Question 3
(a)
Describe the motion of molecules in a gas, according to the kinetic
theory of gases. [2]
(b)
Describe what is observed when viewing Brownian motion that provides
evidence for your answer in (a). [2]
(c)
At a pressure of 1.05 × 105 Pa
and a temperature of 27 °C, 1.00 mol of helium gas has a volume of 0.0240 m3.
The mass of 1.00 mol
of helium gas, assumed to be an ideal gas, is 4.00 g.
(i)
Calculate the root-mean-square (r.m.s.) speed of an atom of helium
gas for a temperature of 27 °C. [3]
(ii)
Using your answer in (i), calculate the r.m.s.
speed of the atoms at 177 °C. [3]
[Total: 10]
Reference: Past Exam Paper – June 2017 Paper 41 & 43 Q4
Solution:
(a)
The molecules move in random motion with a distribution of
speeds and in different directions.
(b)
Small specks of light are observed to move in random
directions.
(c)
(i)
pV = ⅓ Nm〈c2〉
{N is the total number of molecules; N = 1 (for
1 atom)
and m is the mass of 1 molecule
So, Nm is the total mass of the gas (in kg)}
1.05×105 × 0.0240 = ⅓ × 4.00×10-3 × 〈c2〉
〈c2〉 = 1.89 × 106
OR
{Kinetic energy = (3 / 2) kT }
½ m〈c2〉 =
(3 / 2) kT
{m is the mass of 1 molecule / atom
1 mole
- - - > 4.00 g
6.02 × 1023 molecules - - > 4.00 g = 4.00 × 10-3 kg
1 molecule
- - > (4.00 × 10-3 / 6.02 × 1023)
Temperature should be in kelvin}
0.5 × (4.00
× 10-3 / 6.02 × 1023) × 〈c2〉 = 1.5 × 1.38
× 10-23 × 300
〈c2〉 = 1.89 × 106
OR
{pV
= nRT and pV = 1/3 Nm〈c2〉
So,}
nRT = ⅓ Nm〈c2〉
{n : number of moles
N: total number of molecules
m: mass of 1 molecule
Nm: total mass of gas}
1.00 × 8.31
× 300 = ⅓ × 4.00 × 10-3 × 〈c2〉
〈c2〉 = 1.89 × 106
{crms
= √〈c2〉}
cr.m.s. = 1.37 × 103 m s-1
(ii)
{ nRT = ⅓ Nm〈c2〉
So, 〈c2〉 ∝ T }
〈c2〉 ∝ T
{The
mean-square speed is proportional to the absolute temperature.
T is
the thermodynamic temperature (that in, in kelvin)
27°C = 300 K and 177°C
= 177 + 273 = 450 K
From
above,
〈c2〉 ∝ T
〈c2〉 at 300 K - - > 1.89×106
〈c2〉 at 450 K - - > 1.89 × 106 × (450 / 300)}
〈c2〉 at 177 °C = 1.89 × 106 × (450 / 300)
cr.m.s. at 177 °C = 1.68 × 103 m s-1
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