Chemistry and Chemical Reactivity - AP Edition
Chemistry and Chemical Reactivity - AP Edition
10th Edition
ISBN: 9781337399203
Author: Kotz
Publisher: CENGAGE L
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Chapter 10, Problem 107SCQ

A 1.0-L flask contains 10.0 g each of O2 and CO2 at 25 °C.

  1. (a) Which gas has the greater partial pressure, O2 or CO2, or are they the same?
  2. (b) Which molecules have the greater rms speed, or are they the same?
  3. (c) Which molecules have the greater average kinetic energy, or are they the same?

(a)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

For the given set of gases under given temperature, volume and amount the gas with greater partial pressure, with greater rms speed and the gas with greater average kinetic energy should be determined.

Concept introduction:

Ideal gas Equation:

Any gas is described by using four terms namely pressure, volume, temperature and the amount of gas.  Thus combining three laws namely Boyle’s, Charles’s Law and Avogadro’s Hypothesis the following equation could be obtained.  It is referred as ideal gas equation.

   nTPV = RnTPPV = nRTwhere,n = moles of gasP = pressureT = temperatureR = gas constant

Under some conditions gases don not behave like ideal gas that is they deviate from their ideal gas properties.  At lower temperature and at high pressures the gas tends to deviate and behave like real gases.

Boyle’s Law:

At given constant temperature conditions the mass of given ideal gas in inversely proportional to its volume.

Charles’s Law:

At given constant pressure conditions the volume of ideal gas is directly proportional to the absolute temperature.

Avogadro’s Hypothesis:

Two equal volumes of gases with same temperature and pressure conditions tend to have same number of molecules with it.

The root mean square velocity μ is defined as the measure of velocity of particle in gas.  It is the method to determine the single velocity value for particles.

Root mean square velocity can be determined,

  μrms=(3RTM)1/2 (1)

  (gas constant)R=8.314JKmolM=Molarmass

Molar mass: The molar mass of a substance is determined by dividing the given mass of substance by the amount of the substance.

Average Kinetic energy: The kinetic energy for the gas is directly proportional to the kelvin temperature.  The kinetic energy is equal to half of the multiplied value obtained by multiplication of mass of gas with rms velocity of the gas.

Answer to Problem 107SCQ

The gas O2 has greater partial pressure than the other gas CO2

Explanation of Solution

Given:

  Volume,V=1LMassofO2=10gmoles =massmolar mass=10g32g/mol=0.3125molMassofCO2=10gmoles =massmolar mass=10g44.01g/mol=0.2272molTemperature,T = 25oC = 273.15+25 = 298.15K

Using ideal gas equation the partial pressure for each of the given gas is calculated as follows,

  PV= nRTP = nRTVPO2=0.3125mol×0.0821×298.15K1=7.65atmPCO2=0.2272mol×0.0821×298.15K1=5.56atm

From the above calculation it is clear that O2 has larger partial pressure it is due to the fact that O2 have larger number of molecules compared with carbon dioxide which is obtained by multiplying moles with 6.023×1023.

(b)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: For the given set of gases under given temperature, volume and amount the gas with greater partial pressure, with greater rms speed and the gas with greater average kinetic energy should be determined.

Concept introduction:

Ideal gas Equation:

Any gas is described by using four terms namely pressure, volume, temperature and the amount of gas.  Thus combining three laws namely Boyle’s, Charles’s Law and Avogadro’s Hypothesis the following equation could be obtained.  It is referred as ideal gas equation.

   nTPV = RnTPPV = nRTwhere,n = moles of gasP = pressureT = temperatureR = gas constant

Under some conditions gases don not behave like ideal gas that is they deviate from their ideal gas properties.   At lower temperature and at high pressures the gas tends to deviate and behave like real gases.

Boyle’s Law:

At given constant temperature conditions the mass of given ideal gas in inversely proportional to its volume.

Charles’s Law:

At given constant pressure conditions the volume of ideal gas is directly proportional to the absolute temperature.

Avogadro’s Hypothesis:

Two equal volumes of gases with same temperature and pressure conditions tend to have same number of molecules with it.

The root mean square velocity μ is defined as the measure of velocity of particle in gas.  It is the method to determine the single velocity value for particles.

Root mean square velocity can be determined,

  μrms=(3RTM)1/2 (1)

  (gas constant)R=8.314JKmolM=Molarmass

Molar mass: The molar mass of a substance is determined by dividing the given mass of substance by the amount of the substance.

Average Kinetic energy: The kinetic energy for the gas is directly proportional to the kelvin temperature.  The kinetic energy is equal to half of the multiplied value obtained by multiplication of mass of gas with rms velocity of the gas.

Answer to Problem 107SCQ

The gas O2 has greater rms speed.

Explanation of Solution

The rms speed for the given set of gases is determined as follows,

  μrms=(3RTM)1/2rms speed for O2(38.314×298.1532)1/2=(11423.3232)1/2=356.98m/srms speed for CO2(38.314×298.1544.01)1/2=(11423.3244.01)1/2=259.6m/s

From the above calculation it is clear that O2 has larger rms speed value.

(c)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation: For the given set of gases under given temperature, volume and amount the gas with greater partial pressure, with greater rms speed and the gas with greater average kinetic energy should be determined.

Concept introduction:

Ideal gas Equation:

Any gas is described by using four terms namely pressure, volume, temperature and the amount of gas.  Thus combining three laws namely Boyle’s, Charles’s Law and Avogadro’s Hypothesis the following equation could be obtained.  It is referred as ideal gas equation.

   nTPV = RnTPPV = nRTwhere,n = moles of gasP = pressureT = temperatureR = gas constant

Under some conditions gases don not behave like ideal gas that is they deviate from their ideal gas properties.  At lower temperature and at high pressures the gas tends to deviate and behave like real gases.

Boyle’s Law:

At given constant temperature conditions the mass of given ideal gas in inversely proportional to its volume.

Charles’s Law:

At given constant pressure conditions the volume of ideal gas is directly proportional to the absolute temperature.

Avogadro’s Hypothesis:

Two equal volumes of gases with same temperature and pressure conditions tend to have same number of molecules with it.

The root mean square velocity μ is defined as the measure of velocity of particle in gas. It is the method to determine the single velocity value for particles.

Root mean square velocity can be determined,

  μrms=(3RTM)1/2 (1)

  (gas constant)R=8.314JKmolM=Molarmass

Molar mass: The molar mass of a substance is determined by dividing the given mass of substance by the amount of the substance.

Average Kinetic energy: The kinetic energy for the gas is directly proportional to the kelvin temperature.  The kinetic energy is equal to half of the multiplied value obtained by multiplication of mass of gas with rms velocity of the gas.

Answer to Problem 107SCQ

Both the given gases have same kinetic energy since both are under same temperature conditions.

Explanation of Solution

The kinetic energy for the molecules is determined by the temperature in which the gases are placed.  Both the given gases are placed under same temperature that is at 25oC tends to have equal kinetic energy values.

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Chapter 10 Solutions

Chemistry and Chemical Reactivity - AP Edition

Ch. 10.6 - Prob. 10.11CYUCh. 10.7 - Prob. 10.12CYUCh. 10.8 - Prob. 1.1ACPCh. 10.8 - Prob. 1.2ACPCh. 10.8 - At sea level, atmospheric pressure is 1.00 atm....Ch. 10.8 - Prob. 2.2ACPCh. 10.8 - To stay aloft, a blimp must achieve neutral...Ch. 10.8 - Nitrogen gas is produced not only by NaN3...Ch. 10.8 - Prob. 3.2ACPCh. 10 - Pressure (See Section 10.1 and Example 10.1.) The...Ch. 10 - The average barometric pressure at an altitude of...Ch. 10 - Indicate which represents the higher pressure in...Ch. 10 - Put the following in order of increasing pressure:...Ch. 10 - Prob. 5PSCh. 10 - Prob. 6PSCh. 10 - You have 3.5 L of NO at a temperature of 22.0 C....Ch. 10 - Prob. 8PSCh. 10 - Prob. 9PSCh. 10 - You have a sample of CO2 in flask A with a volume...Ch. 10 - You have a sample of gas in a flask with a volume...Ch. 10 - A sample of gas occupies 135 mL at 22.5 C; the...Ch. 10 - One of the cylinders of an automobile engine has a...Ch. 10 - A helium-filled balloon of the type used in...Ch. 10 - Nitrogen monoxide reacts with oxygen to give...Ch. 10 - Ethane bums in air to give H2O and CO2. 2 C2H6(g)...Ch. 10 - A 1.25-g sample of CO2 is contained in a 750.-mL...Ch. 10 - A balloon holds 30.0 kg of helium. 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