations of the Ag+ and S2- ions in a saturated Ag2S solution. It is all too easy to look at the formula for this compound

[S2-] = 2 [Ag+]

This seems reasonable to some, who argue that there are twice as many Ag+ ions as S2- ions in the compound. But the equation is wrong. Because two Ag+ ions are produced for each S2- ion, there are twice as many silver ions as sulfide ions in this solution. This solution is correctly described by the following equation.

[Ag+] = 2 [S2-]

How can you avoid making this mistake? After you write the equation that you think describes the relationship between the concentrations of the ions, try it to see if it works. Suppose just enough Ag2S dissolved in water to give two S2- ions. How many Ag+ ions would you get? Four. If you get the right answer when you substitute this concrete example into your equation, it must be written correctly.

Using Ksp As A Measure Of the Solubility of a Salt

The value of Ka for an acid is proportional to the strength of the acid.

If we find the following Ka values in a table, we can immediately conclude that formic acid is a stronger acid than acetic acid.

The same can be said about values of Kb.

The following base-ionization equilibrium constants imply that methylamine is a stronger base than ammonia.

Unfortunately, there is no simple way to predict the relative solubilities of salts from their Ksp's if the salts produce different numbers of positive and negative ions when they dissolve in water.

The Role of the Ion Product (Qsp) In Solubility Calculations

Consider a saturated solution of AgCl in water.

	H2O
AgCl(s)		Ag+(aq)	+	Cl-(aq)

Because AgCl is a 1:1 salt, the concentrations of the Ag+ and Cl- ions in this solution are equal.

Saturated solution of AgCl in water:

[Ag+] = [Cl-]

Imagine what happens when a few crystals of solid AgNO3 are added to this saturated solution of AgCl in water. According to the solubility rules, silver nitrate is a soluble salt. It therefore dissolves and dissociates into Ag+ and NO3- ions. As a result, there are two sources of the Ag+ ion in this solution.

AgNO3(s)		Ag+(aq)	+	NO3-(aq)

	H2O
AgCl(s)		Ag+(aq)	+	Cl-(aq)

Adding AgNO3 to a saturated AgCl solution therefore increases the Ag+ ion concentrations. When this happens, the solution is no longer at equilibrium because the product of the concentrations of the Ag+ and Cl- ions is too large. In more formal terms, we can argue that the ion product (Qsp) for the solution is larger than the solubility product (Ksp) for AgCl.

Qsp = (Ag+)(Cl-) > Ksp

The ion product is literally the product of the concentrations of the ions at any moment in time. When it is equal to the solubility product for the salt, the system is at equilibrium.

The reaction eventually comes back to equilibrium after the excess ions precipitate from solution as solid AgCl. When equilibrium is reestablished, however, the concentrations of the Ag+ and Cl- ions won't be the same. Because there are two sources of the Ag+ ion in this solution, there will be more Ag+ ion at equilibrium than Cl- ions:

Saturated solution of AgCl to which AgNO3 has been added:

[Ag+] > [Cl-]

Now imagine what happens when a few crystals of NaCl are added to a saturated solution of AgCl in water. There are two sources of the chloride ion in this solution.

	H2O
NaCl(s)		Na+(aq)	+	Cl-(aq)

	H2O
AgCl(s)		Ag+(aq)	+	Cl-(aq)

Once again, the ion product is larger than the solubility product.

Qsp = (Ag+)(Cl-) > Ksp

This time, when the reaction comes back to equilibrium, there will be more Cl- ion in the solution than Ag+ ion.

Saturated solution of AgCl to which NaCl has been added:

[Ag+] < [Cl-]

The figure below shows a small portion of the possible combinations of the Ag+ and Cl- ion concentrations in an aqueous solution. Any point along the curved line in this graph corresponds to a system at equilibrium, because the product of the Ag+ and Cl- ion concentrations for these solutions is equal to Ksp for AgCl.

Point A represents a solution at equilibrium that could be produced by dissolving two sources of the Ag+ ion

Any point that is not along the solid line in the above figure represents a solution that is not at equilibrium. Any point below the solid line (such as Point D) represents a solution for which the ion product is smaller than the solubility product.

If more AgCl were added to the solution at Point D, it would dissolve.

If Qsp < Ksp:

AgCl(s) Ag+(aq) + Cl-(aq)

Points above the solid line (such as Point E) represent solutions for which the ion product is larger than the solubility product.

The solution described by Point E will eventually come to equilibrium after enough solid AgCl has precipitated.

If Qsp > Ksp:

Ag+(aq) + Cl-(aq) AgCl(s)

Which compound is soluble in water AgCl?

Why is AgCl most soluble in water?

Is agno3 and AgCl soluble in water?

What is AgCl most soluble in?