Coulomb's law has the form:
| (1) |
| (2) |
The choices for these constants in the SI and Gaussian units are given below:
CGS (Gaussian) | SI | |
KC | 1 | [1/( 4 pe0)] |
KA | [1/( c2)] | [(m0)/( 4 p)] |
Here, [(m0)/( 4 p)] º 10-7 N/A2 and [1/( 4 pe0)] = c2 ·10-7 N/A2 = 8.98755×109 N ·m2/C2.
Below is a table comparing SI and Gaussian unit systems. The fundamental units for each system are so labeled and are used to define the derived units.
Variable | SI | Gaussian | SI/Gaussian | ||
Unit | Relation | Unit | Relation | ||
length | m | fundamental | cm | fundamental | 100 |
mass | kg | fundamental | gm | fundamental | 1000 |
time | s | fundamental | s | fundamental | 1 |
force | N | kg ·m2/s | dyne | gm ·cm2/s | 105 |
current | A | fundamental | statampere | statcoulomb/s | [1/ 10 c] |
charge | C | A ·s | statcoulomb | Ö{dyne ·cm2} | [1/ 10 c] |
One advantage of the Gaussian system is that all of the field vectors: E,D,B,H,P,M have the same dimensions, and in vacuum, B = H and E = D and the dielectric and permittivity constants e and m are unitless.
CGS (Gaussian) | SI |
Ñ·D = 4 pr | Ñ·D = r |
Ñ·B = 0 | Ñ·B = 0 |
Ñ×E = - 1/c [(¶B)/( ¶t)] | Ñ×E = - [(¶B)/( ¶t)] |
Ñ×H = [(4 p)/ c] J + 1/c [(¶D)/( ¶t)] | Ñ×H = J + [(¶D)/( ¶t)] |
F = q (E + [(v)/ c] ×B | F = q (E + v ×B |
u = [1/( 8 p)] (E·D+B·H) | u = 1/2 (E·D+B·H) |
S = [c/( 4 p)] (E ×H) | S = (E ×H) |