the ph of a solution decreases by 2.0. how does the hydronium ion concentration of the solution change…

the ph of a solution decreases by 2.0. how does the hydronium ion concentration of the solution change? increases to 2 times the original concentration increases to 100 times the original concentration decreases to $\frac{1}{100}$ of the original concentration decreases to $\frac{1}{2}$ of the original concentration

the ph of a solution decreases by 2.0. how does the hydronium ion concentration of the solution change? increases to 2 times the original concentration increases to 100 times the original concentration decreases to $\frac{1}{100}$ of the original concentration decreases to $\frac{1}{2}$ of the original concentration

Answer

Explanation:

Step1: Recall pH formula

The pH is defined as $pH = -\log[H_3O^+]$, where $[H_3O^+]$ is the hydronium - ion concentration. Let the initial pH be $pH_1=-\log[H_3O^+]_1$ and the final pH be $pH_2 = -\log[H_3O^+]_2$.

Step2: Use the given pH change

We know that $pH_1 - pH_2=2.0$. Substituting the pH formula, we get $(-\log[H_3O^+]_1)-(-\log[H_3O^+]_2)=2.0$.

Step3: Simplify the logarithmic equation

Using the property of logarithms $\log a-\log b=\log\frac{a}{b}$, the equation becomes $\log\frac{[H_3O^+]_2}{[H_3O^+]_1}=2.0$.

Step4: Solve for the ratio of concentrations

By the definition of logarithms, if $\log x = y$, then $x = 10^y$. So, $\frac{[H_3O^+]_2}{[H_3O^+]_1}=10^{2.0}=100$.

Answer:

The hydronium - ion concentration increases to 100 times the original concentration. So the correct option is: increases to 100 times the original concentration.