Chapter 10: Gases - Mr. West's Science...

Chapter 10

John Bookstaver

St. Charles Community College

St. Peters, MO

2006, Prentice Hall, Inc.

Chemistry, The Central Science, 10th edition

Theodore L. Brown; H. Eugene LeMay, Jr.;

and Bruce E. Bursten

Characteristics of Gases

• Unlike liquids and solids, they

Expand to fill their containers.

Are highly compressible.

Have extremely low densities.

• Pressure is the amount of force applied to an area.

Pressure

• Atmospheric

pressure is the

weight of air per

unit of area.

Units of Pressure

• Pascals

1 Pa = 1 N/m2

• Bar

1 bar = 105 Pa = 100 kPa

Units of Pressure

• mm Hg or torr

These units are literally

the difference in the

heights measured in mm

(h) of two connected

columns of mercury.

• Atmosphere

1.00 atm = 760 torr

Manometer

Used to measure the

difference in pressure

between atmospheric

pressure and that of a

gas in a vessel.

Standard Pressure

• Normal atmospheric pressure at sea level.

• It is equal to

1.00 atm

760 torr (760 mm Hg)

101.325 kPa

Boyle’s Law

The volume of a fixed quantity of gas at

constant temperature is inversely proportional

to the pressure.

Boyle’s Law

As P and V are

inversely proportional

A plot of V versus P results in a curve.

V = k (1/P)

This means a plot of

V versus 1/P will be

a straight line.

PV = k

Charles’s Law

• The volume of a fixed amount of gas at constant pressure is directly proportional to its absolute temperature.

A plot of V versus T will be a straight line.

• i.e., V

Avogadro’s Law

• The volume of a gas at constant temperature

and pressure is directly proportional to the

number of moles of the gas.

• Mathematically, this means V = kn

Ideal-Gas Equation

V 1/P (Boyle’s law)

V T (Charles’s law)

V n (Avogadro’s law)

• So far we’ve seen that

• Combining these, we get

Ideal-Gas Equation

The constant of

proportionality is

known as R, the

gas constant.

Ideal-Gas Equation

The relationship

then becomes

P V = R

PV = nRT

Ideal-Gas Equation

Densities of Gases

If we divide both sides of the ideal-gas

equation by V and by RT, we get

• We know that

moles molecular mass = mass

Densities of Gases

• So multiplying both sides by the

molecular mass ( ) gives

Densities of Gases

• Mass volume = density

• So,

• Note: One only needs to know the

molecular mass, the pressure, and the

temperature to calculate the density of

a gas.

V = d =

Molecular Mass

We can manipulate the density equation to enable us to find the molecular mass of a gas:

Becomes

RT d =

Dalton’s Law of

Partial Pressures

• The total pressure of a mixture of gases

equals the sum of the pressures that

each would exert if it were present

alone.

• In other words,

Ptotal = P1 + P2 + P3 + …

Partial Pressures of Gases

Partial Pressures

• When one collects a gas over water, there is

water vapor mixed in with the gas.

• To find only the pressure of the desired gas,

one must subtract the vapor pressure of

water from the total pressure.

Kinetic-Molecular Theory

This is a model that

aids in our

understanding of what

happens to gas

particles as

environmental

conditions change.

Main Tenets of Kinetic-

Molecular Theory

Gases consist of large numbers of

molecules that are in continuous,

random motion.

Molecular Theory

• The combined volume of all the

molecules of the gas is negligible

relative to the total volume in which the

gas is contained.

• Attractive and repulsive forces between

gas molecules are negligible.

Molecular Theory

Energy can be transferred between molecules during collisions, but the average kinetic energy of the molecules does not change with time, as long as the temperature of the gas remains constant.

Molecular Theory

The average kinetic

energy of the

molecules is

proportional to the

absolute

temperature.

Effusion

The escape of

gas molecules

through a tiny

hole into an

evacuated

space.

Diffusion

The spread of one

substance

throughout a space

or throughout a

second substance.

Boltzmann Distributions

Effect of Molecular Mass on

Rate of Effusion and Diffusion

Real Gases

In the real world, the

behavior of gases

only conforms to the

ideal-gas equation

at relatively high

temperature and low

pressure.

Deviations from Ideal Behavior

The assumptions made in the kinetic-molecular

model break down at high pressure and/or low

temperature.

Real Gases

Corrections for Nonideal

Behavior

• The ideal-gas equation can be adjusted

to take these deviations from ideal

behavior into account.

• The corrected ideal-gas equation is

known as the van der Waals equation.

The van der Waals Equation

) (V − nb) = nRT n2a

V2 (P +

Chapter 10: Gases - Mr. West's Science...

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