Given:
- Mass of ice mi=10kg at −10∘C
- Mass of water mw=100kg at 25∘C
- Specific heat of ice sice=2100J kg−1∘C−1
- Specific heat of water swater=4200J kg−1∘C−1
- Latent heat of fusion L=3.36×105J kg−1
Find: The decrement in the temperature of water.
The ice first warms from −10∘C to 0∘C, then melts, and finally the melted water warms from 0∘C to the final temperature Tf.
Heat gained by ice in warming to 0∘C:
Q1=mi⋅sice⋅ΔT=10×2100×10=2.1×105JHeat gained in melting:
Q2=mi⋅L=10×3.36×105=3.36×106JHeat gained by melted ice warming to Tf:
Q3=mi⋅swater⋅Tf=10×4200×Tf=42000TfJSo, total heat absorbed by ice is
Qabsorbed=Q1+Q2+Q3=3.57×106+42000TfHeat lost by water cooling from 25∘C to Tf:
Qlost=mw⋅swater⋅(25−Tf)=100×4200×(25−Tf)=420000(25−Tf)Using conservation of energy,
Qabsorbed=Qlost
3.57×106+42000Tf=420000(25−Tf)
3570000+42000Tf=10500000−420000Tf
462000Tf=6930000
Tf=4620006930000=15∘CTherefore, the decrement in the temperature of water is
ΔTwater=25−Tf=25−15=10∘C
The correct option is B. The solution states option D, but the worked calculation gives 10∘C, which matches option B.