To raise the temperature of one cc of water requires i calorie of heat .
you did not specify the volume.
heat will flow from the iron to the water until both are the same temperature
100
The specific heat of water is 1 and the heat released is mass x specific heat x the temperature difference, so we have 15 x 1 x 35 = 525 BTU
The idea here is to: * Look up the specific heat of water. * Multiply the mass, times the temperature difference, times the specific heat of water. You may need to do some unit conversions first; specifically, if the specific heat is given per kilogram, you can convert the grams to kilograms.
Heat required for this transition is given as the the sum of three heatsheat required for heating the ice from -5 degree Celsius +latent heat(conversion of ice at zero degree to water at zero degrees)+heat required to heat the water from 0 to 5 degree CelsiusHeating of ice=m x s x delta T,where m is the mass ,s is the specific heat of ice=200x0.5x5=500calmelting of ice=mxlatent heat=200x80=16,000calHeating of water=m x s x delta T,where m is the mass ,s is the specific heat of water =200x1x5=1000calTotal heat required=500+16,000+1000=17,500 cal
100 degrees celsius are equal to 212 degrees fahrenheit.
Please try to use your brain to solve simple questions such as this one. The change in temperature is simply 100 - 35 = 65 degrees Celsius.
Water boils at 100 degrees Celsius or 212 degrees Fahrenheit.
depends on the amount of water
That has nothing to do with intensity. The temperature 100 degrees Celsius equals 212 degrees Fahrenheit as the boiling point of water.
If fifty grams of water cooled from 50 degrees to 10 degrees, and the specific heat of water is 4.2, 135 kJ of heat was released.
170o
Out
You can allow hot water to cool or you can heat cold water.
The specific heat temperature of mercury is 14 degrees Celsius. Comparably, the specific temperature of water is 417.9 degrees and air is 101 degrees.
Heat (in water) is random molecular motion, so greater heat equals greater disorder, hence more entropy.
heat will flow from the iron to the water until both are the same temperature