In geometric units, every time interval is interpreted as the distance travelled by light during that given time interval. That is, one second is interpreted as one light-second, so time has the geometric units of length. This is dimensionally consistent with the notion that, according to the kinematical laws of special relativity, time and distance are on an equal footing. Energy and momentum are interpreted as components of the four-momentum vector, and mass is the magnitude of this vector, so in geometric units these must all have the dimension of length. We can convert a mass expressed in kilograms to the equivalent mass expressed in metres by multiplying by the conversion factorG/c2. For example, the Sun's mass of in SI units is equivalent to. This is half the Schwarzschild radius of a one solar mass black hole. All other conversion factors can be worked out by combining these two. The small numerical size of the few conversion factors reflects the fact that relativistic effects are only noticeable when large masses or high speeds are considered.
Conversions
Listed below are all conversion factors that are useful to convert between all combinations of the SI base units, and if not possible, between them and their unique elements, because ampere is a dimensionless ratio of two lengths such as , and candela is a dimensionless ratio of two dimensionless ratios such as ratio of two volumes = and ratio of two areas = , while mole is only a dimensionless Avogadro number of entities such as atoms or particles:
m
kg
s
C
K
m
1
c2/G
1/c
c2/1/2
c4/
kg
G/c2
1
G/c3
1/2
c2/kB
s
c
c3/G
1
c3/1/2
c5/
C
1/2/c2
1/1/2
1/2/c3
1
c2/
K
GkB/c4
kB/c2
GkB/c5
kB1/2/c2
1
Geometric quantities
The components of curvature tensors such as the Einstein tensor have, in geometric units, the dimensions of sectional curvature. So do the components of the stress–energy tensor. Therefore the Einstein field equation is dimensionally consistent in these units. Path curvature is the reciprocal of the magnitude of the curvature vector of a curve, so in geometric units it has the dimension of inverse length. Path curvature measures the rate at which a nongeodesic curve bends in spacetime, and if we interpret a timelike curveas the world line of some observer, then its path curvature can be interpreted as the magnitude of the acceleration experienced by that observer. Physical quantities which can be identified with path curvature include the components of the electromagnetic field tensor. Any velocity can be interpreted as the slope of a curve; in geometric units, slopes are evidently dimensionless ratios. Physical quantities which can be identified with dimensionless ratios include the components of the electromagnetic potential four-vector and the electromagnetic current four-vector. Physical quantities such as mass and electric charge which can be identified with the magnitude of a timelike vector have the geometric dimension of length. Physical quantities such as angular momentum which can be identified with the magnitude of a bivector have the geometric dimension of area. Here is a table collecting some important physical quantities according to their dimensions in geometrized units. They are listed together with the appropriate conversion factor for SI units.
Quantity
SI dimension
Geometric dimension
Multiplication factor
Length
1
Time
c
Mass
Gc−2
Velocity
1
c−1
Angular velocity
c−1
Acceleration
c−2
Energy
Gc−4
Energy density
Gc−4
Angular momentum
Gc−3
Force
1
Gc−4
Power
1
Gc−5
Pressure
Gc−4
Density
Gc−2
Electric charge
G1/2c−2−1/2
Electric potential
1
G1/2c−21/2
Electric field
G1/2c−21/2
Magnetic field
G1/2c−11/2
Potential
1
G1/2c−11/2
This table can be augmented to include temperature, as indicated above, as well as further derived physical quantities such as various moments.
