1 Answer

David Dao · Answer 1 · 2020-02-19T18:59:52+0000

Step-by-step explanation:

The given data is as follows.

Specific heat of water =
4.18 J/g^(o)C

Heat of fusion of water = 334 J/g

Mass of water = 200 g

On bringing water at
0^(o)C , heat released will be as follows.

$q_(1) = m * C * \Delta T$

=
200 g * 4.18 J/g^(o)C * (0 - 15)^(o)C

= -12540 J

or, = -12.540 kJ (as 1 kJ = 1000 J)

Now, calculate the heat releasedwhen water freezes at
0^(o)C as follows.

$q_(2) = mass * \text{-heat of fusion}$

=
200 g * -334 J/g

= -66800 J

or, = -66.80 kJ

Therefore, total heat released in freezing water will be as follows.

q_(total) = q_(1) + q_(2)

= (-12.540 - 66.80) kJ

= -79.34 kJ

Hence,

amount of heat released in freezing water = heat used to vaporize
CCl_(2)F_(2)

Now, heat of vaporization of
CCl_(2)F_(2) = 289 J/g

Total heat released in freezing water = -79.34 kJ

Heat consumed to vaporize
CCl_(2)F_(2) = 79.34 kJ = -79340 J

Therefore, calculate the mass of
CCl_(2)F_(2) vaporized as follows.

Mass of
CCl_(2)F_(2) vaporized =
$\frac{\text{heat consumed}}{\text{heat of vaporization}}$

=
(79340 J)/(289 J/g)

= 274.53 g

Thus, we can conclude that 274.53 g mass of this substance must evaporate to freeze 200 g of water initially at
.

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