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Science Chemistry Chemistry: Principles and Practice

The density of atmosphere on the surface of Venus composed of CO 2 gas at 91.2 atm and 730 K has to be calculated. Concept Introduction: Any gas that obeys the assumption laid down in kinetic molecular theory is said to be an ideal gas. The combination of all the gas laws namely Boyle’s law, Charles law and Avogadro’s leads to the ideal gas equation that can be used to relate all the four properties such as given below: P V = n R T Here, R is universal gas constant. V denotes the volume. n denotes the number of moles. T denotes temperature. P denotes the pressure.

The density of atmosphere on the surface of Venus composed of CO 2 gas at 91.2 atm and 730 K has to be calculated. Concept Introduction: Any gas that obeys the assumption laid down in kinetic molecular theory is said to be an ideal gas. The combination of all the gas laws namely Boyle’s law, Charles law and Avogadro’s leads to the ideal gas equation that can be used to relate all the four properties such as given below: P V = n R T Here, R is universal gas constant. V denotes the volume. n denotes the number of moles. T denotes temperature. P denotes the pressure.

Solution Summary: The author explains that any gas that obeys the assumption laid down in kinetic molecular theory is said to be an ideal gas.

Chemistry: Principles and Practice

Chemistry: Principles and Practice

3rd Edition

ISBN: 9780534420123

Author: Daniel L. Reger, Scott R. Goode, David W. Ball, Edward Mercer

Publisher: Cengage Learning

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Chapter 6, Problem 6.57QE

Interpretation Introduction

Interpretation:

The density of atmosphere on the surface of Venus composed of CO2 gas at 91.2 atm and 730 K has to be calculated.

Concept Introduction:

Any gas that obeys the assumption laid down in kinetic molecular theory is said to be an ideal gas. The combination of all the gas laws namely Boyle’s law, Charles law and Avogadro’s leads to the ideal gas equation that can be used to relate all the four properties such as given below:

PV=nRT

Here,

R is universal gas constant.

V denotes the volume.

n denotes the number of moles.

T denotes temperature.

P denotes the pressure.

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Chapter 6, Problem 6.56QE

Chapter 6, Problem 6.58QE

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Chapter 6 Solutions

Chemistry: Principles and Practice

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