Calculate the ratio of the rotational partition functions of 3C13 Cl to that of 3$C133C1under identical conditions and at high temperature assuming identical bond distances.A) 1.03B) 3.22C) 0.52D) 1.62E) 2.05The translational partition function for a noble gas confined to a volume of 1.0 L at 298K is equal to 2.44× 10²9. What is the identity of this gas?A) He (M-4.00 g mol·')B) Ne (M-20.18 g mol)C) Kr (M-83.80 g mol")D) Xe (M=131.30 g mol)E) Ar (M-39.95 g mol")

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Calculate the ratio of the rotational partition functions of 3CSCI to that of 3$C³³CI under identical conditions and at high temperature assuming identical bond distances. A) 1.03 B) C) 0.52 D) 1.62 E) 2.05 3.22 The translational partition function for a noble gas confined to a volume of 1.0 L at 298 K is equal to 2.44 × 10ª9. What is the identity of this gas? A) He (M-4.00 g mol') B) Ne (M=20.18 g mol") C) Kr (M-83.80 g mol") D) Xe (M-131.30 g mol) E) Ar (M-39.95 g mol")

Calculate the ratio of the rotational partition functions of 3CSCI to that of 3$C³³CI under identical conditions and at high temperature assuming identical bond distances. A) 1.03 B) C) 0.52 D) 1.62 E) 2.05 3.22 The translational partition function for a noble gas confined to a volume of 1.0 L at 298 K is equal to 2.44 × 10ª9. What is the identity of this gas? A) He (M-4.00 g mol') B) Ne (M=20.18 g mol") C) Kr (M-83.80 g mol") D) Xe (M-131.30 g mol) E) Ar (M-39.95 g mol")

Physical Chemistry

2nd Edition

ISBN:9781133958437

Author:Ball, David W. (david Warren), BAER, Tomas

Publisher:Ball, David W. (david Warren), BAER, Tomas

Chapter18: More Statistical Thermodynamics

Section: Chapter Questions

Problem 18.4E

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