Difficulty: Easy
Correct Answer: Boyle
Explanation:
Introduction / Context:The ideal gas law PV = nRT is an approximation that becomes exact only when intermolecular forces are negligible. Real gases deviate from ideality due to attractions and repulsions. There exists a special temperature at which the first departures from ideality cancel out over a range of pressures, giving behavior that closely tracks the ideal gas law. This temperature is known as the Boyle temperature and is a standard concept in physical chemistry and chemical engineering thermodynamics.
Given Data / Assumptions:
Concept / Approach:Real-gas behavior can be represented by the virial equation of state: Z = PV/(nRT) = 1 + B(T)P/RT + C(T)(P/RT)^2 + … . The second virial coefficient B(T) captures the dominant effects of intermolecular forces at low to moderate pressures. The Boyle temperature TB is defined by B(TB) = 0. At T = TB, the compressibility factor Z ≈ 1 over a finite pressure range because the first correction term vanishes, causing the gas to mimic ideal behavior better than at other temperatures.
Step-by-Step Solution:
Write virial expansion: Z = 1 + B(T)P/RT + higher terms.Define Boyle temperature TB such that B(TB) = 0.At T = TB, Z ≈ 1 for small to moderate P because the leading correction is zero.Therefore, the temperature sought is the Boyle temperature.Verification / Alternative check:From pair potential models (e.g., Lennard-Jones), B(T) changes sign with T; a specific T exists where attractions and repulsions balance so that the second virial term vanishes. Experimental compressibility plots Z vs. P at TB pass nearly through Z = 1 with minimal slope, confirming the definition.
Why Other Options Are Wrong:
Common Pitfalls:Confusing Boyle temperature with inversion temperature; the former concerns virial behavior near low pressure, the latter concerns throttling temperature effects.
Final Answer:Boyle
Discussion & Comments