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FSCA085 Física General

Propagation, Reflection and Refraction

Geometric Optics

Training Reflection and Refraction

Training Interference and Diffraction

Light and Colors

Light and Colors

Storyboard

One of the characteristics of the Light is its color. This is associated with the frequency of the wave and is proportional to the energy of the photon that represents light in its corpuscular description.

ID:(759, 0)

Rainbow

Image

If you observe a rainbow, you'll notice that there are actually multiple rainbows, and the sequence of colors shifts: from blue to red and then from red to blue again, and so on.

ID:(1844, 0)

The spectre

Image

As the angle of refraction depends on the frequency or wavelength of light in glass, a prism can be used to decompose light into its different colors.

This results in what we call the spectrum of light.

ID:(6972, 0)

The light and its colors

Image

A rainbow shows us that the light illuminating it is broken down into multiple colors. In fact, upon careful observation, you can see that there are multiple rainbows.

This is because each water droplet acts as a tiny circular prism, allowing for multiple refractions and the creation of multiple rainbows.

ID:(1625, 0)

Spectrum according to Newton

Image

Newton used a prism to decompose light into its components, believing he could identify a finite number of colors:

ID:(1682, 0)

Sir Isaac Newton

Image

The first to comprehend the structure of light as a physical entity was Sir Isaac Newton.

Sir Isaac Newton
(1643-1727)
Through a very simple experiment, he demonstrated that white light was composed of colors. However, he believed that the number of colors was discrete, as indicated in his chart representing his observations.

ID:(6971, 0)

The reality of things

Image

The colors we see don't always necessarily correspond to reality. Our eyes capture light and generate electrical impulses based on the amount of blue, red, and green light we perceive. However, the intensity may not accurately represent the real proportions, leading to a perception that differs from reality:

ID:(12676, 0)

Light and Colors

Model

One of the characteristics of the Light is its color. This is associated with the frequency of the wave and is proportional to the energy of the photon that represents light in its corpuscular description.

Variables

Symbol

Text

Variable

Value

Units

Calculate

MKS Value

MKS Units

$n$

n

Air-Lens Refractive Index

-

$\lambda_m$

lambda_m

Largo de onda de la luz en un medio

nm

$\lambda$

lambda

Light Wavelength

m

$\epsilon$

e

Photon energy

J

$\nu$

nu

Photon frequency

Hz

$h$

h

Planck constant

Js

$c$

c

Speed of Light

m/s

$v$

v

Speed of Light in medium

m/s

Calculations

Equation

Number

First, select the equation:

to

, then, select the variable:

to

Symbol

Equation

Solved

Translated

Calculations

Symbol

Equation

Solved

Translated

Variable

Given

Calculate

Target :

Equation

To be used

Equations

$ n =\displaystyle\frac{ c }{ v }$

n = c / v

(ID 3192)

$ \epsilon = h \nu $

e = h * nu

(ID 3341)

$ c = \nu \lambda $

c = nu * lambda

Given that the photon frequency ($\nu$) is the inverse of the period ($T$):

$\nu=\displaystyle\frac{1}{T}$

this means that the speed of Light ($c$) is equal to the distance traveled in one oscillation, which is ERROR:8439, divided by the elapsed time, which corresponds to the period:

$c=\displaystyle\frac{\lambda}{T}$

In other words, the following relationship holds:

$ c = \nu \lambda $

(ID 3953)

$ n =\displaystyle\frac{ \lambda }{ \lambda_m }$

n = lambda / lambda_m

The energy of a wave or particle (photon) of light is given by

$ \epsilon = h \nu $

When this energy propagates from one medium, for example, a vacuum with a speed of light $c$, to another medium with a speed of light $c_m$, it is concluded that the frequency of light remains unchanged. However, this implies that, since the speed of light is equal to the product of frequency and wavelength, as expressed in the equation

$ c = \nu \lambda $

the wavelength must change as it transitions between mediums.

Therefore, if we have a wavelength of light in one medium $\lambda_m$ and in a vacuum $\lambda$, the refractive index can be defined as

$ n =\displaystyle\frac{ c }{ v }$

and can be expressed as

$n=\displaystyle\frac{c}{c_m}=\displaystyle\frac{\lambda\nu}{\lambda_m\nu}=\displaystyle\frac{\lambda}{\lambda_m}$

In other words,

$ n =\displaystyle\frac{ \lambda }{ \lambda_m }$

(ID 9776)

Examples

Rainbow

If you observe a rainbow, you'll notice that there are actually multiple rainbows, and the sequence of colors shifts: from blue to red and then from red to blue again, and so on.

(ID 1844)

The spectre

As the angle of refraction depends on the frequency or wavelength of light in glass, a prism can be used to decompose light into its different colors.

This results in what we call the spectrum of light.

(ID 6972)

The light and its colors

A rainbow shows us that the light illuminating it is broken down into multiple colors. In fact, upon careful observation, you can see that there are multiple rainbows.

This is because each water droplet acts as a tiny circular prism, allowing for multiple refractions and the creation of multiple rainbows.

(ID 1625)

Spectrum according to Newton

Newton used a prism to decompose light into its components, believing he could identify a finite number of colors:

(ID 1682)

Sir Isaac Newton

The first to comprehend the structure of light as a physical entity was Sir Isaac Newton.

Sir Isaac Newton
(1643-1727)
Through a very simple experiment, he demonstrated that white light was composed of colors. However, he believed that the number of colors was discrete, as indicated in his chart representing his observations.

(ID 6971)

The reality of things

The colors we see don't always necessarily correspond to reality. Our eyes capture light and generate electrical impulses based on the amount of blue, red, and green light we perceive. However, the intensity may not accurately represent the real proportions, leading to a perception that differs from reality:

(ID 12676)

ID:(759, 0)