Thin films (e.g. soap bubbles,oil on water) often display brilliant coloration when reflecting white light and show fringes when in monochromatic light.
a
A thin film is a transparent medium whose thickness is comparable with the wavelength of light. Brilliant and beautiful colors in soap bubbles and oil film on the surface of water are due to interference of light reflected from the two surfaces of the film as explained below:
Consider a thin film of a reflecting medium. A beam AB of monochromatic light of wavelength λ is is incident on its upper surface. It is partly reflected along BC and partly refracted into the medium along BD. At D it is again partly reflected inside the medium along DE and then at E refracted along EF as shown in the figure given below:
 |
| Fig . Geometrical construction of interference of light due to a thin oil film |
The beams BC and EF, being the parts of the same beam have a phase coherence. As the film is thin, so the separation between the beam BC and EF will be very small, and they will superpose and the result of their interference will be detected by the eye. It can be seen in the above figure, that the original beam splits into two parts at the point B and they inter the eye after covering different lengths of paths. Their path difference depends upon (i) thickness and nature of the film (ii) angle of incidence. If the two reflected waves reinforce each other, then the film as seen with help of a parallel beam of monochromatic light will look bright however, if the thickness of the film and angle of incidence are such that the two reflected waves cancel each other, the film will look dark.
If white light is incident on a film of irregular thickness at all possible angles, we should consider the interference pattern due to each spectral color separately. It is quite possible that at a certain place on the film, its thickness and the angle of incidence of light are such that the condition of destructive interference of one color is being satisfied. Hence, that portion of the film will exhibit the remaining constituent colors of the white light as shown in the above figure.
If white light is incident on a film of irregular thickness at all possible angles, we should consider the interference pattern due to each spectral color separately. It is quite possible that at a certain place on the film, its thickness and the angle of incidence of light are such that the condition of destructive interference of one color is being satisfied. Hence, that portion of the film will exhibit the remaining constituent colors of the white light as shown in the above figure.
From the above figure incident light first reflects from upper surface gives Part I (pink ray) and also refracts into the film which again reflects from the bottom surface and comes to the eye as Part II (violet ray).
Part I of light has phase change of 180° as it is reflected from a surface beyond which there is medium of higher refractive index. But Part II of light has no phase change as it is reflected from a surface beyond which there is a medium of lower index. Therefore the condition for constructive and destructive interference are reversed then the Young's double slit experiment. For nearly normal incidence the path difference between the two interfering rays is twice the thickness of the film i.e equal to 2t where t is the thickness of the film. If n is the refractive index of medium of the film then,
Hence condition for the maxima or constructive interference is,
m = 0,1,2,....
similarly condition for the minima or destructive interference is,
m = 0,1,2,....
In case of varying thickness of film, there will be a pattern of alternate dark and bright fringes.
Part I of light has phase change of 180° as it is reflected from a surface beyond which there is medium of higher refractive index. But Part II of light has no phase change as it is reflected from a surface beyond which there is a medium of lower index. Therefore the condition for constructive and destructive interference are reversed then the Young's double slit experiment. For nearly normal incidence the path difference between the two interfering rays is twice the thickness of the film i.e equal to 2t where t is the thickness of the film. If n is the refractive index of medium of the film then,
Path difference = 2tn
Hence condition for the maxima or constructive interference is,
m = 0,1,2,.... similarly condition for the minima or destructive interference is,
m = 0,1,2,....In case of varying thickness of film, there will be a pattern of alternate dark and bright fringes.
 |
| Fig . Interference pattern produced by thin soap bubbles |
sample Cups and Thin-Film Sample Support Windows are the basic necessities for containing and analyzing samples by XRF spectroscopy. Superficially, the procedure appears r
ReplyDeleteThinFilm
I think you are an great writer because as you have describe about interference in thin film that is great information for everyone.
ReplyDeletefused silica substrate
What a fantastic blog post you have shared, nice information sharing in this article.
ReplyDeleteglass dicing service
Great
ReplyDeleteFinally, I got what I was looking for. Don’t have enough words to thank you that you choose this particular topic to write about. Feeling really satisfied after reading
ReplyDeletesubstrate dicing
It was necessary for someone to write on this topic and you grabbed the heart of millions by taking the initiative which is enough to bring the evolution. Thanks for bringing it in light.
ReplyDeleteoptical polishing services
This comment has been removed by the author.
ReplyDeleteInteresting information!
ReplyDeleteFor film thickness measurement, you could use Elcometer 500
I am glad that you simply shared this useful information with us.
ReplyDeletethin stainless steel
What is phase difference basically? And path difference here
ReplyDeleteA thin film is a layer of material ranging from fractions of a nanometer (monolayer) to several micrometers in thickness. The controlled synthesis of materials such as thin films (a process referred to as deposition) is a fundamental step in many applications [1]. A familiar example is the household mirror, Thin Films testing
ReplyDeleteIf the light falls normally on thin film then in such case, is path difference depend upon angle??
ReplyDeleteIf the light falls normally on thin film then in such case, is path difference depend upon angle??
ReplyDeleteIf the light falls normally on thin film then in such case, is path difference depend upon angle??
ReplyDeleteYou are writing is always fabulous. This is third time I’ve read your blog and I find the information very useful.
ReplyDeleteCustom optical coatings
THANKS FOR SHARING SUCH A AMAZING WORK
ReplyDeleteNICE WORK
Interference Analysis INDIA
It is an inspiring blog post. The issue handles very nicely. I really appreciate the communication skill of yours and definitely come soon by the time you will complete another write-up.
ReplyDeletecolor glass filters
The title of your write-up is very eye catchy which holds an individual to read till the very end of your blog. Every new paragraph increases the interest of a reader.
ReplyDeleteglass dicing service
https://www.sciencelaws.in/2020/01/Youngs-double-slit-experiment-derivation.html
ReplyDeleteGreat read guys! Thank you for sharing! Anyway anyone from Singapore here? Interested in property investment? I saw a few property launches that has got huge potential. Anyway keen to know more? Click on the link below!
ReplyDeletedaintree
daintree residence
daintree residence balance units
whistler grand
whistler grand condo
whistler grand balance units
jadecape
jadescape condo
jadescape balance units
The title of your write-up is very eye catching, which holds an individual to read till the very end of your blog. Every new paragraph increases the interest of a reader.
ReplyDeletesoda lime glass wafers
I admire your unique way of writing especially the style of using the idioms and phrases which is mind-blowing. I hope you will not mind if I adopt this style of your. Many thanks.
ReplyDeletesoda lime glass wafers