Heat and Mass Proportionality: Examining the Accuracy

AI Thread Summary
The discussion centers on the relationship between the mass of a liquid and the time required to convert it to gas under constant heat supply. It asserts that the time is directly proportional to the mass, given that the heat supplied remains constant. The equation presented, t = m^2(l + cθ), raises questions about the meaning of the variables involved, specifically m (mass), c (specific heat capacity), θ (temperature change), and l (latent heat of vaporization). Clarification is sought on how these variables interact and their implications for the boiling process. Overall, the accuracy of the proportionality and the equation's structure is under scrutiny.
latyph
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I NOTICED THAT THE TIME REQUIRED FOR A GIVEN MASS OF A LIQUID IS PROPORTIONAL DIRECTLY TO THE MASS OF THE LIQUID PROVIDED THE HEAT SUPPLY IS CONSTANT,WHICH MAKES t PROPORTIONAL TO m,the heat is constant.now heat is mctheta +ml.which makes t =m^2(l+ctheta).how true is this,is there a fault i this let me know
 
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given mass of liquid to change to gas to be precised,i made a mistake typin
 
Okay, every liquid has a "heat of boiling" that is the amount of heat required to change 1 gram of the liquid, already at the boiling point into gas. In order to boil x grams of liquid, you must supply a specific number of calories of heat. If you are providing the heat at a constant rate, then the time required to convert all of the liquid to gas is proportional to the mass.

However, having said "THE HEAT SUPPLY IS CONSTANT", you then say "now heat is mctheta +ml". I don't understand that. What are the variables? m, c, theta, l?
or is that ctheta[/b]? I would guess that m is the mass, but what are c and theta (or ctheta[/b]) and is l a separate constant or is ml one amount? Please tell us what your symbols mean.
 
m mass of liquid,c specific heat capacity,theta change in temp.l latent heat of vaporization
 

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