Difference between revisions of "Refraction"

From Flat Earth Community Wiki
Jump to navigation Jump to search
Line 24: Line 24:
  
 
The magnitude of change in the direction of the electromagnetic radiation is related to the magnitude of the difference in refractive indexes.
 
The magnitude of change in the direction of the electromagnetic radiation is related to the magnitude of the difference in refractive indexes.
This can be modeled as a discrete boundary ([[Snell's Law]]). In this case, the [[relative refractive index]] values at the boundary determine the change in direction. The standard usage of this model is when the medium has a well-defined boundary between two [[isotropic]] [[homogenous]] mediums.
+
This can be modeled as a discrete boundary ([[Snell's Law]]). In this case, the [[relative refractive index]] values at the boundary determine the change in direction. The standard usage of this model is when the medium has a well-defined [[boundary]] between two [[isotropic]] [[homogenous]] mediums.
  
 
[[File:Refr-diag-planesurf.jpg|thumb|left|Example diagram]]
 
[[File:Refr-diag-planesurf.jpg|thumb|left|Example diagram]]
Line 32: Line 32:
  
  
Refraction can also be modeled as a continuum according to Fermat's principle of least time. This method is necessary to model the path of electromagnetic radiation through certain types of mediums. The conditions for usage would be for mediums that have ill-defined boundaries, are inhomogeneous or are anisotropic.
+
Refraction can also be modeled as a continuum according to Fermat's [[principle of least time]]. This method is necessary to model the path of electromagnetic radiation through certain types of mediums. The conditions for usage would be for mediums that have ill-defined [[boundaries]], are [[inhomogeneous]] or are [[anisotropic]].
  
 
==References==
 
==References==

Revision as of 23:05, 31 March 2020

General Description

Refraction is the word used to describe the phenomenon of a change in direction that an electromagnetic wave travels in.[1] Electromagnetic radiation (which includes light) is observed to change direction when it's velocity changes. How much this velocity differs from the velocity in a vacuum is commonly called the refractive index. The vacuum value is set to 1 for all wavelengths of electromagnetic radiation.


This property of a medium has a few different names.

NAME
Index of Refraction
Refractive Index
Optical Density
Relative permittivity and permeability

Mechanisms of Refraction

It is commonly believed that the absolute value of the refractive index is what causes electromagnetic radiation to bend. This is an incorrect view. The change of direction of electromagnetic radiation occurs when an absolute refractive index along an arbitrary path of travel changes.

The magnitude of change in the direction of the electromagnetic radiation is related to the magnitude of the difference in refractive indexes. This can be modeled as a discrete boundary (Snell's Law). In this case, the relative refractive index values at the boundary determine the change in direction. The standard usage of this model is when the medium has a well-defined boundary between two isotropic homogenous mediums.

Example diagram
INFOGRAPHIC ABSOLUTE AND RELATIVE RI



Refraction can also be modeled as a continuum according to Fermat's principle of least time. This method is necessary to model the path of electromagnetic radiation through certain types of mediums. The conditions for usage would be for mediums that have ill-defined boundaries, are inhomogeneous or are anisotropic.

References