Haha, thank you, and I'm not sure on the space/IR stuff - I'll have to look into it and see if I can find something there (I've been meaning to look into IR for a while now anyway, so this may be a good excuse).
Colours of corals
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Reefering1
Valuable Member
Make sure to tag me, that would be great
Will do!
OP
OP
Is not as simple as that. The UV damage the skin in that way that it create active oxygen radicals and the black colour is mostly melanin - a well known antioxidant
I´m sorry - its my normal light - not sunlight or something else. The one I have in my aquarium and the spectra is in lower right corner of the picture
And once again - I have I don't intend to decide which approach is right or wrong - I just want to show how different corals look in different light (with different wavelengths) depending on whether their color is mainly reflective or mainly created by fluorescence or a mix of these two
Sincerely Lasse
OP
OP
Green montipora
Note - in the left lower corner is a spectra of the incoming light shown, The spectra show which type of photons that are incoming to the coral
My normal light
6500 K = 0 all others on
6500 and 8000 K = 0 all white are zero - mainly blue is reflected from the edge - the main body stell green
6500K, 8000K, and red 622 nm = 0
6500K, 8000K, red 622 nm and green 530 nm = 0. This means that there is no green photons in the incoming light. If the main bodies green is caused by only reflecting colours - we should not see any green in the next picture.
But we do - this mean that all green photons we see now is created of the coral animal by it self. The coral animal is it owns light source. There is no green photons coming in, hence no is bouncing back. The green photons we see is from blue photons absorbed by the coral animal and after that emitted as a green photon. It is named biofluorescence - It is a form of luminescence. In this cases, the emitted light has a longer wavelength, and therefore a lower photon energy.
6500K, 8000K, red 622 nm, green 530 nm and blue 470 = 0 still green
6500K, 8000K, red 622 nm, green 530 nm, blue 470 and blue 455 = 0
6500K, 8000K, red 622 nm, green 530 nm, blue 470, blue 455 and blue 450 = 0
This serie shows that even in only 425 nm light - the coral is mostly green. This green is a true biofluorescence colour. Now is the question if there is ant reflecting green colours involved. The picture below with only incoming green photons that this is the case. a dark green colour is reflecting
Is there more reflecting colours in this coral - let us see how it looks like in RGB light. yes there is - giving another greenish look.
7500 K white - some more yellow in the picture. The blue peak seems no be so strong that fluorescence is the dominate colour factor
What´s happen if we mix 425 nm blue with 7500 K white. Now its clear that green photons from fluorescence from blue photons dominate the green look from this coral
Other tests I have done shows that mainly 455 (royal blue) and 425 nm seems to be the most important in this green fluorescence
Sincerely Lasse
Note - in the left lower corner is a spectra of the incoming light shown, The spectra show which type of photons that are incoming to the coral
My normal light
6500 K = 0 all others on
6500 and 8000 K = 0 all white are zero - mainly blue is reflected from the edge - the main body stell green
6500K, 8000K, and red 622 nm = 0
6500K, 8000K, red 622 nm and green 530 nm = 0. This means that there is no green photons in the incoming light. If the main bodies green is caused by only reflecting colours - we should not see any green in the next picture.
But we do - this mean that all green photons we see now is created of the coral animal by it self. The coral animal is it owns light source. There is no green photons coming in, hence no is bouncing back. The green photons we see is from blue photons absorbed by the coral animal and after that emitted as a green photon. It is named biofluorescence - It is a form of luminescence. In this cases, the emitted light has a longer wavelength, and therefore a lower photon energy.
6500K, 8000K, red 622 nm, green 530 nm and blue 470 = 0 still green
6500K, 8000K, red 622 nm, green 530 nm, blue 470 and blue 455 = 0
6500K, 8000K, red 622 nm, green 530 nm, blue 470, blue 455 and blue 450 = 0
This serie shows that even in only 425 nm light - the coral is mostly green. This green is a true biofluorescence colour. Now is the question if there is ant reflecting green colours involved. The picture below with only incoming green photons that this is the case. a dark green colour is reflecting
Is there more reflecting colours in this coral - let us see how it looks like in RGB light. yes there is - giving another greenish look.
7500 K white - some more yellow in the picture. The blue peak seems no be so strong that fluorescence is the dominate colour factor
What´s happen if we mix 425 nm blue with 7500 K white. Now its clear that green photons from fluorescence from blue photons dominate the green look from this coral
Other tests I have done shows that mainly 455 (royal blue) and 425 nm seems to be the most important in this green fluorescence
Sincerely Lasse
Bpb
2500 Club Member
I’ll begin by stating I understand the point of the original post. Simply to show different visual effects of different spectra. Nothing more. I don’t believe @Lasse was trying to be persuasive in any way with the write up, so this is not a knock on him or the original subject. I’m more touching on the idea of what is “best” for corals in general, as it has been brought up a bit in the comments.
“best” is largely hypothetical. Because the specific amount of every individual usable wavelength, in an intensity and duration which leads to zero free radical production, zero photoinhibition, and sits perfectly at saturation will be constantly fluctuating from species to species, and even specimen to specimen based on what they’re acclimated to. There is no “best”. And any assumption as such is just that, an assumption, as we don’t presently have any conveniently available metric for quantitative measure on what optimal health actually is. Just preference. Lots of generalizations but none are actually discretely definable
“best” is largely hypothetical. Because the specific amount of every individual usable wavelength, in an intensity and duration which leads to zero free radical production, zero photoinhibition, and sits perfectly at saturation will be constantly fluctuating from species to species, and even specimen to specimen based on what they’re acclimated to. There is no “best”. And any assumption as such is just that, an assumption, as we don’t presently have any conveniently available metric for quantitative measure on what optimal health actually is. Just preference. Lots of generalizations but none are actually discretely definable
OP
OP
Exactly - its a simple way to show the differences between reflection and fluorescence colours of corals and why you need a full spectra if you want all colours to be seen but not exclusive "white LEDs"
Sincerely Lasse
A. grandis
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I'm sorry, but I just want to add something here...
I know this is not the focus of this thread, but I'll leave it here as others did...
If you have no basis for comparison everything is subjective!
If you compare to nature, for example, you have a point and that becomes your goal.
If you are keeping corals just because at the store you saw them under the blue LEDs, you have another goal.
Etc...
The personal preferences will dictate what you want to "reproduce".
That is also true to all related, like for example, keeping a shelf full of frags instead of letting them to grow into colonies, for example.
To one, those blue LEDs over the corals, like in the store, is the the deal! That's what they thought him!
To another, a full spectrum form metal halides, or even "white" LEDs, to resemble what's in nature as much possible, is the real deal.
Everyone will have different "opinions" and do what they want.
Is the coral under blue LEDs healthier than the one under full spectrum metal halides? Why? There will also be different answers there!
BUT... the foundation of this hobby, as we see in books... thought us that the reproduction of what nature offers is what we should follow for the best, to keep the corals healthy in captivity. It is a vision towards biology. The values are changing as mere "personal opinions" today, as the corals would be plastic toys. Still... if you ask any normal person, out of the hobby, they will most likely tell you that we should reproduce what's in nature to offer the best!
Political weird ideas have been polluting our lives and horrible things have been happening because of changes that should be left alone, like this and many other aspects in the reef aquarium hobby.
In the end of the story, your jaw will drop in front a mature system under halides and that blue LED tank full of struggling frags will be ignored after that!
So... it's not that relative in the end! Just ask your grandma!
I know this is not the focus of this thread, but I'll leave it here as others did...
If you have no basis for comparison everything is subjective!
If you compare to nature, for example, you have a point and that becomes your goal.
If you are keeping corals just because at the store you saw them under the blue LEDs, you have another goal.
Etc...
The personal preferences will dictate what you want to "reproduce".
That is also true to all related, like for example, keeping a shelf full of frags instead of letting them to grow into colonies, for example.
To one, those blue LEDs over the corals, like in the store, is the the deal! That's what they thought him!
To another, a full spectrum form metal halides, or even "white" LEDs, to resemble what's in nature as much possible, is the real deal.
Everyone will have different "opinions" and do what they want.
Is the coral under blue LEDs healthier than the one under full spectrum metal halides? Why? There will also be different answers there!
BUT... the foundation of this hobby, as we see in books... thought us that the reproduction of what nature offers is what we should follow for the best, to keep the corals healthy in captivity. It is a vision towards biology. The values are changing as mere "personal opinions" today, as the corals would be plastic toys. Still... if you ask any normal person, out of the hobby, they will most likely tell you that we should reproduce what's in nature to offer the best!
Political weird ideas have been polluting our lives and horrible things have been happening because of changes that should be left alone, like this and many other aspects in the reef aquarium hobby.
In the end of the story, your jaw will drop in front a mature system under halides and that blue LED tank full of struggling frags will be ignored after that!
So... it's not that relative in the end! Just ask your grandma!
A. grandis
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"Personal bias" is a good example of a term invented to justify against what I just posted and avoid reasoning.
You will never hear that when you talk to a biologist or a scientist about what is the best light to keep corals in captivity!
This hobby has regressed big time!
areefer01
2500 Club Member
We all have bias. I do agree. The OP as he noted above was only to show the differences. Not get into any debate as it relates to what is better or best. You, nor I, should care what is generating the light unless we are paying a stipend for it.
Hobby regression - it has changed no doubt but then again so has the world around us. Maybe we are both old men (figure of speech) yelling at the clouds.
A. grandis
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I can expose my thoughts just like others did, though.
I like the fact that my thoughts called your attention to the subject.
OP
OP
Third coral a mushroom species that show up to have both reflection and fluorescence colours
My normal light (By the way no Halides only full spectra LED)
6500 K = 0 all others on - not big difference
6500 and 8000 K = 0 all "white" are zero. Some reflection wavelengths is missing
6500K, 8000K, and red 622 nm = 0 Something happening when red photons disappear - green colours fade away. As you can see in the underlying coral - green photons is still in the incoming light
6500K, 8000K, red 622 nm and green 530 nm = 0. Suddenly . near green showing up - and no incoming green photons
6500K, 8000K, red 622 nm, green 530 nm and blue 470 = 0
6500K, 8000K, red 622 nm, green 530 nm, blue 470 and blue 455 = 0
6500K, 8000K, red 622 nm, green 530 nm, blue 470, blue 455 and blue 450 = 0
RGB only
7750 K
In this coral - it is clearly a mix between reflecting and fluorescent colours
Sincerely Lasse
My normal light (By the way no Halides only full spectra LED)
6500 K = 0 all others on - not big difference
6500 and 8000 K = 0 all "white" are zero. Some reflection wavelengths is missing
6500K, 8000K, and red 622 nm = 0 Something happening when red photons disappear - green colours fade away. As you can see in the underlying coral - green photons is still in the incoming light
6500K, 8000K, red 622 nm and green 530 nm = 0. Suddenly . near green showing up - and no incoming green photons
6500K, 8000K, red 622 nm, green 530 nm and blue 470 = 0
6500K, 8000K, red 622 nm, green 530 nm, blue 470 and blue 455 = 0
6500K, 8000K, red 622 nm, green 530 nm, blue 470, blue 455 and blue 450 = 0
RGB only
7750 K
In this coral - it is clearly a mix between reflecting and fluorescent colours
Sincerely Lasse
OP
OP
A. grandis
2500 Club Member
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LOL! Why lucky?Lucky me that I do not have halides then
Sincerely Lasse
OP
OP
Because if halides is so good as you say - my growing corals had blown up the aquarium
It was a joke
Sincerely Lasse
A. grandis
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LOL! Your tank is lovely!
@Reefering1 - Did a bit of reading today (some of the references are at the bottom, a few pertinent ones are scattered throughout).
For IR and space:
Infrared gives the prettiest pictures of deep space because the long wavelengths of infrared light allows the infrared light to avoid bumping into dust and gases in space; so where visible light would run into dust/gas (making it so that all we would see is a dust cloud), infrared penetrates through and shows us what's on the other side (the first link explains it fairly simply, the second has some more info and some cool examples to demonstrate the difference between visible and IR pics of space):
Infrared Waves - NASA Science
What are Infrared Waves? Infrared waves, or infrared light, are part of the electromagnetic spectrum. People encounter Infrared waves every day; the human eye cannot see it, but humans can detect it as heat. A remote control uses light waves just beyond the visible spectrum of light—infrared...
science.nasa.gov
Wavelengths - NASA Science
Visible Light Because our atmosphere blocks or partially absorbs certain wavelengths, Hubble’s position 320 miles above Earth’s surface puts it in a location where it can capture details of objects that would be difficult or impossible for ground-based telescopes to observe. Hubble has also...
science.nasa.gov
With the ocean life and IR, there doesn't seem to be much research there, but this is what I've found:
-Near-IR (700-1400 nm) can only penetrate a few meters into water; mid- and far-IR (1400-10000 nm) seem to only penetrate less than 1 mm of water. Water seems to absorb IR very quickly; organics in the water absorb it even faster; generally speaking, higher salinity seems to cause it to be absorbed faster as well.
Light in the Ocean | manoa.hawaii.edu/ExploringOurFluidEarth
manoa.hawaii.edu
Freshwater fish, amphibians supercharge their ability to see infrared light - The Source - Washington University in St. Louis
Salmon and other freshwater fish and amphibians supercharge their ability to see red and infrared light. Scientists at the School of Medicine have shown that this evolutionary adaptation hinges on the activity of an enzyme that converts vitamin A1 to vitamin A2, enabling the aquatic creatures to...
source.wustl.edu
The engine of the reef: photobiology of the coral–algal symbiosis
Coral reef ecosystems thrive in tropical oligotrophic oceans because of the relationship between corals and endosymbiotic dinoflagellate algae called Symbiodinium. Symbiodinium convert sunlight and carbon dioxide into organic carbon and oxygen to fuel ...
www.ncbi.nlm.nih.gov
Lateral light transfer ensures efficient resource distribution in symbiont-bearing corals
Coral tissue optics has received very little attention in the past, although the interaction between tissue and light is central to our basic understanding of coral physiology. Here we used fibre-optic and electrochemical microsensors along with variable chlorophyll fluorescence imaging to...
journals.biologists.com
Reefering1
Valuable Member
You're the man!! Thank you, I'll read the links and possibly follow up with some questions..@Reefering1 - Did a bit of reading today (some of the references are at the bottom, a few pertinent ones are scattered throughout).
For IR and space:
Infrared gives the prettiest pictures of deep space because the long wavelengths of infrared light allows the infrared light to avoid bumping into dust and gases in space; so where visible light would run into dust/gas (making it so that all we would see is a dust cloud), infrared penetrates through and shows us what's on the other side (the first link explains it fairly simply, the second has some more info and some cool examples to demonstrate the difference between visible and IR pics of space):
Infrared Waves - NASA Science
What are Infrared Waves? Infrared waves, or infrared light, are part of the electromagnetic spectrum. People encounter Infrared waves every day; the human eye cannot see it, but humans can detect it as heat. A remote control uses light waves just beyond the visible spectrum of light—infrared...The European Space Agency also has some info it, but it's not as detailed as NASA's info above.Wavelengths - NASA Science
Visible Light Because our atmosphere blocks or partially absorbs certain wavelengths, Hubble’s position 320 miles above Earth’s surface puts it in a location where it can capture details of objects that would be difficult or impossible for ground-based telescopes to observe. Hubble has also...
With the ocean life and IR, there doesn't seem to be much research there, but this is what I've found:
-Near-IR (700-1400 nm) can only penetrate a few meters into water; mid- and far-IR (1400-10000 nm) seem to only penetrate less than 1 mm of water. Water seems to absorb IR very quickly; organics in the water absorb it even faster; generally speaking, higher salinity seems to cause it to be absorbed faster as well.
-Some fish (like salmon) and inverts (like mantis shrimp) can see infrared.Light in the Ocean | manoa.hawaii.edu/ExploringOurFluidEarth
-The only research I can really find on IR and corals is about the coral tissue/tissue thickness and IR; these studies indicate that corals seem to basically ignore IR/IR seems to basically ignore corals; 400-700 nm light intensity decreases in coral tissue (being reflected, bounced around/redirected internally, etc.) while IR light (700-800 nm were tested in the two studies I could find) stays basically unchanged (it basically just passes through unimpeded).Freshwater fish, amphibians supercharge their ability to see infrared light - The Source - Washington University in St. Louis
Salmon and other freshwater fish and amphibians supercharge their ability to see red and infrared light. Scientists at the School of Medicine have shown that this evolutionary adaptation hinges on the activity of an enzyme that converts vitamin A1 to vitamin A2, enabling the aquatic creatures to...
The engine of the reef: photobiology of the coral–algal symbiosis
Coral reef ecosystems thrive in tropical oligotrophic oceans because of the relationship between corals and endosymbiotic dinoflagellate algae called Symbiodinium. Symbiodinium convert sunlight and carbon dioxide into organic carbon and oxygen to fuel ...I wouldn't be surprised to find IR has some sort of biological impact on corals, but it doesn't seem any impact has been researched at this point that I can find.Lateral light transfer ensures efficient resource distribution in symbiont-bearing corals
Coral tissue optics has received very little attention in the past, although the interaction between tissue and light is central to our basic understanding of coral physiology. Here we used fibre-optic and electrochemical microsensors along with variable chlorophyll fluorescence imaging to...
OP
OP
About far red (700 - 760 nm) se this thread
https://www.reef2reef.com/threads/advanced-topic-thoughts-on-emerson-effect.369404/
Further on see this page
www.reef2reef.com
Sincerely Lasse
https://www.reef2reef.com/threads/advanced-topic-thoughts-on-emerson-effect.369404/
Further on see this page
Search results for query: emerson effect
www.reef2reef.com
Sincerely Lasse
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