Changes: Unification of Fundamental Forces

{{Preliminary draft|kmarinas86}}

The increase of a refractive index of a material in this new idea is equivalent to a length contraction of that material. The length contraction is achieved by material formation inside high pressure zones inside planets and stars. The frequency of light remains the same however the distance light travels in a given period of time is reduced by the factor of length contraction.

<math>n^{3}</math><div style="background-color: white; margin: 3px; border: 1px #aaa solid ">Properties which are minimized by the cube of the factor of length contraction:

{| border="2" cellpadding="4" cellspacing="0" style="margin: 1em 1em 1em 0; background: #f9f9f9; border: 1px #aaa solid; border-collapse: collapse;"

|-

| volume

| m³

|-

| volume flow rate

| m³/s

| the volume of fluid that flows past a given cross sectional area per second

|-

| G

| m³/(kg•s²)

|-

| resistivity

| &Omega;•m

| property of matter which resists an electric field from getting from A to B

|}</div>

<math>m^{2}</math><div style="background-color: white; margin: 3px; border: 1px #aaa solid ">Properties which are minimized by the square of the factor of length contraction:

{| border="2" cellpadding="4" cellspacing="0" style="margin: 1em 1em 1em 0; background: #f9f9f9; border: 1px #aaa solid; border-collapse: collapse;"

|-

| area

| m²

|-

| energy (Political Analogue: freedom)

| J=kg•m²/s²

| quantity of energy itself

|-

| torque

| kg•m²/s²

| force applied to a member to produce rotational motion

|-

| heat capacity

| J/K

| proportion relating the amount of energy per temperature

|-

| thermal heat capacity

| J/kg

| the heat required to raise the temperature of a substance.

|-

| potential difference (Political Analogue: difficulty)

| J/C

| power per unit current. energy per unit charge. current times resistance. (volt)

|-

| magnetic flux

| Wb=J/A=V•s

| comes from an energetic magnetic field produced by a current (weber, Wb)

|-

| inductance

| J/A²

| accomodation of the production of magnetic flux per current

|-

| power (Political Analogue: power)

| W=J/s

| rate of energy expenditure

|-

| thermal conductance

| W/K

| rate of heat flow

|-

| kinematic viscosity

| m²/s

| ratio of dynamic viscosity to mass density

|-

| magnetic dipole moment

| A•m²

| a vector whose direction is normal to a loop of current. proportional to current and area.

|-

| thermal heat transfer coefficient

| (W/m²)/K

| coefficient, thermal conductance

|}</div>

<math>m^{1}</math><div style="background-color: white; margin: 3px; border: 1px #aaa solid ">Properties which are minimized by the factor of length contraction

{| border="2" cellpadding="4" cellspacing="0" style="margin: 1em 1em 1em 0; background: #f9f9f9; border: 1px #aaa solid; border-collapse: collapse;"

|-

| velocity

| m/s

|-

| velocity change with temperature

| (m/s)/K

| velocity increases with temperature

|-

| wavelength (distance)

| Meters

| m

|-

| electric dipole moment

| C•m

| a vector due to uneven distribution of unlike charges. proportional to charge and distance.

|-

| permeability

| N/A²

| allows an electric field to pass through easily, lets charge through

|-

| thermal conductivity

| (W/m)/K

| ability of a material to conduct heat.

|}</div>

<math>m^{0}</math><div style="background-color: white; margin: 3px; border: 1px #aaa solid ">Properties independent of length contraction:

{| border="2" cellpadding="4" cellspacing="0" style="margin: 1em 1em 1em 0; background: #f9f9f9; border: 1px #aaa solid; border-collapse: collapse;"

|-

| temperature

| K

| corresponding objects of the lower fractal are just as hot, or as cold, as they are in our fractal level

|-

| thermal expansion coefficient and temperature of color

| 1/K

| the fractional change in length or volume per Kelvin at constant pressure

|-

| luminous intensity

| Cd

| power emmited by a light source

|-

| luminous flux

| lm=Cd•sr

| Candelas times Steradians (lumens, lm)

|-

| coulombs (Political Analogue: charge(!))

electric flux

| C

| quantity of electric charge itself

|-

| mass

| Kilograms

| kg

|-

| thermal resistance coefficient

| K/(W/m²)

| coefficient, thermal resistance

|-

| frequency

| 1/s

| influences the other electrical properties for this lower fractal level (Hz, cycles per second)

|-

| angular frequency

| radians/s

| frequency with which phase changes

|-

| angular velocity

| radians/s

|-

| luminous energy

| lm•s

| quantity of light.

|-

| mass flow rate

| kg/s

| the mass of fluid that flows past a given cross sectional area per second

|-

| current (Political Analogue: achievement)

| A=C/s

| flow rate of electricity which provides a force that causes magnetic flux

|-

| magnetic flux density

| Wb/m²

| magnetic flux / area

|-

| applied tension

| J/m²=N/m

| work / area

|-

| surface tension

| J/m²

| the amount of tension that keeps a surface, especially of liquids together

|-

| angular acceleration

| radians/s²

| rate of change of angular velocity

|-

| resistance (Political Analogue: resistance)

| W/A²

| higher electrical resistance at the lower fractal level (ohms &Omega;)

|-

| angular momentum (Political Analogue: liberty)

| J•s

| the discrete quantity of action (quantum unit of angular momentum)

|}</div>

<math>m^{-1}</math><div style="background-color: white; margin: 3px; border: 1px #aaa solid ">Properties which maximized by the factor of length contraction:

{| border="2" cellpadding="4" cellspacing="0" style="margin: 1em 1em 1em 0; background: #f9f9f9; border: 1px #aaa solid; border-collapse: collapse;"

|-

| spectroscopic wavenumber

| 1/m

| the inverse of wavelength

|-

| dynamic viscosity

| (kg/s)/m

| the resistance of a fluid to deformation under shear stress

|-

| magnetic field strength

magnetization

| A/m

| an auxillary field which causes magnetic flux.

magnetic dipole moment per unit volume.

|-

| energy density

| J/m³

| energy / volume

|-

| pressure

| N/m²

|-

| force

| N=J/m

| comes from a energetic kinetic potential produced by an impulse

|-

| force/mass

| m/s²

|-

| impulse and momentum

| N•s=kg•m/s

| force * time. mass * velocity.

|-

| magnetic vector potential

| N/A=Wb/m

| force per amp. magnetic flux per meter.

|-

| electric field strength

| N/C

| force / charge

|}</div>

<math>m^{-2}</math><div style="background-color: white; margin: 3px; border: 1px #aaa solid ">Properties which maximized by the square of the factor of length contraction:

{| border="2" cellpadding="4" cellspacing="0" style="margin: 1em 1em 1em 0; background: #f9f9f9; border: 1px #aaa solid; border-collapse: collapse;"

|-

| luminous efficacy

| lm/W

| power as it appears to an observer versus the actual power

|-

| thermal resistance

| K/W

| index of a material's resistance to heat flow

the reciprocal of conductance

|-

| electric flux density

polarization density

| C/m²

| a field which causes electric flux.

electric dipole moment per unit volume.

|-

| luminosity

| Cd/m²

| light emission / area

|-

| acoustic impedance

| (kg/s)/m²

| proportional to the density and the phase velocity (speed of sound).

|-

| current density

| A/m²

|-

| light flux density

| lm/m²

| light incident / area

|-

| capacitance

| F=C/V=C²/J

| quantity of charge stored for every volt (farads)

|-

| conductance

| A*C/J

| current produced / (energy / charged particle)

|-

| reluctance

| A²/J

| resistance of the production of magnetic flux per current

|}</div>

<math>m^{-3}</math><div style="background-color: white; margin: 3px; border: 1px #aaa solid ">Properties which maximized by the cube of the factor of length contraction:

{| border="2" cellpadding="4" cellspacing="0" style="margin: 1em 1em 1em 0; background: #f9f9f9; border: 1px #aaa solid; border-collapse: collapse;"

|-

| density

| kg/m³

|-

| charge density

| C/m³

| charge / volume

|-

| permittivity

| C/(V•m)

| resists the flow of an electric field, contains charge

|-

| conductivity

| 1/(&Omega;•m)

| property of matter which allows an electric field to get from A to B

|}</div>