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Science Chemistry Chemistry Principles And Practice

Molar mass of a gas that has rms speed of 518 m/s at 28 ° C has to be calculated. Concept Introduction: In accordance with the Kinetic molecular theory, not all of the gas particles will move at the same speed but with an average speed that is given by the expression as follows: K E ¯ = 1 2 m u 2 ¯ Here, K E ¯ is the average kinetic energy. m is the mass of particle. u 2 is the average of the speed. The relation between rms speed ( u rms ) , temperature, and molar mass is given by the equation, u rms = 3 R T M Here, R is the universal gas constant. T denotes temperature in kelvins. M denotes the molar mass in kg/mol .

Molar mass of a gas that has rms speed of 518 m/s at 28 ° C has to be calculated. Concept Introduction: In accordance with the Kinetic molecular theory, not all of the gas particles will move at the same speed but with an average speed that is given by the expression as follows: K E ¯ = 1 2 m u 2 ¯ Here, K E ¯ is the average kinetic energy. m is the mass of particle. u 2 is the average of the speed. The relation between rms speed ( u rms ) , temperature, and molar mass is given by the equation, u rms = 3 R T M Here, R is the universal gas constant. T denotes temperature in kelvins. M denotes the molar mass in kg/mol .

Solution Summary: The author explains how the molar mass of a gas that has an rms speed of 518 m/s at

Chemistry Principles And Practice

Chemistry Principles And Practice

3rd Edition

ISBN: 9781305295803

Author: David Reger; Scott Ball; Daniel Goode

Publisher: Cengage Learning

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Question

Chapter 6, Problem 6.101QE

Interpretation Introduction

Interpretation:

Molar mass of a gas that has rms speed of 518 m/s at 28 °C has to be calculated.

Concept Introduction:

In accordance with the Kinetic molecular theory, not all of the gas particles will move at the same speed but with an average speed that is given by the expression as follows:

KE¯=12mu2¯

Here,

KE¯ is the average kinetic energy.

m is the mass of particle.

u2 is the average of the speed.

The relation between rms speed (urms), temperature, and molar mass is given by the equation,

urms=3RTM

Here,

R is the universal gas constant.

T denotes temperature in kelvins.

M denotes the molar mass in kg/mol.

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Chapter 6, Problem 6.100QE

Chapter 6, Problem 6.102QE

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Chapter 6 Solutions

Chemistry Principles And Practice

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