if a 0.510 $m$ aqueous solution freezes at $-2.90\ ^\circ\text{c}$, what is the vant hoff factor, $i$, of the solute?
consult the table of $k_f$ values.
$i = $

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Accepted Answer

# Explanation:
## Step1: Recall freezing point depression formula
The freezing point depression equation is $\Delta T_f = i 	imes K_f 	imes m$, where $\Delta T_f$ is the change in freezing point, $i$ is the van't Hoff factor, $K_f$ is the cryoscopic constant for water, and $m$ is molality.
## Step2: Calculate $\Delta T_f$
Pure water freezes at $0^\circ	ext{C}$, so $\Delta T_f = 0^\circ	ext{C} - (-2.90^\circ	ext{C}) = 2.90^\circ	ext{C}$
## Step3: Identify $K_f$ for water
For aqueous solutions, $K_f = 1.86^\circ	ext{C}/m$
## Step4: Rearrange formula to solve for $i$
Rearrange to $i = \frac{\Delta T_f}{K_f 	imes m}$
## Step5: Substitute values and calculate
$i = \frac{2.90^\circ	ext{C}}{1.86^\circ	ext{C}/m 	imes 0.510\ m}$
$i = \frac{2.90}{0.9486} \approx 3.06$

# Answer:
$3.06$

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QUESTION IMAGE

Question

Explanation:

Step1: Recall freezing point depression formula

Step2: Calculate $\Delta T_f$

Step3: Identify $K_f$ for water

Step4: Rearrange formula to solve for $i$

Step5: Substitute values and calculate

Answer: