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The percent volume fraction of xenon, atmospheric pressure and temperature and dimensions of the room are given. The mass of the xenon in the room is to be determined. Also the number of xenon atoms inhaled in the given volume of air is to be calculated. Concept introduction: The ideal gas equation is given as, Pressure × Volume = Number of moles × Gas constant × Absolute temperature One mole of a substance is equivalent to 22.4 dm 3 . To determine: The mass of xenon in the room of the given dimension.

The percent volume fraction of xenon, atmospheric pressure and temperature and dimensions of the room are given. The mass of the xenon in the room is to be determined. Also the number of xenon atoms inhaled in the given volume of air is to be calculated. Concept introduction: The ideal gas equation is given as, Pressure × Volume = Number of moles × Gas constant × Absolute temperature One mole of a substance is equivalent to 22.4 dm 3 . To determine: The mass of xenon in the room of the given dimension.

Solution Summary: The author explains how the ideal gas equation is used to determine the mass of xenon in the room of the given dimension.

Chemistry

9th Edition

ISBN: 9781133611097

Author: Steven S. Zumdahl

Publisher: Cengage Learning

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Concept explainers

Group 15 elements

The elements of group 15 are phosphorus, nitrogen, bismuth antimony, and arsenic. The most abundant element which is present in the air is nitrogen and the percentage of nitrogen present in the air is 78%. In the free state, the elemental nitrogen is pre…

Question

Chapter 20, Problem 95CWP

(a)

Interpretation Introduction

Interpretation: The percent volume fraction of xenon, atmospheric pressure and temperature and dimensions of the room are given. The mass of the xenon in the room is to be determined. Also the number of xenon atoms inhaled in the given volume of air is to be calculated.

Concept introduction: The ideal gas equation is given as,

Pressure×Volume=Number of moles×Gas constant×Absolute temperature

One mole of a substance is equivalent to 22.4 dm3 .

To determine: The mass of xenon in the room of the given dimension.

(b)

Interpretation Introduction

Interpretation: The percent volume fraction of xenon, atmospheric pressure and temperature and dimensions of the room are given. The mass of the xenon in the room is to be determined. Also the number of xenon atoms inhaled in the given volume of air is to be calculated.

Concept introduction: The ideal gas equation is given as,

Pressure×Volume=Number of moles×Gas constant×Absolute temperature

One mole of a substance is equivalent to 22.4 dm3 .

To determine: The number of xenon atoms inhaled in the 2 L volume of air during a breath.

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Chapter 20, Problem 94CWP

Chapter 20, Problem 96CWP

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