The units of D 12 is to be identified using equation 19.54. Concept introduction: The mutual diffusion constant involves the three mean free paths, that is, between like gas particles and between the different gas particles. The mutual diffusion constant is given by, D 12 = 3 8 ⋅ R T 2 π μ ⋅ 1 ( r 1 + r 2 ) 2 ρ tot Where, • D 12 is the mutual diffusion constant. • μ is the reduced molar mass. • r 1 and r 2 are the radius of two particles 1 and 2 • ρ tot is the total particle density. • R is the gas constant. • T is the temperature. The mutual diffusion constant does not depend on the mole fractions of the involved gases.

Question

What is the molarity of a 0.393 m glucose solution if its density is 1.16 g/mL? MM glucose 180.2 g/mol

Answer 1

Question

Chapter 19, Problem 19.61E

Interpretation Introduction

Interpretation:

The units of D12 is to be identified using equation 19.54.

Concept introduction:

The mutual diffusion constant involves the three mean free paths, that is, between like gas particles and between the different gas particles. The mutual diffusion constant is given by,

D12=38⋅RT2πμ⋅1(r1+r2)2ρtot

Where,
• D12 is the mutual diffusion constant.

• μ is the reduced molar mass.

• r1 and r2 are the radius of two particles 1 and 2

• ρ tot is the total particle density.

• R is the gas constant.

• T is the temperature.

The mutual diffusion constant does not depend on the mole fractions of the involved gases.

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Answer 2

Question

Chapter 19, Problem 19.61E

Interpretation Introduction

Interpretation:

The units of D12 is to be identified using equation 19.54.

Concept introduction:

The mutual diffusion constant involves the three mean free paths, that is, between like gas particles and between the different gas particles. The mutual diffusion constant is given by,

D12=38⋅RT2πμ⋅1(r1+r2)2ρtot

Where,
• D12 is the mutual diffusion constant.

• μ is the reduced molar mass.

• r1 and r2 are the radius of two particles 1 and 2

• ρ tot is the total particle density.

• R is the gas constant.

• T is the temperature.

The mutual diffusion constant does not depend on the mole fractions of the involved gases.

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Answer 3

Question

Chapter 19, Problem 19.61E

Interpretation Introduction

Interpretation:

The units of D12 is to be identified using equation 19.54.

Concept introduction:

The mutual diffusion constant involves the three mean free paths, that is, between like gas particles and between the different gas particles. The mutual diffusion constant is given by,

D12=38⋅RT2πμ⋅1(r1+r2)2ρtot

Where,
• D12 is the mutual diffusion constant.

• μ is the reduced molar mass.

• r1 and r2 are the radius of two particles 1 and 2

• ρ tot is the total particle density.

• R is the gas constant.

• T is the temperature.

The mutual diffusion constant does not depend on the mole fractions of the involved gases.

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Answer 4

Question

Chapter 19, Problem 19.61E

Interpretation Introduction

Interpretation:

The units of D12 is to be identified using equation 19.54.

Concept introduction:

The mutual diffusion constant involves the three mean free paths, that is, between like gas particles and between the different gas particles. The mutual diffusion constant is given by,

D12=38⋅RT2πμ⋅1(r1+r2)2ρtot

Where,
• D12 is the mutual diffusion constant.

• μ is the reduced molar mass.

• r1 and r2 are the radius of two particles 1 and 2

• ρ tot is the total particle density.

• R is the gas constant.

• T is the temperature.

The mutual diffusion constant does not depend on the mole fractions of the involved gases.

Expert Solution & Answer

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Answer 5

Chapter 19, Problem 19.61E

Interpretation Introduction

Interpretation:

The units of D12 is to be identified using equation 19.54.

Concept introduction:

The mutual diffusion constant involves the three mean free paths, that is, between like gas particles and between the different gas particles. The mutual diffusion constant is given by,

D12=38⋅RT2πμ⋅1(r1+r2)2ρtot

Where,
• D12 is the mutual diffusion constant.

• μ is the reduced molar mass.

• r1 and r2 are the radius of two particles 1 and 2

• ρ tot is the total particle density.

• R is the gas constant.

• T is the temperature.

The mutual diffusion constant does not depend on the mole fractions of the involved gases.

Answer 6

Chapter 19, Problem 19.61E

Interpretation Introduction

Interpretation:

The units of D12 is to be identified using equation 19.54.

Concept introduction:

The mutual diffusion constant involves the three mean free paths, that is, between like gas particles and between the different gas particles. The mutual diffusion constant is given by,

D12=38⋅RT2πμ⋅1(r1+r2)2ρtot

Where,
• D12 is the mutual diffusion constant.

• μ is the reduced molar mass.

• r1 and r2 are the radius of two particles 1 and 2

• ρ tot is the total particle density.

• R is the gas constant.

• T is the temperature.

The mutual diffusion constant does not depend on the mole fractions of the involved gases.

Answer 7

Chapter 19, Problem 19.61E

Interpretation Introduction

Interpretation:

The units of D12 is to be identified using equation 19.54.

Concept introduction:

The mutual diffusion constant involves the three mean free paths, that is, between like gas particles and between the different gas particles. The mutual diffusion constant is given by,

D12=38⋅RT2πμ⋅1(r1+r2)2ρtot

Where,
• D12 is the mutual diffusion constant.

• μ is the reduced molar mass.

• r1 and r2 are the radius of two particles 1 and 2

• ρ tot is the total particle density.

• R is the gas constant.

• T is the temperature.

The mutual diffusion constant does not depend on the mole fractions of the involved gases.

Answer 8

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Answer 19

Ch. 19 - Prob. 19.1E Ch. 19 - What is the kinetic energy of a single atom of...Ch. 19 - Prob. 19.3E Ch. 19 - One mole of Ne atoms confined to a volume of 10.0L...Ch. 19 - Prob. 19.5E Ch. 19 - Prob. 19.6E Ch. 19 - Prob. 19.7E Ch. 19 - Prob. 19.8E Ch. 19 - Prob. 19.9E Ch. 19 - Prob. 19.10E

Solution Summary: The author explains that the mutual diffusion constant involves the three mean free paths, that is, between like gas particles and between the different gases.

Chapter 19 Solutions