Water Density & Volume: 0-100°C

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Water density decreases from 990 kg/m3 at 0°C to 958.593 kg/m3 at 100°C, indicating a 4% loss in mass. However, the volume increase is only about 2% due to the non-linear relationship between temperature and density. The expansion rate of water is approximately 1.0002 for each 1°C increase, but this rate varies with temperature, particularly around 20°C. The relationship between density and volume is not straightforward, as the product of density and specific volume remains constant. Understanding these dynamics is crucial for accurate calculations in thermodynamics.
Yuri B.
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Water density at 0 C is 990 kg/m3.
Water density at 100 C is 1030 kg/m3 - 1 m3 of water "loses" about 4 % of its mass.
Water expansion rate is 1.0002 for each 1 C increase in temperature - 2 % for the above rise from 0 C to 100 C..
How comes that water density decreases 4 % but its volume increases just 2 % ?
 
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Yuri B. said:
Water density at 0 C is 990 kg/m3.
Water density at 100 C is 1030 kg/m3 - 1 m3 of water "loses" about 4 % of its mass.
Water expansion rate is 1.0002 for each 1 C increase in temperature - 2 % for the above rise from 0 C to 100 C..
How comes that water density decreases 4 % but its volume increases just 2 % ?

It's one consequence of dealing with too little information. The density-temperature relation for liquid water between 0 C and 100 C is a curve, with the maximum density occurring at about 4 C. Plot the values from the density table referenced by DrClaude.
 
I mistakenly put it otherwise so, more precisely - according to the reference - it should be :
0.999808 at 0 °C
0.958593 at 100 °C - about 4 % of the initial value
But the volume will increase just 2 %
Maybe there is square root relation ?
 
Yuri B. said:
I mistakenly put it otherwise so, more precisely - according to the reference - it should be :
0.999808 at 0 °C
0.958593 at 100 °C - about 4 % of the initial value
But the volume will increase just 2 %
Maybe there is square root relation ?
Again: the relationship isn't linear.
 
Let it be it, but I refer to the exactly 2 points (on the "curve") between which there is the 4% decrease in density for, as it seems, 2% increase in volume
Square root ?
 
Yuri B. said:
Let it be it, but I refer to the exactly 2 points (on the "curve") between which there is the 4% decrease in density for, as it seems, 2% increase in volume
Square root ?
But as Russ said, the relationship is not linear. In other words, you can't use the same expansion coefficient at all temperatures.

Yuri B. said:
Water expansion rate is 1.0002 for each 1 C increase in temperature
This is only true around 20°C.
 
Please have a look at the link DrClaude gave you in post #2. You may even try dropping the data into a spreadsheet and calculating the coefficient at different temperatures. You will find that it varies substantially from 2%.
 
Last edited:
But will % of expansion = % of decrease in density ?
 
  • #10
The product of density and specific volume is 1. So there is no square root relation involved.

Chet
 
  • #11
Thank you.
 

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