Chemistry: An Atoms First Approach
Chemistry: An Atoms First Approach
2nd Edition
ISBN: 9781305079243
Author: Steven S. Zumdahl, Susan A. Zumdahl
Publisher: Cengage Learning
Question
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Chapter 19, Problem 70E
Interpretation Introduction

Interpretation: The temperature, pressure and dimension of a room is given. The mass and number of argon atoms in the room is to be calculated. Also, the number of argon atoms inhaled in one breath is to be calculated. The difference in the health risk between argon gas and radon gas is to be explained.

Concept introduction: The expression to calculate the number of moles of an atom is,

PV=nRTn=PVRT

To determine: The mass and number of argon atoms in the room at 25°C and 1atm ; the number of argon atoms inhaled in one breath; the explanation of the difference in the health risk between argon gas and radon gas.

Expert Solution & Answer
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Answer to Problem 70E

Answer

The mass of argon atom in the given volume of room is 1.5×104g_ .

The number of argon atoms in the given volume of room is 2.2×1026atoms_ .

The number of argon atoms inhaled in one breath is 4.5×1020atoms_ .

The main difference between argon and radon is that, radon is a radioactive element whereas argon is not a radioactive element.

Explanation of Solution

Explanation

Given

Dimension of room is 10.0m×10.0m×10.0m .

Temperature is 25°C .

Pressure is 1.0atm .

Refer to Table 19-22 .

Atmospheric abundance of argon is 9.0×101 .

Volume of room is equal to the dimension. The volume of room is,

10.0m×10.0m×10.0m=1.0×103m3

The conversion of cubic meter (m3) into liter (L) is done as,

1m3=103L

Hence, the conversion of 1.0×103m3 into liter is,

1.0×103m3=(1.0×103×103)L=1.0×106L

Volume of argon in the room is 1.0×106L . But, the percentage of atmospheric abundance of argon is 9.0×101 .

Hence, the overall volume of argon is,

1.0×106L(9.0×101100)=9.0×103L

The conversion of degree Celsius (°C) into Kelvin (K) is done as,

T(K)=T(°C)+273

Hence, the conversion of 25°C into Kelvin is,

T(K)=T(°C)+273T(K)=(25+273)K=298K

Formula

Number of moles of argon is calculated using the formula,

PV=nRTn=PVRT

Where,

  • P is the total pressure.
  • V is the volume.
  • n is the total moles.
  • R is the universal gas constant (0.08206Latm/Kmol) .
  • T is the absolute temperature.

Substitute the values of P,V,R and T in the above equation.

n=PVRT=9.0×103L(1.0atm)(0.08206Latm/Kmol)(298K)=368mol_

The mass of argon atom in the given volume of room is 1.5×104g_ .

The number of moles of argon is 368mol .

The atomic mass of argon is 39.95g/mol .

Formula

The mass of argon is calculated using the formula,

m=nM

Where,

  • m is the mass of argon.
  • M is the atomic mass of argon.
  • n is the number of moles of argon.

Substitute the values of M and n in the above equation.

m=nM=386mol×39.95g/mol=1.5×104g_

The number of argon atoms in the given volume of room is 2.2×1026atoms_ .

The number of moles of argon is 368mol .

Formula

The number of argon atoms is calculated using the formula,

N=nA

Where,

  • N is the number of argon atoms.
  • A is the Avogadro’s number (6.023×1023) .
  • n is the number of moles of argon.

Substitute the values of A and n in the above equation.

N=nA=(6.023×1023)(386)=2.2×1026atoms_

Number of moles of argon in the given volume of air is 7.4×104mol_ .

Given

Volume of air in the room is 2.0L .

Temperature is 25°C .

Pressure is 1.0atm .

The conversion of degree Celsius (°C) into Kelvin (K) is done as,

T(K)=T(°C)+273

Hence, the conversion of 25°C into Kelvin is,

T(K)=T(°C)+273T(K)=(25+273)K=298K

Given volume of air in the room is 2.0L . Since, the percentage atmospheric abundance of argon is 9.0×101 .

Hence, the overall volume of argon breathed is,

2.0L(9.0×101100)=0.018L

Formula

Number of moles of argon is calculated using the formula,

PV=nRTn=PVRT

Where,

  • P is the total pressure.
  • V is the volume.
  • n is the total moles.
  • R is the universal gas constant (0.08206Latm/Kmol) .
  • T is the absolute temperature.

Substitute the values of P,V,R and T in the above equation.

n=PVRT=0.018L(1.0atm)(0.08206Latm/Kmol)(298K)=7.4×104mol_

The number of argon atoms inhaled in one breath is 4.5×1020atoms_ .

Number of moles of argon taken in one breath is 7.4×104mol .

Formula

The number of argon atoms is calculated using the formula,

N=nA

Where,

  • N is the number of argon atoms.
  • A is the Avogadro’s number (6.023×1023) .
  • n is the number of moles of argon.

Substitute the values of A and n in the above equation.

N=nA=(6.023×1023)(7.4×104)=4.5×1020atoms_

The main difference between argon and radon is that, radon is a radioactive element whereas argon is not a radioactive element.

Both argon and radon are inert gas. But radon is a radioactive element. The long exposure of this element may cause lung cancer.

Conclusion

Conclusion

The required value of mass of argon atom in the given volume of room is 1.5×104g_ . The number of argon atoms in the given volume of room is 2.2×1026atoms_ . The number of argon atoms inhaled in one breath is 4.5×1020atoms_

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Chapter 19 Solutions

Chemistry: An Atoms First Approach

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