The Ksp vale for PbI 2 solution should be calculate, when it has 5 .0×10 -3 M [Pb 2+ ] and [I - ] = 1 .3 ×10 -3 M Concept Introduction: Solubility product constant: The equilibrium constant of a more soluble ionic compound in water at the higher solubility is known as solubility product constant. The equilibrium constant of more soluble ionic compound is given by Ksp and it is expressed by product of multiplication of number of each ion present in the compound rise to the power of number respective ion present in the compound to give a maximum solubility of the compound. M m X x (s) ⇌ mM n+ (aq) + xX y- (aq) K sp = [M n+ ] m ×[X y- ] x
The Ksp vale for PbI 2 solution should be calculate, when it has 5 .0×10 -3 M [Pb 2+ ] and [I - ] = 1 .3 ×10 -3 M Concept Introduction: Solubility product constant: The equilibrium constant of a more soluble ionic compound in water at the higher solubility is known as solubility product constant. The equilibrium constant of more soluble ionic compound is given by Ksp and it is expressed by product of multiplication of number of each ion present in the compound rise to the power of number respective ion present in the compound to give a maximum solubility of the compound. M m X x (s) ⇌ mM n+ (aq) + xX y- (aq) K sp = [M n+ ] m ×[X y- ] x
Solution Summary: The author explains that the equilibrium constant of a more soluble ionic compound in water is known as solubility product constant.
The Ksp vale for PbI2 solution should be calculate, when it has 5.0×10-3 M [Pb2+] and [I-] = 1.3 ×10-3 M
Concept Introduction:
Solubility product constant:
The equilibrium constant of a more soluble ionic compound in water at the higher solubility is known as solubility product constant.
The equilibrium constant of more soluble ionic compound is given by Ksp and it is expressed by product of multiplication of number of each ion present in the compound rise to the power of number respective ion present in the compound to give a maximum solubility of the compound.
MmXx(s)⇌ mMn+(aq) + xXy-(aq)Ksp = [Mn+]m×[Xy-]x
(b)
Interpretation Introduction
Interpretation:
The concentration of [I-] in PbI2 solution should be calculate that has [Pb2+] = 2.5 ×10-4M.
Concept Introduction:
Solubility product constant:
The equilibrium constant of a more soluble ionic compound in water at the higher solubility is known as solubility product constant.
The equilibrium constant of more soluble ionic compound is given by Ksp and it is expressed by product of multiplication of number of each ion present in the compound rise to the power of number respective ion present in the compound to give a maximum solubility of the compound.
MmXx(s)⇌ mMn+(aq) + xXy-(aq)Ksp = [Mn+]m×[Xy-]x
(c)
Interpretation Introduction
Interpretation:
The concentration of [Pb2+] in PbI2 solution should be calculate that has [I−] = 2.5 ×10-4M.
Concept Introduction:
Solubility product constant:
The equilibrium constant of a more soluble ionic compound in water at the higher solubility is known as solubility product constant.
The equilibrium constant of more soluble ionic compound is given by Ksp and it is expressed by product of multiplication of number of each ion present in the compound rise to the power of number respective ion present in the compound to give a maximum solubility of the compound.
A particular saturated solution of PbI2(s) and [Pb2+] = 5.0 x 10-3M and [I-] = 1.3 x 10-3 a. What is the value of Ksp?
Wifey?:
What is the Ksp for a compound with generic formula A3X2 if the concentration of X3- ions in a solution saturated with the compound in water is 2.80 x 10-2 M.
A.
1.18x10-3
B.
1.51x10-11
C.
4.65x10-7
D.
1.16x10-7
E.
5.81x10-8
Zach Childress:
What
What is the solubility of Sr(IO₃)₂ in a solution that contains 0.0300 M Sr²⁺ ions? (Ksp of Sr(IO₃)₂ is 1.14×10⁻⁷)
What is the solubility of Sr(IO₃)₂ in a solution that contains 0.0550 M IO₃⁻ ions? (Ksp of Sr(IO₃)₂ is 1.14×10⁻⁷)
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, chemistry and related others by exploring similar questions and additional content below.