Unpacking the Meaning of Specific Heat Capacity in Base Units

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Specific heat capacity is expressed in joules per gram-kelvin (J g–1 K–1) and can also be represented in base units as m2 s-2 K-1. While using base units may seem less intuitive, it is equivalent when converting grams to kilograms. This representation is particularly useful in problems involving speed, where kinetic energy can be converted into thermal energy. For instance, if an object with specific heat capacity c is moving at speed x, its temperature increase can be calculated using the formula x²/2c, independent of mass. The discussion highlights the relevance of base units in specific contexts, despite their complexity.
mikkol
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specific heat capacity is measured in joule per gram-kelvin (J g–1 K–1). In base units it is m2 s-2 k-1.
Is that meaningless to express specific heat capacity in base units? Is there an explanation?

Thanks
Nick
 
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It's exactly equivalent if you replace the gram with kilogram, but fewer people would recognize it, and it's not as intuitive (because in specific heat problems you're usually given information in joules and kilograms, not meters).
 
ok, but what does exactly mean m2 s-2 k-1? What has it got to do with specific heat capacity?
 
It doesn't have much to do with typical thermodynamics problems, but it's well suited for a class of problems that involve speed. For example, if a homogeneous object with specific heat capacity c (in m2 s-2 K-1) is moving at a speed of x m s-1 and its kinetic energy is turned completely into thermal energy, then its temperature will increase by x2/2c kelvins. Independent of its mass! So there's a problem where your units might be more intuitive to use.

(Obviously I've just equated the original kinetic energy with the increase in thermal energy,

\frac{1}{2}mv^2=mc\Delta T

and canceled out the mass.)
 
thanks Mapes!
 

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