Precipitating silver(I) salts from the solution of barium(II) cyanate and iodide Announcing the arrival of Valued Associate #679: Cesar Manara Planned maintenance scheduled April 17/18, 2019 at 00:00UTC (8:00pm US/Eastern)I have 100 mg of a proteinase K lyophilized powder and I need to make it to a working concentration of 25 mg/mLHow to determine which salt will precipitate from a solution containing multiple ions?Is solubility in Qsp affected by coefficient?Why should I acidify twice in the procedure for qualitative analysis of chloride anions?Adding powdered Pb and Fe to a solutionApparent solubility of Ag2C2O4 in a buffer solutionFinding x and y in Pt(NH3)xClyWhat is the net ionic equation of the following?How to calculate the volume or mass of carbon dioxide gas absorbed by a calcium hydroxide solution?Precipitation of AgCl from the tap water solution of the group 2 chloride
How to deal with a team lead who never gives me credit?
Why is there no army of Iron-Mans in the MCU?
Is high blood pressure ever a symptom attributable solely to dehydration?
What would be the ideal power source for a cybernetic eye?
Sorting numerically
What do you call a plan that's an alternative plan in case your initial plan fails?
How can players work together to take actions that are otherwise impossible?
Should gear shift center itself while in neutral?
Is the Standard Deduction better than Itemized when both are the same amount?
When to stop saving and start investing?
macOS-like app switching in Plasma 5
How widely used is the term Treppenwitz? Is it something that most Germans know?
Are variable time comparisons always a security risk in cryptography code?
How is the internal pullup resistor in a microcontroller wired?
Java 8 stream max() function argument type Comparator vs Comparable
What does the "x" in "x86" represent?
What causes the vertical darker bands in my photo?
If Jon Snow became King of the Seven Kingdoms what would his regnal number be?
WAN encapsulation
Can inflation occur in a positive-sum game currency system such as the Stack Exchange reputation system?
What LEGO pieces have "real-world" functionality?
Precipitating silver(I) salts from the solution of barium(II) cyanate and iodide
Check which numbers satisfy the condition [A*B*C = A! + B! + C!]
Letter Boxed validator
Precipitating silver(I) salts from the solution of barium(II) cyanate and iodide
Announcing the arrival of Valued Associate #679: Cesar Manara
Planned maintenance scheduled April 17/18, 2019 at 00:00UTC (8:00pm US/Eastern)I have 100 mg of a proteinase K lyophilized powder and I need to make it to a working concentration of 25 mg/mLHow to determine which salt will precipitate from a solution containing multiple ions?Is solubility in Qsp affected by coefficient?Why should I acidify twice in the procedure for qualitative analysis of chloride anions?Adding powdered Pb and Fe to a solutionApparent solubility of Ag2C2O4 in a buffer solutionFinding x and y in Pt(NH3)xClyWhat is the net ionic equation of the following?How to calculate the volume or mass of carbon dioxide gas absorbed by a calcium hydroxide solution?Precipitation of AgCl from the tap water solution of the group 2 chloride
$begingroup$
Consider a $pu10.0 mL$ solution containing $pu1.0e-10 M$ each of $ceBa(CN)2$ and $ceBaI2$. If $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, will any precipitate(s) form? If yes, what compound(s) will precipitate?
$K_mathrmsp(ceAgCN) = pu6.0e-17$; $K_mathrmsp(ceAgI) = pu8.5e-17$.
The answer was only $ceAgCN$ will precipitate, but I don't understand why $ceAgI$ wouldn't precipitate as well since there is more than enough excess $ceAgNO3$ available to precipitate with both $ceI-$ and $ceCN-$?
inorganic-chemistry aqueous-solution solubility
edited 6 hours ago
andselisk
19.4k664126
asked 6 hours ago
user77021user77021
111
New contributor
user77021 is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
$endgroup$
add a comment |
$begingroup$
Consider a $pu10.0 mL$ solution containing $pu1.0e-10 M$ each of $ceBa(CN)2$ and $ceBaI2$. If $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, will any precipitate(s) form? If yes, what compound(s) will precipitate?
$K_mathrmsp(ceAgCN) = pu6.0e-17$; $K_mathrmsp(ceAgI) = pu8.5e-17$.
The answer was only $ceAgCN$ will precipitate, but I don't understand why $ceAgI$ wouldn't precipitate as well since there is more than enough excess $ceAgNO3$ available to precipitate with both $ceI-$ and $ceCN-$?
inorganic-chemistry aqueous-solution solubility
edited 6 hours ago
andselisk
19.4k664126
asked 6 hours ago
user77021user77021
111
New contributor
user77021 is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
$endgroup$
2
$begingroup$
"There is more than enough." How did you determine that with out any quantitative calculations?
$endgroup$
– Zhe
6 hours ago
$begingroup$
I did calculate that max CN- that could be precipitated as AgCN is 2 x 10-12 mol. This leaves 3.498 x10-9 mol Ag+ remaining to react with I-
$endgroup$
– user77021
6 hours ago
4
$begingroup$
Only if the concentrations are such that the solubility product exceeds $K_mathrmsp$.
$endgroup$
– Zhe
6 hours ago
add a comment |
$begingroup$
Consider a $pu10.0 mL$ solution containing $pu1.0e-10 M$ each of $ceBa(CN)2$ and $ceBaI2$. If $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, will any precipitate(s) form? If yes, what compound(s) will precipitate?
$K_mathrmsp(ceAgCN) = pu6.0e-17$; $K_mathrmsp(ceAgI) = pu8.5e-17$.
The answer was only $ceAgCN$ will precipitate, but I don't understand why $ceAgI$ wouldn't precipitate as well since there is more than enough excess $ceAgNO3$ available to precipitate with both $ceI-$ and $ceCN-$?
inorganic-chemistry aqueous-solution solubility
edited 6 hours ago
andselisk
19.4k664126
asked 6 hours ago
user77021user77021
111
New contributor
user77021 is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
$endgroup$
Consider a $pu10.0 mL$ solution containing $pu1.0e-10 M$ each of $ceBa(CN)2$ and $ceBaI2$. If $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, will any precipitate(s) form? If yes, what compound(s) will precipitate?
$K_mathrmsp(ceAgCN) = pu6.0e-17$; $K_mathrmsp(ceAgI) = pu8.5e-17$.
The answer was only $ceAgCN$ will precipitate, but I don't understand why $ceAgI$ wouldn't precipitate as well since there is more than enough excess $ceAgNO3$ available to precipitate with both $ceI-$ and $ceCN-$?
inorganic-chemistry aqueous-solution solubility
inorganic-chemistry aqueous-solution solubility
edited 6 hours ago
andselisk
19.4k664126
asked 6 hours ago
user77021user77021
111
New contributor
user77021 is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
edited 6 hours ago
andselisk
19.4k664126
asked 6 hours ago
user77021user77021
111
New contributor
user77021 is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
edited 6 hours ago
andselisk
19.4k664126
edited 6 hours ago
andselisk
19.4k664126
edited 6 hours ago
andselisk
19.4k664126
19.4k664126
asked 6 hours ago
user77021user77021
111
New contributor
user77021 is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
asked 6 hours ago
user77021user77021
111
asked 6 hours ago
user77021user77021
111
111
New contributor
user77021 is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
New contributor
user77021 is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
user77021 is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
2
$begingroup$
"There is more than enough." How did you determine that with out any quantitative calculations?
$endgroup$
– Zhe
6 hours ago
$begingroup$
I did calculate that max CN- that could be precipitated as AgCN is 2 x 10-12 mol. This leaves 3.498 x10-9 mol Ag+ remaining to react with I-
$endgroup$
– user77021
6 hours ago
4
$begingroup$
Only if the concentrations are such that the solubility product exceeds $K_mathrmsp$.
$endgroup$
– Zhe
6 hours ago
add a comment |
2
$begingroup$
"There is more than enough." How did you determine that with out any quantitative calculations?
$endgroup$
– Zhe
6 hours ago
$begingroup$
I did calculate that max CN- that could be precipitated as AgCN is 2 x 10-12 mol. This leaves 3.498 x10-9 mol Ag+ remaining to react with I-
$endgroup$
– user77021
6 hours ago
4
$begingroup$
Only if the concentrations are such that the solubility product exceeds $K_mathrmsp$.
$endgroup$
– Zhe
6 hours ago
2
2
$begingroup$
"There is more than enough." How did you determine that with out any quantitative calculations?
$endgroup$
– Zhe
6 hours ago
$begingroup$
"There is more than enough." How did you determine that with out any quantitative calculations?
$endgroup$
– Zhe
6 hours ago
$begingroup$
I did calculate that max CN- that could be precipitated as AgCN is 2 x 10-12 mol. This leaves 3.498 x10-9 mol Ag+ remaining to react with I-
$endgroup$
– user77021
6 hours ago
$begingroup$
I did calculate that max CN- that could be precipitated as AgCN is 2 x 10-12 mol. This leaves 3.498 x10-9 mol Ag+ remaining to react with I-
$endgroup$
– user77021
6 hours ago
4
4
$begingroup$
Only if the concentrations are such that the solubility product exceeds $K_mathrmsp$.
$endgroup$
– Zhe
6 hours ago
$begingroup$
Only if the concentrations are such that the solubility product exceeds $K_mathrmsp$.
$endgroup$
– Zhe
6 hours ago
add a comment |
2 Answers
2
active
oldest
votes
$begingroup$
Consider a $pu10.0 mL$ solution containing $pu1.0e-10 M$ each of $ceBa(CN)2$ and $ceBaI2$. If $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, will any precipitate(s) form? If yes, what compound(s) will precipitate?
$K_mathrmsp(ceAgCN) = pu6.0e-17$; $K_mathrmsp(ceAgI) = pu8.5e-17$.
Assuming that $ceBa(CN)2$ and $ceBaI2$ dissociate completely.
$ce[CN-]_i = [I-]_i = 2cdot10^-10$ molar
Neglecting any volume change of solution the initial concentration of $ceAg+$ will be
$ce[Ag+]_i = dfrac3.5cdot10^-9pumol0.010puL = 3.5cdot10^-7puM$
Now if both the $ceCN-$ and $ceI-$ are quantitatively removed then the same amount of $ceAg+$ must be removed.
$ce[CN-]_i + [I-]_i = 4cdot10^-10$ molar
$ce[Ag+]_f = 3.5cdot10^-7puM - 4cdot10^-10puM approx 3.5cdot10^-7puM$
So the final concentration of $ceAg+$ is essentially the same as the initial concentration. The concentration of $ceAg+$ with the Ksp's can now be used to calculated how much of the two anions can remain in solution.
The final concentration of $ceCN-$ is
$ce[CN-]_f = dfracK_spce[Ag+]_f = dfrac6.0cdot10^-173.5cdot10^-7 = pu1.7e-10$
The the final concentration of $ceI-$ is
$ce[I-]_f = dfracK_spce[Ag+]_f = dfrac8.5cdot10^-173.5cdot10^-7 = pu2.4e-10$
Conclusion:
Since $ce[CN-]_i > [CN-]_f$ some $ceAgCN$ will ppt.
Since $ce[I-]_i < [I-]_f$ no $ceAgI$ will ppt.
answered 5 hours ago
MaxWMaxW
15.7k22261
$endgroup$
add a comment |
$begingroup$
Alternative method to MaxW method:
Assume that an initial $pu10.0 mL$ solution of $pu1.0e-10 M$ in each of $ceBa(CN)2$ and $ceBaI2$ is clear (homogeneous). That means $ceBa(CN)2$ and $ceBaI2$ have dissociated completely. Thus concentrations of ions are as follows:
$$ce[CN-]_i = [I-]_i = pu2cdot10^-10 mol ! L^-1$$
Suppose when $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, no volume change has occured. Thus, the initial concentration of added ions in the solution will be:
$$ce[Ag+]_i = [NO3-]_i = dfracpu3.5cdot10^-9 molpu0.010 L = pu3.5cdot10^-7 mol ! L^-1$$
For precipitation of $ceAgCN(s)$:
$$Q_mathrmsp = ce[Ag+]_icdot ce[CN-]_i = (pu3.5cdot10^-7 mol ! L^-1)(pu2cdot10^-10 mol ! L^-1) \ = pu7.0cdot10^-17 mol^2 ! L^-2 gt K_mathrmsp(ceAgCN) = pu6.0cdot10^-17 mol^2 ! L^-2 $$
Therefore, $ceAgCN(s)$ will precipitate.
For precipitation of $ceAgI(s)$:
$$Q_mathrmsp = ce[Ag+]_icdot ce[I-]_i = (pu3.5cdot10^-7 mol ! L^-1)(pu2cdot10^-10 mol ! L^-1) \ = pu7.0cdot10^-17 mol^2 ! L^-2 lt K_mathrmsp(ceAgCN)=pu8.5cdot10^-17 mol^2 ! L^-2 $$
Therefore, $ceAgI(s)$ will not precipitate in this condition.
answered 3 hours ago
Mathew MahindaratneMathew Mahindaratne
6,328725
$endgroup$
add a comment |
Your Answer
StackExchange.ready(function()
var channelOptions =
tags: "".split(" "),
id: "431"
;
initTagRenderer("".split(" "), "".split(" "), channelOptions);
StackExchange.using("externalEditor", function()
// Have to fire editor after snippets, if snippets enabled
if (StackExchange.settings.snippets.snippetsEnabled)
StackExchange.using("snippets", function()
createEditor();
);
else
createEditor();
);
function createEditor()
StackExchange.prepareEditor(
heartbeatType: 'answer',
autoActivateHeartbeat: false,
convertImagesToLinks: false,
noModals: true,
showLowRepImageUploadWarning: true,
reputationToPostImages: null,
bindNavPrevention: true,
postfix: "",
imageUploader:
brandingHtml: "Powered by u003ca class="icon-imgur-white" href="https://imgur.com/"u003eu003c/au003e",
contentPolicyHtml: "User contributions licensed under u003ca href="https://creativecommons.org/licenses/by-sa/3.0/"u003ecc by-sa 3.0 with attribution requiredu003c/au003e u003ca href="https://stackoverflow.com/legal/content-policy"u003e(content policy)u003c/au003e",
allowUrls: true
,
onDemand: true,
discardSelector: ".discard-answer"
,immediatelyShowMarkdownHelp:true
);
);
user77021 is a new contributor. Be nice, and check out our Code of Conduct.
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
StackExchange.ready(
function ()
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fchemistry.stackexchange.com%2fquestions%2f112803%2fprecipitating-silveri-salts-from-the-solution-of-bariumii-cyanate-and-iodide%23new-answer', 'question_page');
);
Post as a guest
Required, but never shown
2 Answers
2
active
oldest
votes
2 Answers
2
active
oldest
votes
active
oldest
votes
active
oldest
votes
$begingroup$
Consider a $pu10.0 mL$ solution containing $pu1.0e-10 M$ each of $ceBa(CN)2$ and $ceBaI2$. If $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, will any precipitate(s) form? If yes, what compound(s) will precipitate?
$K_mathrmsp(ceAgCN) = pu6.0e-17$; $K_mathrmsp(ceAgI) = pu8.5e-17$.
Assuming that $ceBa(CN)2$ and $ceBaI2$ dissociate completely.
$ce[CN-]_i = [I-]_i = 2cdot10^-10$ molar
Neglecting any volume change of solution the initial concentration of $ceAg+$ will be
$ce[Ag+]_i = dfrac3.5cdot10^-9pumol0.010puL = 3.5cdot10^-7puM$
Now if both the $ceCN-$ and $ceI-$ are quantitatively removed then the same amount of $ceAg+$ must be removed.
$ce[CN-]_i + [I-]_i = 4cdot10^-10$ molar
$ce[Ag+]_f = 3.5cdot10^-7puM - 4cdot10^-10puM approx 3.5cdot10^-7puM$
So the final concentration of $ceAg+$ is essentially the same as the initial concentration. The concentration of $ceAg+$ with the Ksp's can now be used to calculated how much of the two anions can remain in solution.
The final concentration of $ceCN-$ is
$ce[CN-]_f = dfracK_spce[Ag+]_f = dfrac6.0cdot10^-173.5cdot10^-7 = pu1.7e-10$
The the final concentration of $ceI-$ is
$ce[I-]_f = dfracK_spce[Ag+]_f = dfrac8.5cdot10^-173.5cdot10^-7 = pu2.4e-10$
Conclusion:
Since $ce[CN-]_i > [CN-]_f$ some $ceAgCN$ will ppt.
Since $ce[I-]_i < [I-]_f$ no $ceAgI$ will ppt.
answered 5 hours ago
MaxWMaxW
15.7k22261
$endgroup$
add a comment |
$begingroup$
Consider a $pu10.0 mL$ solution containing $pu1.0e-10 M$ each of $ceBa(CN)2$ and $ceBaI2$. If $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, will any precipitate(s) form? If yes, what compound(s) will precipitate?
$K_mathrmsp(ceAgCN) = pu6.0e-17$; $K_mathrmsp(ceAgI) = pu8.5e-17$.
Assuming that $ceBa(CN)2$ and $ceBaI2$ dissociate completely.
$ce[CN-]_i = [I-]_i = 2cdot10^-10$ molar
Neglecting any volume change of solution the initial concentration of $ceAg+$ will be
$ce[Ag+]_i = dfrac3.5cdot10^-9pumol0.010puL = 3.5cdot10^-7puM$
Now if both the $ceCN-$ and $ceI-$ are quantitatively removed then the same amount of $ceAg+$ must be removed.
$ce[CN-]_i + [I-]_i = 4cdot10^-10$ molar
$ce[Ag+]_f = 3.5cdot10^-7puM - 4cdot10^-10puM approx 3.5cdot10^-7puM$
So the final concentration of $ceAg+$ is essentially the same as the initial concentration. The concentration of $ceAg+$ with the Ksp's can now be used to calculated how much of the two anions can remain in solution.
The final concentration of $ceCN-$ is
$ce[CN-]_f = dfracK_spce[Ag+]_f = dfrac6.0cdot10^-173.5cdot10^-7 = pu1.7e-10$
The the final concentration of $ceI-$ is
$ce[I-]_f = dfracK_spce[Ag+]_f = dfrac8.5cdot10^-173.5cdot10^-7 = pu2.4e-10$
Conclusion:
Since $ce[CN-]_i > [CN-]_f$ some $ceAgCN$ will ppt.
Since $ce[I-]_i < [I-]_f$ no $ceAgI$ will ppt.
answered 5 hours ago
MaxWMaxW
15.7k22261
$endgroup$
add a comment |
$begingroup$
Consider a $pu10.0 mL$ solution containing $pu1.0e-10 M$ each of $ceBa(CN)2$ and $ceBaI2$. If $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, will any precipitate(s) form? If yes, what compound(s) will precipitate?
$K_mathrmsp(ceAgCN) = pu6.0e-17$; $K_mathrmsp(ceAgI) = pu8.5e-17$.
Assuming that $ceBa(CN)2$ and $ceBaI2$ dissociate completely.
$ce[CN-]_i = [I-]_i = 2cdot10^-10$ molar
Neglecting any volume change of solution the initial concentration of $ceAg+$ will be
$ce[Ag+]_i = dfrac3.5cdot10^-9pumol0.010puL = 3.5cdot10^-7puM$
Now if both the $ceCN-$ and $ceI-$ are quantitatively removed then the same amount of $ceAg+$ must be removed.
$ce[CN-]_i + [I-]_i = 4cdot10^-10$ molar
$ce[Ag+]_f = 3.5cdot10^-7puM - 4cdot10^-10puM approx 3.5cdot10^-7puM$
So the final concentration of $ceAg+$ is essentially the same as the initial concentration. The concentration of $ceAg+$ with the Ksp's can now be used to calculated how much of the two anions can remain in solution.
The final concentration of $ceCN-$ is
$ce[CN-]_f = dfracK_spce[Ag+]_f = dfrac6.0cdot10^-173.5cdot10^-7 = pu1.7e-10$
The the final concentration of $ceI-$ is
$ce[I-]_f = dfracK_spce[Ag+]_f = dfrac8.5cdot10^-173.5cdot10^-7 = pu2.4e-10$
Conclusion:
Since $ce[CN-]_i > [CN-]_f$ some $ceAgCN$ will ppt.
Since $ce[I-]_i < [I-]_f$ no $ceAgI$ will ppt.
answered 5 hours ago
MaxWMaxW
15.7k22261
$endgroup$
Consider a $pu10.0 mL$ solution containing $pu1.0e-10 M$ each of $ceBa(CN)2$ and $ceBaI2$. If $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, will any precipitate(s) form? If yes, what compound(s) will precipitate?
$K_mathrmsp(ceAgCN) = pu6.0e-17$; $K_mathrmsp(ceAgI) = pu8.5e-17$.
Assuming that $ceBa(CN)2$ and $ceBaI2$ dissociate completely.
$ce[CN-]_i = [I-]_i = 2cdot10^-10$ molar
Neglecting any volume change of solution the initial concentration of $ceAg+$ will be
$ce[Ag+]_i = dfrac3.5cdot10^-9pumol0.010puL = 3.5cdot10^-7puM$
Now if both the $ceCN-$ and $ceI-$ are quantitatively removed then the same amount of $ceAg+$ must be removed.
$ce[CN-]_i + [I-]_i = 4cdot10^-10$ molar
$ce[Ag+]_f = 3.5cdot10^-7puM - 4cdot10^-10puM approx 3.5cdot10^-7puM$
So the final concentration of $ceAg+$ is essentially the same as the initial concentration. The concentration of $ceAg+$ with the Ksp's can now be used to calculated how much of the two anions can remain in solution.
The final concentration of $ceCN-$ is
$ce[CN-]_f = dfracK_spce[Ag+]_f = dfrac6.0cdot10^-173.5cdot10^-7 = pu1.7e-10$
The the final concentration of $ceI-$ is
$ce[I-]_f = dfracK_spce[Ag+]_f = dfrac8.5cdot10^-173.5cdot10^-7 = pu2.4e-10$
Conclusion:
Since $ce[CN-]_i > [CN-]_f$ some $ceAgCN$ will ppt.
Since $ce[I-]_i < [I-]_f$ no $ceAgI$ will ppt.
answered 5 hours ago
MaxWMaxW
15.7k22261
edited 5 hours ago
answered 5 hours ago
MaxWMaxW
15.7k22261
answered 5 hours ago
MaxWMaxW
15.7k22261
answered 5 hours ago
MaxWMaxW
15.7k22261
15.7k22261
add a comment |
add a comment |
$begingroup$
Alternative method to MaxW method:
Assume that an initial $pu10.0 mL$ solution of $pu1.0e-10 M$ in each of $ceBa(CN)2$ and $ceBaI2$ is clear (homogeneous). That means $ceBa(CN)2$ and $ceBaI2$ have dissociated completely. Thus concentrations of ions are as follows:
$$ce[CN-]_i = [I-]_i = pu2cdot10^-10 mol ! L^-1$$
Suppose when $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, no volume change has occured. Thus, the initial concentration of added ions in the solution will be:
$$ce[Ag+]_i = [NO3-]_i = dfracpu3.5cdot10^-9 molpu0.010 L = pu3.5cdot10^-7 mol ! L^-1$$
For precipitation of $ceAgCN(s)$:
$$Q_mathrmsp = ce[Ag+]_icdot ce[CN-]_i = (pu3.5cdot10^-7 mol ! L^-1)(pu2cdot10^-10 mol ! L^-1) \ = pu7.0cdot10^-17 mol^2 ! L^-2 gt K_mathrmsp(ceAgCN) = pu6.0cdot10^-17 mol^2 ! L^-2 $$
Therefore, $ceAgCN(s)$ will precipitate.
For precipitation of $ceAgI(s)$:
$$Q_mathrmsp = ce[Ag+]_icdot ce[I-]_i = (pu3.5cdot10^-7 mol ! L^-1)(pu2cdot10^-10 mol ! L^-1) \ = pu7.0cdot10^-17 mol^2 ! L^-2 lt K_mathrmsp(ceAgCN)=pu8.5cdot10^-17 mol^2 ! L^-2 $$
Therefore, $ceAgI(s)$ will not precipitate in this condition.
answered 3 hours ago
Mathew MahindaratneMathew Mahindaratne
6,328725
$endgroup$
add a comment |
$begingroup$
Alternative method to MaxW method:
Assume that an initial $pu10.0 mL$ solution of $pu1.0e-10 M$ in each of $ceBa(CN)2$ and $ceBaI2$ is clear (homogeneous). That means $ceBa(CN)2$ and $ceBaI2$ have dissociated completely. Thus concentrations of ions are as follows:
$$ce[CN-]_i = [I-]_i = pu2cdot10^-10 mol ! L^-1$$
Suppose when $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, no volume change has occured. Thus, the initial concentration of added ions in the solution will be:
$$ce[Ag+]_i = [NO3-]_i = dfracpu3.5cdot10^-9 molpu0.010 L = pu3.5cdot10^-7 mol ! L^-1$$
For precipitation of $ceAgCN(s)$:
$$Q_mathrmsp = ce[Ag+]_icdot ce[CN-]_i = (pu3.5cdot10^-7 mol ! L^-1)(pu2cdot10^-10 mol ! L^-1) \ = pu7.0cdot10^-17 mol^2 ! L^-2 gt K_mathrmsp(ceAgCN) = pu6.0cdot10^-17 mol^2 ! L^-2 $$
Therefore, $ceAgCN(s)$ will precipitate.
For precipitation of $ceAgI(s)$:
$$Q_mathrmsp = ce[Ag+]_icdot ce[I-]_i = (pu3.5cdot10^-7 mol ! L^-1)(pu2cdot10^-10 mol ! L^-1) \ = pu7.0cdot10^-17 mol^2 ! L^-2 lt K_mathrmsp(ceAgCN)=pu8.5cdot10^-17 mol^2 ! L^-2 $$
Therefore, $ceAgI(s)$ will not precipitate in this condition.
answered 3 hours ago
Mathew MahindaratneMathew Mahindaratne
6,328725
$endgroup$
add a comment |
$begingroup$
Alternative method to MaxW method:
Assume that an initial $pu10.0 mL$ solution of $pu1.0e-10 M$ in each of $ceBa(CN)2$ and $ceBaI2$ is clear (homogeneous). That means $ceBa(CN)2$ and $ceBaI2$ have dissociated completely. Thus concentrations of ions are as follows:
$$ce[CN-]_i = [I-]_i = pu2cdot10^-10 mol ! L^-1$$
Suppose when $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, no volume change has occured. Thus, the initial concentration of added ions in the solution will be:
$$ce[Ag+]_i = [NO3-]_i = dfracpu3.5cdot10^-9 molpu0.010 L = pu3.5cdot10^-7 mol ! L^-1$$
For precipitation of $ceAgCN(s)$:
$$Q_mathrmsp = ce[Ag+]_icdot ce[CN-]_i = (pu3.5cdot10^-7 mol ! L^-1)(pu2cdot10^-10 mol ! L^-1) \ = pu7.0cdot10^-17 mol^2 ! L^-2 gt K_mathrmsp(ceAgCN) = pu6.0cdot10^-17 mol^2 ! L^-2 $$
Therefore, $ceAgCN(s)$ will precipitate.
For precipitation of $ceAgI(s)$:
$$Q_mathrmsp = ce[Ag+]_icdot ce[I-]_i = (pu3.5cdot10^-7 mol ! L^-1)(pu2cdot10^-10 mol ! L^-1) \ = pu7.0cdot10^-17 mol^2 ! L^-2 lt K_mathrmsp(ceAgCN)=pu8.5cdot10^-17 mol^2 ! L^-2 $$
Therefore, $ceAgI(s)$ will not precipitate in this condition.
answered 3 hours ago
Mathew MahindaratneMathew Mahindaratne
6,328725
$endgroup$
Alternative method to MaxW method:
Assume that an initial $pu10.0 mL$ solution of $pu1.0e-10 M$ in each of $ceBa(CN)2$ and $ceBaI2$ is clear (homogeneous). That means $ceBa(CN)2$ and $ceBaI2$ have dissociated completely. Thus concentrations of ions are as follows:
$$ce[CN-]_i = [I-]_i = pu2cdot10^-10 mol ! L^-1$$
Suppose when $pu3.5e-9 mol$ of $ceAgNO3(s)$ is added to this solution, no volume change has occured. Thus, the initial concentration of added ions in the solution will be:
$$ce[Ag+]_i = [NO3-]_i = dfracpu3.5cdot10^-9 molpu0.010 L = pu3.5cdot10^-7 mol ! L^-1$$
For precipitation of $ceAgCN(s)$:
$$Q_mathrmsp = ce[Ag+]_icdot ce[CN-]_i = (pu3.5cdot10^-7 mol ! L^-1)(pu2cdot10^-10 mol ! L^-1) \ = pu7.0cdot10^-17 mol^2 ! L^-2 gt K_mathrmsp(ceAgCN) = pu6.0cdot10^-17 mol^2 ! L^-2 $$
Therefore, $ceAgCN(s)$ will precipitate.
For precipitation of $ceAgI(s)$:
$$Q_mathrmsp = ce[Ag+]_icdot ce[I-]_i = (pu3.5cdot10^-7 mol ! L^-1)(pu2cdot10^-10 mol ! L^-1) \ = pu7.0cdot10^-17 mol^2 ! L^-2 lt K_mathrmsp(ceAgCN)=pu8.5cdot10^-17 mol^2 ! L^-2 $$
Therefore, $ceAgI(s)$ will not precipitate in this condition.
answered 3 hours ago
Mathew MahindaratneMathew Mahindaratne
6,328725
edited 3 hours ago
answered 3 hours ago
Mathew MahindaratneMathew Mahindaratne
6,328725
answered 3 hours ago
Mathew MahindaratneMathew Mahindaratne
6,328725
answered 3 hours ago
Mathew MahindaratneMathew Mahindaratne
6,328725
6,328725
add a comment |
add a comment |
user77021 is a new contributor. Be nice, and check out our Code of Conduct.
user77021 is a new contributor. Be nice, and check out our Code of Conduct.
user77021 is a new contributor. Be nice, and check out our Code of Conduct.
user77021 is a new contributor. Be nice, and check out our Code of Conduct.
Thanks for contributing an answer to Chemistry Stack Exchange!
- Please be sure to answer the question. Provide details and share your research!
But avoid …
- Asking for help, clarification, or responding to other answers.
- Making statements based on opinion; back them up with references or personal experience.
Use MathJax to format equations. MathJax reference.
To learn more, see our tips on writing great answers.
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
StackExchange.ready(
function ()
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fchemistry.stackexchange.com%2fquestions%2f112803%2fprecipitating-silveri-salts-from-the-solution-of-bariumii-cyanate-and-iodide%23new-answer', 'question_page');
);
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
2
$begingroup$
"There is more than enough." How did you determine that with out any quantitative calculations?
$endgroup$
– Zhe
6 hours ago
$begingroup$
I did calculate that max CN- that could be precipitated as AgCN is 2 x 10-12 mol. This leaves 3.498 x10-9 mol Ag+ remaining to react with I-
$endgroup$
– user77021
6 hours ago
4
$begingroup$
Only if the concentrations are such that the solubility product exceeds $K_mathrmsp$.
$endgroup$
– Zhe
6 hours ago