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ZHIHZ said:Is this diffraction??Help..sorry if I've posted in the wrong place.
I have not taken the best pic from the video but please take a look at this short video and tell me what you think.davenn said:just looks like some very blurry -- out of focus, so probably not
ZHIHZ said:I have not taken the best pic from the video but please take a look at this short video and tell me what you think.
Ok.thank you for taking a look anyways.i will keep trying to capture what i can see with my eyes.looks like something to me but the only thing i can find online that looks anything like it are diffraction patterns.davenn said:I still go with my earlier comments ... unfortunately, it's just a meaningless out of focus blur
Dave
If you tell us what it is that you are looking at, it would help. When do you reckon you are 'seeing' a diffraction pattern?ZHIHZ said:Ok.thank you for taking a look anyways.i will keep trying to capture what i can see with my eyes.looks like something to me but the only thing i can find online that looks anything like it are diffraction patterns.
I will try to exsplane best i can later when I've put the kids in bed.i know you can't get diffraction from a notmal light source that's why I am asking you guys to help me figure out what it is.the light source is a normal street lamp and the video is of the light bouncing off a bio liquid.imagine the tiny shimmer you get from a diamond that tiny point of light reflecting.thats what I am trying to focus on.that tiny dot of reflected light at a certain Angeles allows me to see structurs that are like looking at the surface of an alien planet.ive looked all over the web to exsplane it but found nothing..i will upload the full video later to see if that help anyone tell me what it is.thankssophiecentaur said:If you tell us what it is that you are looking at, it would help. When do you reckon you are 'seeing' a diffraction pattern?
I could point out that you cannot get a diffraction pattern with an individual photon and that you need an awful lot of photons to build up a diffraction. But all may be solved if you describe what you have been doing.
What kind of streetlamp? What color is it?ZHIHZ said:i know you can't get diffraction from a notmal light source that's why I am asking you guys to help me figure out what it is.the light source is a normal streed lamp
If the diffraction was from poor focus of the camera then i would not be able to see it with my eyes would i?Khashishi said:No, the blurring you see is not diffraction. There's always some diffraction that contributes to the blur, but in this case, most of the blur seems to come from poor focus.
You are awesome.Thank you so much.i found this picture that is exactly the same as the rectangular patterns i am seeing.https://i.imgur.com/2NyUPtt.jpgsophiecentaur said:To be pedantic about this question, I could say that, as diffraction accounts for the formation of any image when you treat the light as waves, everything you see is 'diffraction'. The occasions when there is an identifiable fringe structure will be when there is a limited aperture or where there are multiple path lengths for the waves to get to a destination. The above images and videos are probably due to diffraction due to some small scattering structure in the light path. A great example of this is the diffraction pattern caused by the supports in a Newtonian telescope. You will notice that those spikes are not noticeably 'coloured'. The images in this link seem to be copyright protected so i couldn't post an image but they show what I mean, very well. They do not occur all over the picture - often just where the object is a lot brighter than the surroundings. They can occur without the original object actually turning up in the picture and that's what I think is happening in the above images. There must be a bright source well off axis.
Other examples are what you see when bright lights pass through a wet windscreen when the wipers have gone over a slightly greasy patch and the effect that 'effects filters' (star burst) on cameras will show. There is sometimes a bit of chromatic spread but nothing like as strong as the basic 'white' pattern.
P.S. The main peak in these particular patterns is in the same direction for all wavelengths and the width is small - hence the white appearance.
Nice image. Of course, it is in monochrome but I suggest that you would actually a slightly 'coloured' outline in the original.ZHIHZ said:the rectangular patterns i am seeing.https://i.imgur.com/2NyUPtt.jpg
Diffraction is a phenomenon in which waves spread out as they pass through an opening or around an obstacle. It is a fundamental property of all types of waves, including sound waves, light waves, and water waves.
Diffraction occurs when a wave encounters an obstacle or passes through an opening that is comparable in size to its wavelength. The wave will bend and spread out as it passes through the opening or around the obstacle, creating a pattern of alternating light and dark areas.
Diffraction and refraction are both ways in which waves interact with obstacles or boundaries, but they are different phenomena. Diffraction occurs when waves bend and spread out as they pass through an opening or around an obstacle, while refraction is the bending of waves as they pass through a medium with varying density.
Diffraction is a useful tool in many scientific fields, including physics, chemistry, and biology. It can be used to study the properties of waves and the structure of materials. Diffraction patterns are also used in techniques such as X-ray crystallography to determine the structure of molecules.
Yes, diffraction can occur with all types of waves, including sound waves, light waves, and water waves. However, the amount of diffraction that occurs depends on the wavelength of the wave and the size of the obstacle or opening it encounters. For example, sound waves with longer wavelengths will diffract more than light waves with shorter wavelengths.