22 Chapter 1Numbers, variables, and units
The standard acceleration of gravity isg 1 = 1 9.80665 m s
− 21 = 1 980.665 Gal, where
Gal 1 = 110
− 2m s
− 2(cm s
− 2) is called the galileo.
(iii)Forcehas dimensions of mass ×acceleration:
[M] 1 × 1 [LT
− 2] 1 = 1 MLT
− 2, with SI unit the newton,N 1 = 1 kg m s
− 2.
(iv)Pressurehas dimensions of force per unit area:
[MLT
− 2] 2 [L
2] 1 = 1 ML
− 1T
− 2, with SI unit thepascal,Pa 1 = 1 N m
− 21 = 1 kg m
− 1s
− 2Widely used alternative non-SI units for pressure are:
‘standard pressure’: bar 1 = 110
5Pa
atmosphere: atm 1 = 1 101325 Pa
torr: Torr 1 = 1 (101325 2 760) Pa 1 ≈ 1 133.322 Pa
(v)Work, energy and heatare quantities of the same kind, with the same dimensions
and unit. Thus, work has dimensions of force ×distance:
[MLT
− 2] 1 × 1 [L] 1 = 1 ML
2T
− 2, with SI unit thejoule,J 1 = 1 N m 1 = 1 kg m
2s
− 2and kinetic energy has dimensions of mass ×(velocity)
2:
[M] 1 × 1 [LT
− 1]
21 = 1 ML
2T
− 2.
0 Exercises 91–94
Dimensional analysis
The terms on both sides of an equation that contains physical quantities must have
the same dimensions. Dimensional analysis is the name given to the checking of
equations for dimensional consistency.
EXAMPLE 1.17For the ideal-gas equationpV 1 = 1 nRT, equation (1.1), the dimensions
of pV(using Tables 1.1 and 1.2) are those of work (or energy): [ML
− 1T
− 2] 1 × 1 [L
3] 1 = 1 ML
2T
− 2.
The corresponding expression in terms of SI units is
Pa 1 × 1 m
31 = 1 N m
− 21 × 1 m
31 = 1 N m 1 = 1 J.
For nRT,
(mol)(J K
− 1mol
− 1)(K) 1 = 1 J
122mv