Enthelpy of transition of water to ice

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SUMMARY

The discussion focuses on calculating the change in enthalpy (ΔH) during the transition of supercooled liquid water to ice at a constant temperature of 258K and pressure of 1.000 atm. The specific heat capacities (Cp,m) for liquid water and ice are given as 75.48 kJ/mol and 37.15 kJ/mol, respectively. The process involves heating the supercooled water from 258K to 273K, freezing it, and then cooling the ice back to 258K. This method allows for the calculation of ΔH using the defined heat capacities and the heat of fusion at 0°C.

PREREQUISITES
  • Understanding of enthalpy changes in phase transitions
  • Knowledge of specific heat capacity (Cp,m) concepts
  • Familiarity with the heat of fusion/melting
  • Basic principles of thermodynamics
NEXT STEPS
  • Calculate the change in enthalpy (ΔH) for the transition using the provided Cp,m values
  • Explore the concept of supercooling and its implications in thermodynamics
  • Research the heat of fusion for various substances at different temperatures
  • Study the relationship between temperature, pressure, and phase changes in water
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Students and professionals in chemistry and physics, particularly those studying thermodynamics and phase transitions of substances.

Joel Martis
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1.At constant temperature of 258K and constant pressure of 1.000 atm , super cooled liquid water (2.00mol) freezes irreversibly. Find the change in enthalpy(ΔH) by assuming that Cp,m of liquid water and ice are 75.48 KJ/mol and 37.15KJ/mol and are constant. (this problem was from my assignment sheet so there might be errors in the units of Cp,m. By the way , Cp,m is the specific heat capacity at constant pressure.)



2.the only equation i could think of is ΔH=ΔU+ΔPV
 
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Hi Joel Martis. Welcome to Physics Forums.

In terms of the enthalpy and temperature, what is the defining equation for the heat capacity at constant pressure?

Chet
 
I think it is Cp,m= (∂H/∂T)p
 
Joel Martis said:
I think it is Cp,m= (∂H/∂T)p

Good. So now you have to define a path form the starting point to the final point along which you know all the properties needed to calculate the ΔH. The starting point is liquid water at -15C, and the end point is ice at -15 C. But, you only know the heat of melting/fusion at 0C. So, how do you get form the starting point to the final point if you only know the heat of fusion/melting at 0 C, and the heat capacities for the liquid water and the water ice?

Chet
 
Well, how about heating the supercooled water from 258K to 273K , freezing it, and then cooling the ice back to 258K?
 
Joel Martis said:
Well, how about heating the supercooled water from 258K to 273K , freezing it, and then cooling the ice back to 258K?

Sounds great.

Chet
 

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