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Science Chemistry Chemistry: Principles and Practice

Root mean square speed of neon at 100 ° 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 .

Root mean square speed of neon at 100 ° 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 root mean square speed of neon is calculated using the Kinetic molecular theory. The formula to convert degree Celsius to kelvin is as follows.

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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Concept explainers

Kinetic-Theory of Gases

Kinetic theory of gases is the model or method which was developed in the 19th century by Maxwell and Boltzmann. This is possible as the interatomic force which is of short-range forces that are important for solids and liquids can be neglected for gases…

Question

Chapter 6, Problem 6.99QE

Interpretation Introduction

Interpretation:

Root mean square speed of neon at 100 °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 6.98QE

Chapter 6, Problem 6.100QE

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Find the rms speed of the molecules of a sample of N2 (diatomic nitrogen) gas at a temperature of 39.7° C .

c) This relationship is known as Graham's Law of Effusion. Since both gases are at te same temperature, they must have the same average kinetic energy (½ mv²), where m is mass and v is velocity (like speed). Since both gases have the same average kinetic energy, you can state that ½ muvL2 = v ². Multiplying both sides by 2 gives you m v 2 y ². Rearranging the equation to get H H LL H H 2 m = m both masses on the same side of the equation will give you mu/mH = V 2/VL2. In 3a and 3b, you probably noticed that the heavy gas particles took twice as long to diffuse as the light gas particles. This means that the light gas particles are moving twice as fast, VH/VL = ½. Therefore, V 2/VL2 = ¼. How many times heavier is the heavy gas compared to the light gas? d) If the light gas was Ne, what would be a reasonable identity for the heavy gas?

Chapter 6 Solutions

Chemistry: Principles and Practice

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