Pycnometer Equation: Understanding Specific Gravity

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SUMMARY

The discussion centers on the pycnometer equation used to determine specific gravity, specifically the equation F = g(m_b - \frac{ \rho_a m_b}{ \rho_b}). Participants clarify that the term -\frac{ \rho_a m_b}{ \rho_b} accounts for the buoyancy of air, which is crucial for precise measurements. The correction for buoyancy must consider air temperature, pressure, and humidity, as these factors can significantly affect the results. Understanding this correction is essential for accurate specific gravity calculations.

PREREQUISITES
  • Understanding of the pycnometer and its application in measuring specific gravity
  • Familiarity with basic physics concepts, including force and buoyancy
  • Knowledge of density and its role in fluid mechanics
  • Awareness of how environmental factors like temperature and pressure affect measurements
NEXT STEPS
  • Research the principles of buoyancy and Archimedes' principle
  • Study the effects of air density variations due to temperature and pressure on measurements
  • Explore advanced pycnometer techniques for precise specific gravity determination
  • Learn about the impact of humidity on air density and its implications for laboratory measurements
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Students, researchers, and professionals in chemistry and physics who are involved in precise measurements of specific gravity and require a deeper understanding of the factors influencing these measurements.

nobahar
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hello!

On wiki, regarding specific gravity, it gives the derivation for the pycnometer equation for determining specific gravity. However, the first equation confuses me. It goes as follows:
The pycnometer, placed on a balance, will exert a force:
F = g(m_b - \frac{ \rho_a m_b}{ \rho_b})
The subscript b is for the bottle, and a is for air. rho is density and m is mass; g is the acceleration due to gravity
The force on the balance would be F = gm. The above equation suggests that the mass of the air displaced by the bottle needs to be subtracted from the mass of the bottle; so the mass used in the equation is the difference in mass between the bottle and the air that would occupy the space of the material used for the bottle. I don't understand why this is the case. Why does the mass of air that would occupy that space if the bottle wasn't there even matter? It seems irrelevant. Surely we need to consider the mass of the bottle, all of its mass.

Any help appreciated.
 
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You have to go back to Archimedes.
 
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nobahar said:
hello!

On wiki, regarding specific gravity, it gives the derivation for the pycnometer equation for determining specific gravity. However, the first equation confuses me. It goes as follows:
The pycnometer, placed on a balance, will exert a force:
F = g(m_b - \frac{ \rho_a m_b}{ \rho_b})
The subscript b is for the bottle, and a is for air. rho is density and m is mass; g is the acceleration due to gravity
The force on the balance would be F = gm. The above equation suggests that the mass of the air displaced by the bottle needs to be subtracted from the mass of the bottle; so the mass used in the equation is the difference in mass between the bottle and the air that would occupy the space of the material used for the bottle. I don't understand why this is the case. Why does the mass of air that would occupy that space if the bottle wasn't there even matter? It seems irrelevant. Surely we need to consider the mass of the bottle, all of its mass.

Any help appreciated.

The second term:

- \frac{ \rho_a m_b}{ \rho_b}

is the correction to the weight of the bottle for the buoyancy of air. In the most precise work, this must be determined using air temperature, pressure, and humidity. This can amount to a correction of a few parts per million.
 
Thanks for the responses. I have a really dumb question: if something is flat on the surface, how can the air "push up" underneath the bottle? Dumb question, I know, but I am trying to visualise where the pressure comes from! Thanks for the responses so far!
 

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