part a\nwater (2310 g) is heated until it just begins to boil. if the water absorbs 5.83×10^5 j of heat in…

part a\nwater (2310 g) is heated until it just begins to boil. if the water absorbs 5.83×10^5 j of heat in the process, what was the initial temperature of the water?\nexpress your answer with the appropriate units.\nview available hint(s)\n\nvalue units\n\nsubmit previous answers\n\n× incorrect; try again; 7 attempts remaining\nenter your answer using units of temperature\n\nai study tools
Answer
Explanation:
Step1: Recall the heat - transfer formula
The heat - transfer formula is $Q = mc\Delta T$, where $Q$ is the heat absorbed, $m$ is the mass of the substance, $c$ is the specific heat capacity, and $\Delta T$ is the change in temperature. For water, $c = 4.186\ J/(g\cdot^{\circ}C)$. The boiling point of water is $T_f=100^{\circ}C$. We want to find the initial temperature $T_i$. Rearranging the formula for $\Delta T$ gives $\Delta T=\frac{Q}{mc}$, and since $\Delta T=T_f - T_i$, then $T_i=T_f-\frac{Q}{mc}$.
Step2: Identify the given values
We have $m = 2310\ g$, $Q = 5.83\times10^{5}\ J$, $c = 4.186\ J/(g\cdot^{\circ}C)$ and $T_f = 100^{\circ}C$.
Step3: Calculate $\frac{Q}{mc}$
$\frac{Q}{mc}=\frac{5.83\times 10^{5}\ J}{2310\ g\times4.186\ J/(g\cdot^{\circ}C)}$ $=\frac{5.83\times 10^{5}}{2310\times4.186}\ ^{\circ}C$ $=\frac{5.83\times 10^{5}}{9679.66}\ ^{\circ}C\approx60.2^{\circ}C$
Step4: Calculate the initial temperature
$T_i=T_f-\frac{Q}{mc}=100^{\circ}C - 60.2^{\circ}C = 39.8^{\circ}C$
Answer:
$39.8^{\circ}C$