Sutherland’s Law

Sutherland’s law, or Sutherland’s formula, is an approximation for how the viscosity of gases depends on the temperature. This law is based on an idealized intermolecular-force potential and reads (Ref. 5)

(5-7)

where Sμ is an effective temperature called the Sutherland constant. Each gas has its own Sutherland constant. Equation 5-7 is strictly valid only for single-component gases at low pressure. It does, however, work well for air because air is mainly composed of nitrogen and oxygen, which have very similar properties. Parameter values for some common gases are given in Table 5-2 (Ref. 5).

Table 5-2: Sutherland’s Law Parameters for Dynamic Viscosity
Gas	μ0	T0	Sμ
Air	1.716·10-5	273	111
Argon	2.125·10-5	273	114
C02	1.370·10-5	273	222
CO	1.657·10-5	273	136
N2	1.663·10-5	273	107
O2	1.919·10-5	273	139
H2	8.411·10-5	273	97
Steam	1.12·10-5	350	1064

The SI unit for μ0 in Table 5-2 is N·s/m2. The SI unit for T0 and Sμ is kelvin (K).

Sutherland’s law can also be formulated for thermal conductivity (Ref. 5):

(5-8)

Values for k0, T0, and Sk for some common gases are given in Table 5-3(Ref. 5).

Table 5-3: Sutherland’s Law Parameters for Thermal Conductivity
Gas	k0	T0	S,k
Air	0.0241	273 K	194
Argon	0.0163	273	170
C02	0.0146	273	1800
CO	0.0232	273	180
N2	0.0242	273	150
O2	0.0244	273	240
H2	0.168	273	120
Steam	0.0181	300	2200

The unit for k0 in Table 5-3 is W/(m·K). The unit for T0 and Sk is kelvin (K).