Calculating Thermal Dilation in Sodium Using Bulk Modulus and Temperature

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SUMMARY

The discussion focuses on calculating the root mean square thermal dilation of sodium at 300 K using its bulk modulus of 7·1010 [unit]. The relationship between elastic energy density and bulk modulus is defined by the equation U = 1/2 Bδ2. The confusion arises from the claim that the elastic energy density is equivalent to thermal energy density, specifically U = 1/2 kBT, due to the single degree of freedom in elastic expansion. This indicates a direct correlation between thermal energy and elastic properties in sodium under the given conditions.

PREREQUISITES
  • Understanding of bulk modulus in materials science
  • Familiarity with thermal energy concepts, specifically kBT
  • Knowledge of elastic energy density equations
  • Basic principles of solid state physics as outlined in Kittel's textbook
NEXT STEPS
  • Study the derivation of elastic energy density from bulk modulus
  • Explore the concept of Debye temperature and its implications on thermal properties
  • Learn about the relationship between thermal dilation and temperature in solids
  • Investigate the degrees of freedom in different types of elastic expansions
USEFUL FOR

Students and professionals in materials science, physicists studying solid state physics, and anyone involved in thermal analysis of materials, particularly those interested in the properties of sodium and similar elements.

daudaudaudau
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Homework Statement



This is problem 5.2 in Kittel's Introduction to solid state physics:
Estimate for 300 K the root mean square thermal dilation for a primitive cell of sodium. Take the bulk modulus as 7\cdot10^{10} [unit]. Note that the Debye temperature 158 K is less than 300 K, so that the thermal energy is of the order of k_BT.

Homework Equations



Relation between elastic energy density, bulk modulus and volume dilation: U=\frac{1}{2}B\delta^2.

The Attempt at a Solution



So obviously I need the elastic energy density. Kittel claims that this is just \frac{1}{2}k_BT because there is only one degree of freedom in this kind of elastic expansion. But I don't understand this. He's supposed to find the elastic energy density, but then he finds the thermal energy density? Are these equal? And why are there suddently LESS degrees of freedom just because the material is expanding? I mean, usually the internal energy is U=3Nk_BT, right?
 
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I know this is not a hard question... :-)
 
No one can tell me how to calculate thermal dilation from temperature and the bulk modulus ? This is not even homework...
 

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