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2 years ago

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Hydrochloric acid (75.0 mL of 0.250 M) is added to 225.0 mL of 0.0550 M Ba(OH)2 solution. What is the concentration of the exces

s H1 or OH2 ions left in this solution?

2 answers:

LUCKY_DIMON [66]2 years ago

7 0

Answer:

Concentration of unreacted hydroxide ions in the final solution is 0.02 mol/L.

Explanation:

$Molarity=\frac{moles}{\text {Volume in L}}$

Moles of HCl

= $Molarity\times {\text {Volume in L}}=0.250 M\times 0.075L=0.01875 moles$

1 mole of HCl give = 1 mole of $H^+$

Thus 0.01875 moles of HCl give = 0.01875 mole of $H^+$

Moles of $Ba(OH)_2$ :

$=Molarity\times {\text {Volume in L}}=0.0550\times 0.225=0.012375 mol$

According to stoichiometry:

1 mole of Ba(OH)_2 gives = 2 moles of $OH^-$ :

Thus 0.012 moles of $Ba(OH)_2$ give = 2 \times 0.012375 =0.02475 moles of $OH^-$

According to neutralization reaction, 1 mole of $H^+$ neutralizes 1 mol $OH^-$ .

0.01875 mol of $H^+$ will neutralize 0.01875 mol $OH^-$ .

Moles of hydroxide ion left unreacted :

= 0.02475 mol - 0.01875 mol = 0.006 mol

Concentration of unreacted hydroxide ions in the final solution:

$\frac{0.006 mol}{0.225 L+0.075 L}=0.02 mol/L$

Shalnov [3]2 years ago

4 0

Answer: The concentration of excess $[OH^-]$ in solution is 0.017 M.

Explanation:

1. $Molarity=\frac{moles}{\text {Volume in L}}$

moles of $HCl=Molarity\times {\text {Volume in L}}=0.250\times 0.075=0.019moles$

1 mole of $HCl$ give = 1 mole of $H^+$

Thus 0.019 moles of $HCl$ give = 0.019 mole of $H^+$

2. moles of $Ba(OH)_2=Molarity\times {\text {Volume in L}}=0.0550\times 0.225=0.012moles$

According to stoichiometry:

1 mole of $Ba(OH)_2$ gives = 2 moles of $OH^-$

Thus 0.012 moles of $Ba(OH)_2$ give = $2 \times 0.012=0.024$ moles of $OH^-$

$H^++OH^-\rightarrow H_2O$

As 1 mole of $H^+$ neutralize 1 mole of $OH^-$

0.019 mole of $H^+$ will neutralize 0.019 mole of $OH^-$

Thus (0.024-0.019)= 0.005 moles of $OH^-$ will be left.

$[OH^-]=\frac{\text {moles left}}{\text {Total volume in L}}=\frac{0.005}{0.3L}=0.017M$

Thus molarity of $[OH^-]$ in solution is 0.017 M.

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The balanced chemical equation for the above reaction is as follows ;
Mg + 2HCl —> MgCl2 + H2
The stoichiometry of Mg to HCl is 1:2
This means that 1 mol of Mg reacts with 2 mol of HCl
Equal amounts of both Mg and HCl have been added. One reagent is the limiting reactant and other reactant is in excess.
Limiting reactant is the reagent that is fully used up in the reaction and the amount of Product formed depends on the amount of limiting reactant present.
In this reaction if Mg is the limiting reactant, 4.40 moles of Mg should react with 4.40x2 -8.80 moles of HCl.
But only 4.40 moles of HCl present therefore HCl is the limiting reactant that reacts with 4.40/2 = 2.20 moles of Mg
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Explanation:

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$1.5\times10^{24}\ ml=4\times10^{-2}\times1.5\times10^{24}$

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Hence, The total amount of Au is $ $2.0\times10^{24}$

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Rank the following compounds in order of reactivity toward nitration with HNO3:_______. thiophene, benzene, 3-methylthiophene, a

siniylev [52]

Answer:

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Gwar [14]

Mass of water vapor is 0.48 gms.

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= 1.173 kJ

Now the final temperature of the metal block is calculated by the formula:

q = m × c × ΔT

q = m × c × (T₂ - T₁)

Here, q is the amount of heat, m is the mass of the metal, c is the specif heat of the metal, T₁ is initial temperature, and T₂ is the final temperature.

Now, substituting the values we get,

1.173 kJ = 55 g × 0.903 J/g. ° C * (T₂ - 25°C)

1.173 × 10³ J = 55 g × 0.903 J/g. degree C × (T₂ - 25°C)

1.173 × 10³ = 49.665 ° C * (T₂ - 25° C)

T₂ = 49° C.

Thus, the final temperature of the metal block is 49° C.

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2 years ago