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Science Chemistry Chemistry: Principles and Practice

The gases neon at 25 ° C , helium at 100 ° C and argon at 0 ° C has to be arranged in order of average molecular speed of the particles. 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 Since gas constant R , and temperature T are constants so root mean square speed is inversely related to the square root of the molar mass. u rms = 1 M

The gases neon at 25 ° C , helium at 100 ° C and argon at 0 ° C has to be arranged in order of average molecular speed of the particles. 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 Since gas constant R , and temperature T are constants so root mean square speed is inversely related to the square root of the molar mass. u rms = 1 M

Solution Summary: The author explains that the average molecular speed of the gases neon, helium, and argon is inversely related to the square root of molar mass.

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 6.98QE

Interpretation Introduction

Interpretation:

The gases neon at 25 °C, helium at 100 °C and argon at 0 °C has to be arranged in order of average molecular speed of the particles.

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

Since gas constant R, and temperature T are constants so root mean square speed is inversely related to the square root of the molar mass.

urms=1M

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Chapter 6, Problem 6.97QE

Chapter 6, Problem 6.99QE

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Chapter 6 Solutions

Chemistry: Principles and Practice

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