So true, I was just thinking about passive/evaporative cooling used traditionally in the middle east, technology might allow to go "back" to better solution then current AC systems
@@cecilia00960 passive evaporative cooling is very neat and efficient, but it requires a low humidity environment (among other trade-offs) which is why it works so well in deserts, and is basically useless in humid heat. It's a good example of how most problems don't have a universal silver bullet solution, but it's still worthwhile to have a buffet of good options that excel under different conditions.
This is amazing! I'm writing a sci-fi book about how people adapt over a 200 year period and I am going to research this branch of materials science to use in the book. Thank you for getting the word out!
I wrote a book about space based mirrors that are used to cool the planet, how they preform as a heat engine that shunts heat back into space, but one could also run the engine in reverse and cook your enemy with a death ray. You know, that old chestnut.
The only information I have is what was available in the papers unfortunately. And what was talked about with Arny. As for the aerogel coating it's biggest constraint is that it's not the most durable material against the elements. In it's current state it's not an ideal candidate for large scale use, however the current best use is for coolers or containers that you want to keep the contents cool. Keep food cooler longer and it can be sheltered from harsh elements. The silk paper showed that after extensive manipulation, twisting, and stretching, the nanoprocessed silk maintained the bonds between it's fibers and the aluminum nanoparticles. So unless there's a health issue to having aluminum near your skin that I don't know of I think that one is very much a viable option. The metafabric paper claims it's a scalable process and as seen in some photos, they were certainly able to make large reams of cloth. I don't know how scarce titanium is, so that may be a limiting ingredient. That paper also (That I can recall) didn't go into depth on durability. There was another fabric paper I didn't talk about that made a polyethylene fabric which was extremely scalable. So I think there are certainly options. My main concern is the reliance on continued use of plastics.
@@ButWhySci RE: metafabric titanium scarcity: titanium isnt very scarce but it is quite expensive- about $4 per kilo vs steel at about $1.25. It'd be interesting to put forward to a chemical engineer, if its really that scalable, they should have no issue setting up a production facility.
NASA has been using something similar to this for decades on their spacesuits and spacecraft. Their white paints reflect visible light, near-IR and near-UV - I.E. most of the Sun's radiation - because they're... you know... WHITE. However, the same paints have a high thermal emittance - something usually not found in reflective materials - because in the mid and low infrared spectrum they actually look black. The result is that anything coated in these paints will radiate away heat but not gain any from the sunlight.
@@Gliccit Titanium oxide is actually very inexpensive and readily available. In fact almost all white pigments used in almost all paints are derived from titanium oxide.
There's some info about passive cooling in architecture if you search for it. In the past, this was the only option once there was no electricity The book "barefoot architect" demonstrates some techniques to achieve the passive cooling in buildings It's not exactly what's shown in the video but you can have some ideias about passive cooling
Found this video after seeing NightHawkInLight's recent video on DIY versions of the IR emitting/reflecting paints! Very nifty! I'm glad to see this research continuing and spreading.
Since asbestos, I am always wary about the use of strange new materials in the form of fabric, where it may break away and form airborne fibers that might be toxic, or pollutants of some kind, that nobody expected. Keep it in a solid block so it won't disperse as easily, please. I can see some lightweight shindles that can form a tent-like structure, too.
@@GeeTrieste I would say its Blender, just from personal experience it does look like Blender UI with a geometry node viewer in the bottom panel. As you can see he's got his terrain set up in the top panel. On the right there's a list of all his assets in the scene, those little orange boxes in the top right.
@@gauthierruberti8065 I spent the last year with my free time getting a better understanding of materials and while geometry nodes were growing in popularity and tutorials I sat back and ignored it. Now I'm getting into, but oh so late, lol. Better late than never?
@@firemyst9064 better now than before! Now you have access to many more nodes and an enormous amount of tutorials. Now will probably be less stressful to look for specific stuff
The narration, the animation, the sentence structure, the clarifications, the pacing. I couldn't find a single issue in this whole video and the way you avoided popular misconceptualizing definitions gave me the hope back that properly sharing information is still possible in this world where they rather converge to large audiences with common slurs. Thank you thank you thank you!
First correction: most polymers absorb infrared at many frequencies and are not infrared windows. A few polymers with very simple structures such as polyethylene (PE) absorb in only a few relatively narrow bands and are good infrared windows at other frequencies. However, the width of an absorption band also depends on the homogeneity (uniformity) of the local chemical environment. Some grades of PE have polymer chains aligned in the same direction (quasi crystals) and hence are good infrared windows. In PTFE (teflon) the polymer chains have less long range order with two consequences (1) wider absorption bands and (2) more scattering from refractive index inhomogeneity. If the size of the inhomogeneity is comparable to wavelength, the scattering is described by the Mei theory (this is why teflon is translucent rather than transparent). A second correction is that molecular absorption and emission is highly orientation dependent. The isotropic emission shown in this video only applies because the molecules are randomly oriented and emission is averaged over the random orientations. The spectral characteristics change when molecules are oriented by a surface or manipulated by electromagnetic fields. These properties become very interesting in the context of medical diagnostics (one of the topics in my lab). Its also worth mentioning that another field of research is dielectric (super) mirrors with reflectivity above 99%. The problem is making super mirrors cheap enough for widespread commercial applications (another topic in my lab currently at pilot scale manufacturing stage).
I know of a channel called "NightHawkInLight" that has some videos explaining how to make a passive radiative cooling material from household items. The recipe gets better in more recent videos as he finds other methods to produce higher quality materials.
Ray tracing does make the fever dream nature of these animations even more fever dreamy, which I believe is a good thing and looks cool. Can't help but wonder how much it increases the rendering or processing time though, it couldn't be good...
The biggest thing is that it drastically increases disk space usage since you have to render everything out to individual files/frames. Normally I render out to MP4. But yes it also takes much longer. Not too big an issue because I just have it render remotely while I'm working on another scene. Something weird happened though with exporting from EXR, my photons and sun got very yellow. It looked normal in the video editing software but after export some lights got yellower.
@@ButWhySci I recommend importing it into something like Da Vinci Resolve and messing with the sliders: When seeings the EXR all at the same time, you're seeing all the information at the same time (a lot more than mp4). You might want to use Da Vinci to dial down settings (contrast is the one you want probably) and make it look like blender shows
This actually feels pretty reasonable. If you can make a material that lets through infrared but reflects (instead of absorbing) light / radiation / photons at higher frequencies, it will effectively be an exceptionally efficient sun shade. Now the problem is, as always, how do you mass produce this, and can you do it economically and ideally cleanly?
I'm wondering how it would be implemented in big buildings and areas of extreme distress (with earthquakes and hurricanes and such) and if that implementation would require complete rebuilding to be effective.
@@raffimolero64 Over the years, huh? If only we'd started 40 years ago... Not sure how many years of ramp-up time we can afford for stuff like this before it becomes less about managing energy and more about how to make better stillsuits.
@@adnan7698 its just bad luck, he will explode sooner or later, he just needs the timing to be perfect and juuust the right title for youtube algorythm and boom
@@sMASHsoundTrees do just that. And they are larger surface than our buildings on earth . And yet global warming is still here . Perhaps global warming is not something new to the planet and the planet has been heating up for thousands of years. We know that the desert and Egypt were much greener a few thousand years ago. that there was an ice age. So why do we make this global warming event something new? Just so that a few people as usual take advantage to milk others for money, just for profit? Was the market overcrowded, and did some think of putting another fear into play that could be used to milk people?
You are my favourite science channel. You don’t dumb down the concepts but you do explain then in a way most people can understand.You don’t pad the videos for time unnecessarily meaning you respect your audience. You dive deep into the actual processes of what’s happening at the atomic level making things actually make sense. Just everything about your videos makes me and all my science friends geek out and that is just so cool. Thank you for everything you do, never change please you are my hero.
your visuals are out of this world, I wish you could collaborate with schools or institutes. more students need to see your clear, simple, very will throughout explanation videos.
RE: “hopefully what I find will inspire one of you to start your own research…” I paused the video three times before I got to the end to begin my own research already! Mission accomplished, and great video, mate. I’d love to get my hands on those papers.
Oh, HOW I thank my parents/ancestors to be alive here at this moment (and as a non-native English) to have learned how to read/write and study Physics at school and then study English at another school and then understand SOME of this video's knowledge to apply on my day-a-day life. Thank you, content creator.
As someone who has a voracious appetite for science and technology breakthroughs, it is hard to find content that is presented well enough for me to understand as a layman to new subjects, while also being in-depth and informative enough to actually teach me things I didn't know before and inspire me to learn more. I feel like you really nailed this sweet spot for me in this video. Liked and subscribed!
I am an architect . Great video btw. The only practical problem with this is that a building needs to hold onto heat in winter also. So a fancy inverted greenhouse would be great for hot summers but terrible for cold winters.
it won't be the perfect solution for every environment. but you could easily cover the material in winter or if it is a frabric just remove it entirely in winter.
Only run the HVAC through the dissipater during the winter. You don’t run the A/C during the winter. Sure it won’t have the impact in temperate climates it will in equatorial ones, but it doesn’t need to work as well there either.
But this would work for infrastructure which is close to the equator, since that these places don’t have cold winters. Heat is problem almost all year round and therefore would be a great idea to implement. Just because it may not work for your situation does not mean it won’t work everywhere.
Also .. the more humans /animals confined in the same space will negate the benefit. The better and trusted solution is Thermal mass ( Under ground systems) See Cooper Peddy, SA Australia for houses made underground. The glorious version is Bilbo Baggins house - thermal mass
@@bluedark7724It actually wouldn't negate the benefit, because these materials are specifically designed to be transparent to heat. They don't trap the heat to let it build up, so more bodies in the building wouldn't significantly increase the overall temperature
Absolutely loved this video. As a scientist it's awesome to find channels such as yours. As a curious millenium teenager I was sometimes frustrated for not having enough knowledge or having where to search for it. I'm thrilled today there are content producers like you. Thanks!!!
This only strengthens my belief that materials science is by and far the most wild of the practical sciences. There is SO much that this field effects that we pay little mind to or take for granted.
Well done content will defend itself. Your channel will blow sooned than later. And I can't stress enough, how your calmly tone, makes it easier to absorb the facts. While other science channels pump up their videos to make them more entertaining, yours dominate them when someone wants to learn. Not in vain there are multiple comments about teachers that should use your vids in schools.
Cool video. I read about a paint utilizing a similar effect a while back. A question re: Your description of the greenhouse effect. My understanding is that the atmospheric density at sea-level causes an excited molecule: CO2, water, methane, etc. to transfer its energy to neighboring molecules via collisions (conduction). Collisions happen so fast that most excited molecules don't have time to revert to their ground state before hitting other molecules. This increases the average kinetic energy, increasing the probability some molecules get enough energy to radiate in the infrared. The resulting warmer, moister air rises until the water vapor precipitates out, radiating the latent heat (again infrared). Above the tropopause we still have CO2, methane, greenhouse gasses that don't precipitate out on Earth. Once the atmosphere gets thin enough then the emissions lines thin out and we need to consider that emissions go in random directions. Often back towards the Earth. I would appreciate your feedback. Thanks in Advance.
Thanks for letting the video running in the directions your research took you. It helps keep the material holistic and inclusive. In a larger context rather than caught narrowly in a single context.
Your level of thoroughness in describing underlying theory as well as applying it to both everyday occurrences and bleeding-edge research is amazing! Just found this channel and you got a new sub!
Convection! Love the science and part of science is feedback... Greenhouse maintain their temperature primarily by preventing convection from letting warm air rise. Open all the vents in a greenhouse and it's temperature will be barely warmer than the surounding air.
Amazing new discovery! Thank you for this info! The underside of certain types of elytra (aka beetle wings) is also covered with numerous nano sized structures but probably not for thermal conductivity
Amazing work! Better than most of the popular "science & tech" channels out there. This is what I call high quality content. I need to rewatch the video.
NighthawkInLight covered a similar thing to this, well, kinda precisely half of it - a paint that can cool objects using the principle of optimisation for radiating the heat away into space. What is extremely interesting is that the paint can be made at home and surprisingly easily without some toxic ingredients
Amazing sir. you've got the trifecta: Great topics, great explainer voice, and intuitive info graphics. I'm always looking forward to your videos and frankly, I really wish they were longer.
Wow!! The animations are sooooooo accurate and awesome! Helps learning complex things so quickly. Thank you for the efforts and all the knowledge share.
At 11:01 I thought it would lead into an advert for Brilliant but no, you actually meant it. I loved the video and explanations thank you for creating it!
@@guimaciel7457 But if they can switch quickly, you would have the best results for cold fronts or a quick heatwave. The only reason I ever used the AC here in Texas was to get the humidity down indoors.
even if you cant change them for the cold season, it would still save a colossal amount of energy even if its only used jn zones where its hot all year round
The best substance for the inverse greenhouse effect is in fact snow. Because it is nearly perfectly white for visible light, and nearly perfectly black for infrared. To those who don't know, emissivity = absorptivity (this is required by the 2nd law of thermodynamics, otherwise a black object and white object suspended in a vacuum and surrounded by mirrors so they were in thermal contact only with each other and only through radiation, would not settle to the same temperature and you could make a perpetual motion machine type 2) so being black to infrared means it is an efficient emitter of infrared. You couldn't ask for it to be more perfect. A pity about it all going away now.
Wouldn't snow emit IR in wavelengths that water vapor in the air absorbs? I'd think you'd want to avoid those wavelengths. IR emission by water molecules in snow vs IR absorption by water molecules in the atmosphere. I guess the phase (solid vs gas) tweaks things, but I'd be surprised if the "tweak" is enough to make absorption by water vapor negligible. Maybe it's not a big issue in the dry air of the poles, but for most of the surface of the planet, there's a lot of water vapor overhead.
Snow isn't especially unique in this property. Most materials emit better in ir than visible. A sheet of white paper is also almost a blackbody in thermal IR and... well... white in visible.
This was so cool and inspiring. Thank you for making this video and doing researching and converting hard laborious scholar articles into a fun way to understand them. I greatly appreciate your efforts.
That meta fabric sounds amazing but I’d like to know if those micro beads in the fabric could contaminate the environment like micro beads have already done.
You're missing something.... convection. A garden greenhouse works primarily by blocking convection which would otherwise quickly take away the air and water vapour warmed by the upwelling IR. Another thing to consider, the atmosphere is a pressure gradient, so there isn't a 50/50 chance of re-emission going up or down, it's slightly more likely to go up. There are more particles below to absorb the IR than there are above, so while the direction of radiation is random, the distance before the next collision increases with altitude.
You left out a huge part of the explanation of the greenhouse effect (probably dishonestly because it reduces the fear porn of alarmists) When IR is emitted it is emitted across normal radiation spectrum. But CO2 only absorbs on two narrow bands. Makings its effect logarithmic. You have exponentially increase concentrations for a linear effect.
and water overwhelms those bands at about 25 times, in width, height, and saturation. Imagine one junior high freshman on the field against 25 professional football players...
@@geraldfrost4710 But the water vapor does not change that much. Too dry and more evaporation occurs. Too wet and it is precipitation. For your scenario. Imagine instead of one junior we have three. This will change the score slightly. instead of 0-100 we now have 0-97. Given the (max+min/2)temperature of the moon is -180 deg celcius. and the temperature of the earth is around 10-20, it only takes a few percentage points difference to add a couple of degrees.
Didn’t realize most of the heat from my oxyacetylene cutting torch was actually radiation. And how little heat is transferred by the actual molecule contact. It’s like, when I hold my bare hand next to a hot vehicle exhaust, the radiation heat is twice as powerful as when I physically contact that exhaust. Ok, you have taught me how global warming really happens. Thermal radiation is one way to accurately measure heat. Most of the heat on the surface of the sun is not radiating through the perfect transparency of space and heating the Earths surface to two thirds of origin.
I dont think that two thirds of the heat of your oxyacetylene torch come from radiation. That would mean, that it would be almost as hot next to your torch than it is right in front of it since it radiates in all directions randomly. However the cutting only works when the flame is directly contacting the material, so i think conduction plays a major role in this case.
@asimi900 Your right. I was being kinda snarky. They do take a known scientific fact, thermal radiation can increase heat in objects that absorb it, but blow it way out of proportion to come up with aggressive heating due to trace amounts of CO2. Maybe because satellites only measure the IR radiation to get temperature readings anymore, so it is impossible to separate the contact heat from radiation heat. There are many real scientists who don’t believe in GGGW. But the basic principle is correct.
@@glenndavis4452 Yeah, CO2 was almost never considered the main contributor in the first place since it’s so short lived. In a single human lifetime most of what’s been released can become part of a plant. CO2 has always been about power, money, and starting the conversation. The actual kickers are a whole gamut of different things, like methane, which can stick around for centuries and actually do some damage. Coincidentally about as much is getting released from the short-term problem of melting ice-caps/glaciers as all of human industry combined, which is why people were so panicky before, trying to keep those damn ice formations intact. At this point the ice is melting at such a rate that quite a lot of people have resigned themselves to the higher electricity bill and the hundred-year floods every other year. Local governments are really struggling with all the disaster relief they have to do these days, sadly.
@@thesquishedelf1301 It’s sad that they limit you guys climate disaster information to the last few decades. Only. I’m not going to even try to list the catastrophic floods, droughts, and monumental forest fires documented in newspapers from up to 150 years ago. Birds falling dead from trees because of heat. Thousands of people dying. The Peshtigo fire of the late 1800s covered a third or more of three Midwestern states. The Dust Bowl of the early 1930s had tens of thousands of refugees. Or maybe even more. Starvation otherwise from widespread drought. Sand dunes or bare earth extending up into middle Kansas. Yes they are spending big money now. Formerly hundreds or thousands died from climate events. There’s a channel on YT that documents events like that. Tony Heller. Yes natural methane releases are huge and have varied throughout geological time. It does not survive long in the upper atmosphere. Methane and CO2 also block IR from the sun, in the frigid upper atmosphere. The claimed difference would be achieved at night, when the absorb the far weaker IR from the earth, transferring whatever heat that creates to the atmosphere. But they are special in that respect only because oxygen and nitrogen don’t interact with the IR wavelength. If we have enough dust or smoke atmospherically, doing the EXACT same thing with IR radiation, we experienced mini Ice Ages, not global warming. There is just way too much actual proven science for me to believe in GGGW. IF these special molecules can heat thousands of times their mass, from the relatively low level IR of the earth surface, we could damn sure heat our homes and create green steam energy by using that “proven science”. I did used to believe it, too.
Hey, i´m a chemical engineering student, and i got to say, this channel is amazing, i love every second of it. I have thought about this topic for a while, but haven´t gotten around to studying, you have peeked my curiosity.:) I have a semester project on particle detection, and the explanation on Mie scattering was very direct and easy to understand. Keep up the good work, i will be watching:)
God is the ultimate engineer. He built the whole system in the first place and he says the weather's not going to change... Genesis 8:22 - While the earth remains, Seedtime and harvest, Cold and heat, Winter and summer, And day and night Shall not cease.
@@brianhale3678 I'm sorry, i don't think i understand, are you saying that global warming isn't a thing or that you don't belive in the tehnology. I could be misunderstanding, but what was the point of this comment?
@@andreasflensmark8616 I'm saying God knows more about the weather than all of the climatologists in the world. He gave this sentence to Noah immediately after the flood and it has held true for 4,400 years and it's going to hold true in our near future as well.
@Brian Hale Near future?? also i don't think you replied to my question, whether or not he said those things is not that important, i am asking you, do you not believe in the technology or climate change
@@andreasflensmark8616 How about you answer one questions? First. Do you believe in the standard propaganda mandated in public schools. That is, that we are merely hairless animals that randomly evolved in a meaningless and uncaring universe destined to die and then decompose into dirt...? I kinda already answered your question but I'll be a little bit more explicit if you want me to.
Excellent video contents, I like when the video's don't try to loose you with high flying knowledge only a physics'Philadelphia lawyer could understand... This is an art form in its own write to explain and not loose the viewer's... Nice one... Thanks... Thom in Scotland.
You might want to research your research. You strongly indicate that these materials will, without intervention, cool their environment. The papers are about reducing heat gain of internally heated materials and/or objects. In short, they are increasing emission. At first I thought you were dumbing down your presentation. After looking at the papers, I no longer feel that way.
very interesting, i've been interested in passive cooling for 3 years now but i didn't hear about this before i did some simple passive cooling experiences using open carboard boxes with a temperature probe inside facing the open sky and the temperature really dropped below ambient i remember that cellophane was a bit transparent to infrared but not glass
Heat will always flow from a hot temperature to a cool one. There is no way to remove heat from something when it is cooler then the ambient temperature with out energy input. What is happening is you are blocking the heat to a single area so that area becomes cooler then its surroundings. The James webb is a very good example of this. The sun shield will keep the opposite side of the craft close to the temperature of deep space, but it still requires active cooling to work. I find passive cooling a misnomer as you are not cooling something you are instead preventing it from heating up.
@@rascototalwar8618 The first sentence is true, but the notion of 'ambient temperature' doesn't really fit into that model quite the way you imply. There are 3 obvious relevant temperatures; The sun, our test object, and the ambient temperature. Heat will always flow from hot to cold so if you only consider these three then you would be correct that we could not cool something below ambient (as this is obviously lower than the sun), but you are missing one important temperature: the temperature of the rest of the sky. It is around 3 kelvin. The idea of these materials is to maximise energy exchange with the sky while limiting the exchange with the sun and the air, and that absolutely is cooling. It is not a misnomer. Most of James Webb is not actively cooled, it is just the sensors. Those are cooled well below the temperature of deep space, which is why they need active cooling.
Chemistry has been on a whole new level for years. It's only a matter of time until a huge amount of these things can scale and totally change our world.
Now I wish my kids were more fluent in english. They would suck this video up! This is so much their jam! They would understand maybe half of it and we would need to pause quite often to answer questions, so we would need maybe an hour to watch this video, but they love such things. Really nicely done! I understood everything perfectly well. It was so well explained, that, like I said, my kids could've able to follow, if they were more fluent. (But they barely speak english, understand a bit more.)
If people are disciplined to not throw plastic or ANY trash in to the environment, then there is no big issue. Recycling all the different plastics is not feasible today. PS there are garbage burning plants in sweden that operates at very high temp thus NO dioxins, then there is a filter that collects the ash in the gas, the ash left in the bottom of the oven is then used as filling material.
Well you subsequently gave me an answer that I'd started to think was just too far above me to ever stumble across or purposefully discover, so a great big thanx for you & aluminum oxide!! Liked & subscribed.
there a company called 'Skycool systems' That is manufacturing some panels, except they say it works because of a gap in the atmosphere, Which is certain type of wavelength do not get asorbed
Correct! That is the company and tech Arny showed me while we were talking. That is called the Infrared Window and the greenhouse gases aren't excited about those frequencies. The IR window corresponds to wavelengths of ~8-14 microns. So I wonder if they convert the radiation to that ideal frequency. I'm not super certain if they have a special technology or not.
@@ButWhySci The property is florescence; absorb at one frequency, and emit at another. Laser dyes do this all the time. The problem isn't the underlying technology, it's field stability. Dyes in general are light sensitive; flowers are brighter in the morning because the light degrades the dyes.
Nice video as always. Would you look into the claim that the greenhouse effect is the reason traditional greenhouses work? My understanding is that in greenhouses, preventing convective losses is the key ingredient (see for example the wikipedia entry).
Glass greenhouses for growing plants do not operate on the same principle as the so called "greenhouse gases" like CO2 and CH4 (methane). A glass greenhouse gets hot because the sunlight energy is allowed in by the glass, but the hot air that gets produced (after the sunlight photon energy is absorbed by the ground/plants inside the greenhouse and turns to heat energy) is blocked from convectively rising and wafting away, due to the near air tight glass roof presenting a physical barrier. "Greenhouse gases" like CO2 and methane heat the Earth in the manner described in this RUclips video. The sun radiates much of its energy between around 300nm to 1000nm down to the surface of the Earth. At the surface of the Earth, the sunlight photons hit something like the ground or a tree leaf, and then converts into thermal energy, at a temperature roughly around 300 Kelvin (~25 Celsius). The 300 K earth surface then acts approximately like a blackbody radiator, which re-emits much longer wavelengths of radiation, mostly in the range of 5,000nm to 25,000nm. The so called "greenhouse gases" like CO2 are very transparent to 300nm - 1000nm sunlight radiation, but it is not fully transparent to the 5,000nm to 25,000nm radiation. CO2 has a relatively high absorption of longwave infrared photons in the range of 12,000nm to 25,000nm. Therefore, some of the longer wavelengths of the ~300 K radiation originating from the surface of the Earth end up getting absorbed by CO2 molecules in the atmosphere, and then they get re-emitted in a new and random direction (50% of the time still pointing up towards space, but the other 50% of the time pointing back down towards the surface of the Earth, which causes it to get re-absorbed by the surface of the Earth, thus temporarily preventing the energy from escaping into space). Thus, CO2 does slow/impede radiative cooling of the Earth, which does result in higher average Earth biosphere temperatures. However, the "heating mechanism" of atmospheric CO2 is not the same as a glass greenhouse for growing plants (which relies on mechanically blocking convection of hot air). Perhaps a more accurate term, rather than "greenhouse gases" (for CO2 and CH4), would be "weather modifying gases".
It has nothing to do with convection. It has only to do with the fact that gases like carbon dioxide and methane are ever so slightly opaque to infrared but much more transparent to visible light, so the light from the sun sees no encumbrance in getting in, but the infrared coming from the Earth sees something of an obstacle getting out.
@@Fritz_Schlunder Yes and No. There are 3 methods of heat transfer. Conduction, Convection and Radiation. They all affect the final temperature of the greenhouse in significant ways. It depends on the day, the outside temperatures, the wind speed, the opacity of the air, humidity. Just saying it's convection and convection only, is not really accurate. Not saying convection isn't important, just that it isn't the only thing.
@@Fritz_Schlunder N2 and O2 comprise 99% of the atmosphere; 2,500 times more abundant than CO2. A thermometer held in the air will reveal the temperature of all the constituent gases. If N2 and O2 are "non-radiative" and all the energy absorbed by CO2 is immediately re-radiated, how does the atmosphere as a whole warm and cool? In fact, at 1 bar atmospheric pressure, the CO2 molecule will collide with 1,000 other particles in the refractory period following vibrational excitation, whereby the energy goes into heating the atmosphere, not the surface of the Earth. Wrapping the sphere in a blanket of gas, then warming the gas might raise the temperature of the surface but not by bouncing the same photon back and forth. Equally, it might not, since the warmer air will rise more quickly away from the surface and closer to the level at which energy can be radiated to space by, perhaps, a now enhanced concentration of radiative gases.
This is very interesting technology. The first thing I thought of was cooling for PCs and electronic equipment, that may not substitute coolers but may aid in reducing their load and consequently reducing power usage.
Wow, I was completely blown away by the detail and educational value of this video. a sub well earned. I was even more surprised, I understood most of the video! :D
Wow, this was enlightening! And of course, great production quality! I subscribed. I got an idea from this. We may not be able to make aerogels at home, as NileRed demonstrated how difficult it may be. But PE is very common. And we only need the small particles of it. Then, we can just make dust of it at home using abrasives or crushing, or any way that works. Then, we can either fill it into some microfiber cloth or suspend it in some kind of IR transparent polymer. As a result, we get a DIY cooling material. IDK if that would work, though. I would love to experiment myself, actually. But IDK if I will do it or not.
We already know how to build sefl sustaining houses, i had a whole semester on it. It's about the angle of windows, roof length over windows and thermal mass of the house and the position. Most architects don't care for ecology, they just design by looks and make inefficient housing.
Most of the volume of aerogel is made up of microscopic holes. A very small amount of plastic will produce a very large amount of aerogel. The amount of plastic in the aerogel required to cool a building would be less than the amount of plastic in the paints or tiles that would have made up the facade of the building anyway. If it ever does cause an issue, other polycarbonate molecules such as lipids or cellulose would be fairly easy and renewable replacements/alternatives.
A continuation: Aerogel or other hyper-porous materials could however be prone to shedding micro or nano-particles as they wear under exposure to the elements. For instance, under direct sunlight and wind, it is possible that aerogel could start releasing airborne microplastics, which are known to be harmful to both people and animals. Lipid or cellulose based aerogel alternatives would likely do the same, but, being common organic materials, the particles given off would be less harmful than sawdust
Indeed. Teflon is toxic. Titanium is a heavy metal. And nano particles of these 2 elements would be very volatile and dangerous. Easily inhalated. Organisms can't get rid of nano particles. We will have the same kind of sanitary issue as the one caused by asbestos.
This gave me an idea about a way to generate electricity using the difference of temperature of a building with its environment. Really cool concept! Thanks!
Really cool technology 👍 But please whatever you do don't turn it into a gas and release it into the atmosphere to prevent climate change. Snowpiercer reference
I wrote a book about space based mirrors that are used to cool the planet, how they preform as a heat engine that shunts heat back into space, but one could also run the engine in reverse and cook your enemy with a death ray. You know, that old chestnut.
When talking about human consumption of electricity, and how much of it will be consumed in the future, I will always assume the answer is "More". That said, this looks like an incredible idea; using specific material and their inherent molecular makeup to expel light is far more efficient than air conditioners.
At 10 sec into your video, I already stopped to give you a LIKE! You just jumpled right into the most important info without boring us or wasting our time. I wish all videos did that. I can't wait to push play again....
This is very interesting and enlightening. I have known for 40 years that radiant heat management is a very underdeveloped area of the construction industry, but didn’t know this type of work was ongoing. Thank you very much for the video
Thank you for presenting this in a way a non-scientific mind can understand. I'm always interested in science and its application to real, common life. Two ideas beyond this which might be worth investigating for any who are interested: 1. I saw a segment about 15 years ago where some university students were developing solar paint. (Stuff to absorb and then transform to power.) I have no idea how far they got. They probably ran out of funding but it would be worth checking out. 2. I've always wondered why we can't take our plastic trash, which I've seen it densely compacted into great 'walls' before being sent elsewhere to be trashed. Why can't these walls be used in communities that currently use bits of tin for walls and rooves? Surely they'd provide some insulation whilst letting in some light? It has to be better than tin which can rust over time? Run some giant steel pegs down through them for stabilisation (in the same way foam walls or straw bale walls are built). Render them in mud or concrete for more aesthetic appeal. Who knows- perhaps the odd, random formations or pockets of space contained within these plastic bottles and products will be enough to reduce the heat in the buildings?
Aren't more trees a better way to reduce our heat issue. I am a fan of science and really like this video. When I look a nature, there is a nice solution for the heat. Under a tree it is a lot cooler and it is very green. We just should stop cutting them down and learn how to live with nature. I experience a tree is a inverted greenhouse.
I love when the math checks out.
Passive cooling always worked - but modern material science is taking it to the next level.
Yeah, I bet scientists 30 years ago wouldn't believe that such a simple cloth could be used to cool things down with amazing results
Did you hear from the self cooling clay water bottles of old desert tribes...
So true, I was just thinking about passive/evaporative cooling used traditionally in the middle east, technology might allow to go "back" to better solution then current AC systems
@@cecilia00960 passive evaporative cooling is very neat and efficient, but it requires a low humidity environment (among other trade-offs) which is why it works so well in deserts, and is basically useless in humid heat. It's a good example of how most problems don't have a universal silver bullet solution, but it's still worthwhile to have a buffet of good options that excel under different conditions.
almost read meth
This is amazing! I'm writing a sci-fi book about how people adapt over a 200 year period and I am going to research this branch of materials science to use in the book. Thank you for getting the word out!
I wrote a book about space based mirrors that are used to cool the planet, how they preform as a heat engine that shunts heat back into space, but one could also run the engine in reverse and cook your enemy with a death ray. You know, that old chestnut.
Good luck with your book!
What is the title of the book 📖?
Let us know when u finished the book
Good luck with your book!
This certainly does feel too good to be true. Could you do a more in-depth video on this? I also had no idea such a field existed!
The only information I have is what was available in the papers unfortunately. And what was talked about with Arny. As for the aerogel coating it's biggest constraint is that it's not the most durable material against the elements. In it's current state it's not an ideal candidate for large scale use, however the current best use is for coolers or containers that you want to keep the contents cool. Keep food cooler longer and it can be sheltered from harsh elements.
The silk paper showed that after extensive manipulation, twisting, and stretching, the nanoprocessed silk maintained the bonds between it's fibers and the aluminum nanoparticles. So unless there's a health issue to having aluminum near your skin that I don't know of I think that one is very much a viable option.
The metafabric paper claims it's a scalable process and as seen in some photos, they were certainly able to make large reams of cloth. I don't know how scarce titanium is, so that may be a limiting ingredient. That paper also (That I can recall) didn't go into depth on durability.
There was another fabric paper I didn't talk about that made a polyethylene fabric which was extremely scalable.
So I think there are certainly options. My main concern is the reliance on continued use of plastics.
@@ButWhySci RE: metafabric titanium scarcity: titanium isnt very scarce but it is quite expensive- about $4 per kilo vs steel at about $1.25. It'd be interesting to put forward to a chemical engineer, if its really that scalable, they should have no issue setting up a production facility.
NASA has been using something similar to this for decades on their spacesuits and spacecraft.
Their white paints reflect visible light, near-IR and near-UV - I.E. most of the Sun's radiation - because they're... you know... WHITE. However, the same paints have a high thermal emittance - something usually not found in reflective materials - because in the mid and low infrared spectrum they actually look black.
The result is that anything coated in these paints will radiate away heat but not gain any from the sunlight.
@@Gliccit Titanium oxide is actually very inexpensive and readily available. In fact almost all white pigments used in almost all paints are derived from titanium oxide.
There's some info about passive cooling in architecture if you search for it. In the past, this was the only option once there was no electricity
The book "barefoot architect" demonstrates some techniques to achieve the passive cooling in buildings
It's not exactly what's shown in the video but you can have some ideias about passive cooling
Found this video after seeing NightHawkInLight's recent video on DIY versions of the IR emitting/reflecting paints! Very nifty! I'm glad to see this research continuing and spreading.
Since asbestos, I am always wary about the use of strange new materials in the form of fabric, where it may break away and form airborne fibers that might be toxic, or pollutants of some kind, that nobody expected. Keep it in a solid block so it won't disperse as easily, please. I can see some lightweight shindles that can form a tent-like structure, too.
Agree and the recommend material is made with Teflon, the new asbestos 🤷🏻♀️
@@aduantas gets into your body as micro plastics and disrupts your endocrine systems (at the least)
Nano particles in general are unkind to life and they have no certainty of the totality of the unkindness.
Good point, Teflon, for example, is known to be toxic to humans
Calcium carbonate is also decent for reflecting a lot of light.
You know this guy's on another level when you realize he's able to use geometry nodes in Blender
I was wondering what 3D app he was using. Is it obviously Blender? I was thinking maybe iClone.
At 11:01 you can see him using blender
@@GeeTrieste I would say its Blender, just from personal experience it does look like Blender UI with a geometry node viewer in the bottom panel. As you can see he's got his terrain set up in the top panel. On the right there's a list of all his assets in the scene, those little orange boxes in the top right.
@@gauthierruberti8065 I spent the last year with my free time getting a better understanding of materials and while geometry nodes were growing in popularity and tutorials I sat back and ignored it. Now I'm getting into, but oh so late, lol.
Better late than never?
@@firemyst9064 better now than before! Now you have access to many more nodes and an enormous amount of tutorials. Now will probably be less stressful to look for specific stuff
The narration, the animation, the sentence structure, the clarifications, the pacing. I couldn't find a single issue in this whole video and the way you avoided popular misconceptualizing definitions gave me the hope back that properly sharing information is still possible in this world where they rather converge to large audiences with common slurs. Thank you thank you thank you!
Nice name too 🤣
I hope we start to see some of this in the real world at a not too unreasonable price.
You can already buy aerogel-based insulating paint but cheap it isn't 🤣
The polyester-based insulator is already widely available while we waiting for aerogel-based roofs to be massively produced.
I hope this gets put into commercial use instead of falling into the abyss of obscurity like ever other potentially world changing technology
@@freedom4651 What is a product that is available?
Nah gucci is gonna do something with it and nect thing you know society is gonna accept it as luxury commodity cause were stupid and all that
First correction: most polymers absorb infrared at many frequencies and are not infrared windows. A few polymers with very simple structures such as polyethylene (PE) absorb in only a few relatively narrow bands and are good infrared windows at other frequencies. However, the width of an absorption band also depends on the homogeneity (uniformity) of the local chemical environment. Some grades of PE have polymer chains aligned in the same direction (quasi crystals) and hence are good infrared windows. In PTFE (teflon) the polymer chains have less long range order with two consequences (1) wider absorption bands and (2) more scattering from refractive index inhomogeneity. If the size of the inhomogeneity is comparable to wavelength, the scattering is described by the Mei theory (this is why teflon is translucent rather than transparent).
A second correction is that molecular absorption and emission is highly orientation dependent. The isotropic emission shown in this video only applies because the molecules are randomly oriented and emission is averaged over the random orientations. The spectral characteristics change when molecules are oriented by a surface or manipulated by electromagnetic fields. These properties become very interesting in the context of medical diagnostics (one of the topics in my lab).
Its also worth mentioning that another field of research is dielectric (super) mirrors with reflectivity above 99%. The problem is making super mirrors cheap enough for widespread commercial applications (another topic in my lab currently at pilot scale manufacturing stage).
As an architect student this is so exciting, now I hope it could be commercialized!
@@mt2mgames851 O K
This will get blocked as people are against oil which is required to make the plastic.
I know of a channel called "NightHawkInLight" that has some videos explaining how to make a passive radiative cooling material from household items. The recipe gets better in more recent videos as he finds other methods to produce higher quality materials.
@@lumarans30 ah nice! Thanks
Ray tracing does make the fever dream nature of these animations even more fever dreamy, which I believe is a good thing and looks cool. Can't help but wonder how much it increases the rendering or processing time though, it couldn't be good...
I'm sure he's got that covered, but damn you're spot on. I'm sick right now and I feel like I was just dreaming this video up in my mind. Great stuff.
The biggest thing is that it drastically increases disk space usage since you have to render everything out to individual files/frames. Normally I render out to MP4. But yes it also takes much longer. Not too big an issue because I just have it render remotely while I'm working on another scene. Something weird happened though with exporting from EXR, my photons and sun got very yellow. It looked normal in the video editing software but after export some lights got yellower.
@@ButWhySci If the remote rendering is done near a black hole, it can redshift your animations. :^P
@@ButWhySci I recommend importing it into something like Da Vinci Resolve and messing with the sliders: When seeings the EXR all at the same time, you're seeing all the information at the same time (a lot more than mp4). You might want to use Da Vinci to dial down settings (contrast is the one you want probably) and make it look like blender shows
@@casenc Exactly, i watched a video about this even though i don't use any of these things lol
This actually feels pretty reasonable. If you can make a material that lets through infrared but reflects (instead of absorbing) light / radiation / photons at higher frequencies, it will effectively be an exceptionally efficient sun shade.
Now the problem is, as always, how do you mass produce this, and can you do it economically and ideally cleanly?
even if we don't do it efficiently today, demand would probably force producers to make it more and more efficient over the years.
See clouds.
I'm wondering how it would be implemented in big buildings and areas of extreme distress (with earthquakes and hurricanes and such) and if that implementation would require complete rebuilding to be effective.
And the follow up story......"How a Nobel Prize winner started the next ice age."
@@raffimolero64 Over the years, huh? If only we'd started 40 years ago... Not sure how many years of ramp-up time we can afford for stuff like this before it becomes less about managing energy and more about how to make better stillsuits.
One of the best science channels :) criminally underrated too
Very few channels give me amazing new insights with every video.
But Why?
Hol up *criminally?*
so true ahhahhah
@@adnan7698 its just bad luck, he will explode sooner or later, he just needs the timing to be perfect and juuust the right title for youtube algorythm and boom
This has to be the highest quality brief explanation of heat transfer and chemistry I have ever seen. Love the journal referencing too!
This video is exactly why I want to get a major degree in Materials Engineering, such a fascinating and endless field of study
this is indeed fascinating. even a 10% reduction in heat absorption, would go a longggg way to change climate trajectory.
@@sMASHsoundTrees do just that. And they are larger surface than our buildings on earth . And yet global warming is still here . Perhaps global warming is not something new to the planet and the planet has been heating up for thousands of years. We know that the desert and Egypt were much greener a few thousand years ago. that there was an ice age. So why do we make this global warming event something new? Just so that a few people as usual take advantage to milk others for money, just for profit? Was the market overcrowded, and did some think of putting another fear into play that could be used to milk people?
Go for it! I am studying materials science and engineering and its really cool stuff
You are my favourite science channel. You don’t dumb down the concepts but you do explain then in a way most people can understand.You don’t pad the videos for time unnecessarily meaning you respect your audience. You dive deep into the actual processes of what’s happening at the atomic level making things actually make sense. Just everything about your videos makes me and all my science friends geek out and that is just so cool. Thank you for everything you do, never change please you are my hero.
your visuals are out of this world, I wish you could collaborate with schools or institutes. more students need to see your clear, simple, very will throughout explanation videos.
Hi Robin, I have been watching your Videos for many years now and it's great to see how much you do for the environment.
RE: “hopefully what I find will inspire one of you to start your own research…”
I paused the video three times before I got to the end to begin my own research already!
Mission accomplished, and great video, mate. I’d love to get my hands on those papers.
Oh, HOW I thank my parents/ancestors to be alive here at this moment (and as a non-native English) to have learned how to read/write and study Physics at school and then study English at another school and then understand SOME of this video's knowledge to apply on my day-a-day life.
Thank you, content creator.
As someone who has a voracious appetite for science and technology breakthroughs, it is hard to find content that is presented well enough for me to understand as a layman to new subjects, while also being in-depth and informative enough to actually teach me things I didn't know before and inspire me to learn more. I feel like you really nailed this sweet spot for me in this video. Liked and subscribed!
Yeah its pretty neat, I hate when science channels are too vague
I'm blown away by the depth and detail of this presentation while still staying on the 'somewhat easy to understand' side of things. Spectacular!
I am an architect . Great video btw.
The only practical problem with this is that a building needs to hold onto heat in winter also.
So a fancy inverted greenhouse would be great for hot summers but terrible for cold winters.
it won't be the perfect solution for every environment. but you could easily cover the material in winter or if it is a frabric just remove it entirely in winter.
Only run the HVAC through the dissipater during the winter. You don’t run the A/C during the winter.
Sure it won’t have the impact in temperate climates it will in equatorial ones, but it doesn’t need to work as well there either.
But this would work for infrastructure which is close to the equator, since that these places don’t have cold winters. Heat is problem almost all year round and therefore would be a great idea to implement. Just because it may not work for your situation does not mean it won’t work everywhere.
Also .. the more humans /animals confined in the same space will negate the benefit. The better and trusted solution is Thermal mass ( Under ground systems)
See Cooper Peddy, SA Australia for houses made underground.
The glorious version is Bilbo Baggins house - thermal mass
@@bluedark7724It actually wouldn't negate the benefit, because these materials are specifically designed to be transparent to heat. They don't trap the heat to let it build up, so more bodies in the building wouldn't significantly increase the overall temperature
Absolutely loved this video. As a scientist it's awesome to find channels such as yours. As a curious millenium teenager I was sometimes frustrated for not having enough knowledge or having where to search for it. I'm thrilled today there are content producers like you. Thanks!!!
Exactly
This only strengthens my belief that materials science is by and far the most wild of the practical sciences. There is SO much that this field effects that we pay little mind to or take for granted.
The raytracing is sick brother. Keep up the amazing work, these videos will be used by science teachers soon if they aren't already
Well done content will defend itself. Your channel will blow sooned than later.
And I can't stress enough, how your calmly tone, makes it easier to absorb the facts.
While other science channels pump up their videos to make them more entertaining, yours dominate them when someone wants to learn.
Not in vain there are multiple comments about teachers that should use your vids in schools.
Cool video. I read about a paint utilizing a similar effect a while back. A question re: Your description of the greenhouse effect. My understanding is that the atmospheric density at sea-level causes an excited molecule: CO2, water, methane, etc. to transfer its energy to neighboring molecules via collisions (conduction). Collisions happen so fast that most excited molecules don't have time to revert to their ground state before hitting other molecules. This increases the average kinetic energy, increasing the probability some molecules get enough energy to radiate in the infrared. The resulting warmer, moister air rises until the water vapor precipitates out, radiating the latent heat (again infrared). Above the tropopause we still have CO2, methane, greenhouse gasses that don't precipitate out on Earth. Once the atmosphere gets thin enough then the emissions lines thin out and we need to consider that emissions go in random directions. Often back towards the Earth. I would appreciate your feedback. Thanks in Advance.
Thanks for letting the video running in the directions your research took you. It helps keep the material holistic and inclusive. In a larger context rather than caught narrowly in a single context.
I appreciate the combination of depth and clarity of the explanation here. thank you.
Your level of thoroughness in describing underlying theory as well as applying it to both everyday occurrences and bleeding-edge research is amazing! Just found this channel and you got a new sub!
Convection! Love the science and part of science is feedback... Greenhouse maintain their temperature primarily by preventing convection from letting warm air rise. Open all the vents in a greenhouse and it's temperature will be barely warmer than the surounding air.
It's an unfortunate case of inaccurate naming.
Amazing new discovery! Thank you for this info! The underside of certain types of elytra (aka beetle wings) is also covered with numerous nano sized structures but probably not for thermal conductivity
Amazing work! Better than most of the popular "science & tech" channels out there.
This is what I call high quality content.
I need to rewatch the video.
NighthawkInLight covered a similar thing to this, well, kinda precisely half of it - a paint that can cool objects using the principle of optimisation for radiating the heat away into space. What is extremely interesting is that the paint can be made at home and surprisingly easily without some toxic ingredients
Link? To the formula?
@@markfinley3703 just search "nighhawkinlight paint", he has an entire step-by-step tutorial on how to make it
@@markfinley3703 Google is your friend.
Amazing sir. you've got the trifecta: Great topics, great explainer voice, and intuitive info graphics. I'm always looking forward to your videos and frankly, I really wish they were longer.
Wow!! The animations are sooooooo accurate and awesome! Helps learning complex things so quickly. Thank you for the efforts and all the knowledge share.
This is a REALLY intuitive way to communicate some REALLY information dense concepts, well done
Great explanation, definitely sparked some questions about things that make me want to research further. Thank you for the post
At 11:01 I thought it would lead into an advert for Brilliant but no, you actually meant it. I loved the video and explanations thank you for creating it!
With such technology, we'll need roofs that change with the weather to absorb or radiate heat.
That's not a problem, they could be easily swapped once a year as the material is extremely light
@@guimaciel7457 But if they can switch quickly, you would have the best results for cold fronts or a quick heatwave. The only reason I ever used the AC here in Texas was to get the humidity down indoors.
even if you cant change them for the cold season, it would still save a colossal amount of energy even if its only used jn zones where its hot all year round
Even in these regions you get winter nights below freezing temperatures
@@guimaciel7457 ??? where i live its winter and the worst we get at night is like 5C
Said, while using the hottest computer specs known to man
The best substance for the inverse greenhouse effect is in fact snow. Because it is nearly perfectly white for visible light, and nearly perfectly black for infrared. To those who don't know, emissivity = absorptivity (this is required by the 2nd law of thermodynamics, otherwise a black object and white object suspended in a vacuum and surrounded by mirrors so they were in thermal contact only with each other and only through radiation, would not settle to the same temperature and you could make a perpetual motion machine type 2) so being black to infrared means it is an efficient emitter of infrared. You couldn't ask for it to be more perfect. A pity about it all going away now.
So we can use snow to build cool houses in summer. Oh wait...
Wouldn't snow emit IR in wavelengths that water vapor in the air absorbs? I'd think you'd want to avoid those wavelengths. IR emission by water molecules in snow vs IR absorption by water molecules in the atmosphere. I guess the phase (solid vs gas) tweaks things, but I'd be surprised if the "tweak" is enough to make absorption by water vapor negligible. Maybe it's not a big issue in the dry air of the poles, but for most of the surface of the planet, there's a lot of water vapor overhead.
Snow isn't especially unique in this property. Most materials emit better in ir than visible. A sheet of white paper is also almost a blackbody in thermal IR and... well... white in visible.
@@appa609 time to make a paper tent
@@lauraclose5604 rain : i am about to end this man whole career
Damn, this is one of maybe the top-three most valuable channels on RUclips.
these videos are so cool and love how you show screenshots of the paper rather than just a quoting the paper with its citation
This was so cool and inspiring. Thank you for making this video and doing researching and converting hard laborious scholar articles into a fun way to understand them. I greatly appreciate your efforts.
Your animations are incredible!
That meta fabric sounds amazing but I’d like to know if those micro beads in the fabric could contaminate the environment like micro beads have already done.
ofc it will, it's made with PFASs, and we had enough with the forever chemical....
First time watching one of your videos. Great stuff, and most importantly, THANK YOU for listing your sources!
You're missing something.... convection.
A garden greenhouse works primarily by blocking convection which would otherwise quickly take away the air and water vapour warmed by the upwelling IR.
Another thing to consider, the atmosphere is a pressure gradient, so there isn't a 50/50 chance of re-emission going up or down, it's slightly more likely to go up. There are more particles below to absorb the IR than there are above, so while the direction of radiation is random, the distance before the next collision increases with altitude.
You left out a huge part of the explanation of the greenhouse effect (probably dishonestly because it reduces the fear porn of alarmists) When IR is emitted it is emitted across normal radiation spectrum. But CO2 only absorbs on two narrow bands.
Makings its effect logarithmic. You have exponentially increase concentrations for a linear effect.
and water overwhelms those bands at about 25 times, in width, height, and saturation.
Imagine one junior high freshman on the field against 25 professional football players...
@@geraldfrost4710 But the water vapor does not change that much. Too dry and more evaporation occurs. Too wet and it is precipitation.
For your scenario. Imagine instead of one junior we have three. This will change the score slightly.
instead of 0-100 we now have 0-97.
Given the (max+min/2)temperature of the moon is -180 deg celcius. and the temperature of the earth is around 10-20, it only takes a few percentage points difference to add a couple of degrees.
Didn’t realize most of the heat from my oxyacetylene cutting torch was actually radiation. And how little heat is transferred by the actual molecule contact. It’s like, when I hold my bare hand next to a hot vehicle exhaust, the radiation heat is twice as powerful as when I physically contact that exhaust.
Ok, you have taught me how global warming really happens.
Thermal radiation is one way to accurately measure heat. Most of the heat on the surface of the sun is not radiating through the perfect transparency of space and heating the Earths surface to two thirds of origin.
Yup! Space is cold
I dont think that two thirds of the heat of your oxyacetylene torch come from radiation. That would mean, that it would be almost as hot next to your torch than it is right in front of it since it radiates in all directions randomly. However the cutting only works when the flame is directly contacting the material, so i think conduction plays a major role in this case.
@asimi900
Your right. I was being kinda snarky. They do take a known scientific fact, thermal radiation can increase heat in objects that absorb it, but blow it way out of proportion to come up with aggressive heating due to trace amounts of CO2.
Maybe because satellites only measure the IR radiation to get temperature readings anymore, so it is impossible to separate the contact heat from radiation heat. There are many real scientists who don’t believe in GGGW. But the basic principle is correct.
@@glenndavis4452 Yeah, CO2 was almost never considered the main contributor in the first place since it’s so short lived. In a single human lifetime most of what’s been released can become part of a plant. CO2 has always been about power, money, and starting the conversation.
The actual kickers are a whole gamut of different things, like methane, which can stick around for centuries and actually do some damage. Coincidentally about as much is getting released from the short-term problem of melting ice-caps/glaciers as all of human industry combined, which is why people were so panicky before, trying to keep those damn ice formations intact.
At this point the ice is melting at such a rate that quite a lot of people have resigned themselves to the higher electricity bill and the hundred-year floods every other year. Local governments are really struggling with all the disaster relief they have to do these days, sadly.
@@thesquishedelf1301
It’s sad that they limit you guys climate disaster information to the last few decades. Only.
I’m not going to even try to list the catastrophic floods, droughts, and monumental forest fires documented in newspapers from up to 150 years ago. Birds falling dead from trees because of heat. Thousands of people dying. The Peshtigo fire of the late 1800s covered a third or more of three Midwestern states. The Dust Bowl of the early 1930s had tens of thousands of refugees. Or maybe even more. Starvation otherwise from widespread drought. Sand dunes or bare earth extending up into middle Kansas.
Yes they are spending big money now. Formerly hundreds or thousands died from climate events.
There’s a channel on YT that documents events like that. Tony Heller.
Yes natural methane releases are huge and have varied throughout geological time. It does not survive long in the upper atmosphere.
Methane and CO2 also block IR from the sun, in the frigid upper atmosphere. The claimed difference would be achieved at night, when the absorb the far weaker IR from the earth, transferring whatever heat that creates to the atmosphere.
But they are special in that respect only because oxygen and nitrogen don’t interact with the IR wavelength.
If we have enough dust or smoke atmospherically, doing the EXACT same thing with IR radiation, we experienced mini Ice Ages, not global warming.
There is just way too much actual proven science for me to believe in GGGW.
IF these special molecules can heat thousands of times their mass, from the relatively low level IR of the earth surface, we could damn sure heat our homes and create green steam energy by using that “proven science”.
I did used to believe it, too.
Hey, i´m a chemical engineering student, and i got to say, this channel is amazing, i love every second of it. I have thought about this topic for a while, but haven´t gotten around to studying, you have peeked my curiosity.:) I have a semester project on particle detection, and the explanation on Mie scattering was very direct and easy to understand. Keep up the good work, i will be watching:)
God is the ultimate engineer. He built the whole system in the first place and he says the weather's not going to change...
Genesis 8:22 -
While the earth remains,
Seedtime and harvest,
Cold and heat,
Winter and summer,
And day and night
Shall not cease.
@@brianhale3678 I'm sorry, i don't think i understand, are you saying that global warming isn't a thing or that you don't belive in the tehnology. I could be misunderstanding, but what was the point of this comment?
@@andreasflensmark8616
I'm saying God knows more about the weather than all of the climatologists in the world.
He gave this sentence to Noah immediately after the flood and it has held true for 4,400 years and it's going to hold true in our near future as well.
@Brian Hale Near future?? also i don't think you replied to my question, whether or not he said those things is not that important, i am asking you, do you not believe in the technology or climate change
@@andreasflensmark8616
How about you answer one questions? First.
Do you believe in the standard propaganda mandated in public schools.
That is, that we are merely hairless animals that randomly evolved in a meaningless and uncaring universe destined to die and then decompose into dirt...?
I kinda already answered your question but I'll be a little bit more explicit if you want me to.
Nice i clear presntation. I saw this technologies on other chanels, but none of them explained them that clearly. Good job.
Excellent video contents, I like when the video's don't try to loose you with high flying knowledge only a physics'Philadelphia lawyer could understand... This is an art form in its own write to explain and not loose the viewer's... Nice one... Thanks... Thom in Scotland.
You might want to research your research. You strongly indicate that these materials will, without intervention, cool their environment. The papers are about reducing heat gain of internally heated materials and/or objects. In short, they are increasing emission. At first I thought you were dumbing down your presentation. After looking at the papers, I no longer feel that way.
Nighthawkin light made a video on sub ambient cooling paint that jas a really good explanation imo
What about worms silkworms??
I would agree but I don't think the passive emissions from the dissipation of heat would equivocate to the active emissions used to power AC.
Radiation is emitted back to space (partly) and reduces energy consumption which generates heat
@@zlkanglwrth2776 There is no energy consumption any where in the system. Consumption is converting energy to another form such as matter.
very interesting, i've been interested in passive cooling for 3 years now
but i didn't hear about this before
i did some simple passive cooling experiences using open carboard boxes with a temperature probe inside facing the open sky and the temperature really dropped below ambient
i remember that cellophane was a bit transparent to infrared but not glass
Heat will always flow from a hot temperature to a cool one. There is no way to remove heat from something when it is cooler then the ambient temperature with out energy input.
What is happening is you are blocking the heat to a single area so that area becomes cooler then its surroundings. The James webb is a very good example of this. The sun shield will keep the opposite side of the craft close to the temperature of deep space, but it still requires active cooling to work.
I find passive cooling a misnomer as you are not cooling something you are instead preventing it from heating up.
@@rascototalwar8618 The first sentence is true, but the notion of 'ambient temperature' doesn't really fit into that model quite the way you imply. There are 3 obvious relevant temperatures; The sun, our test object, and the ambient temperature. Heat will always flow from hot to cold so if you only consider these three then you would be correct that we could not cool something below ambient (as this is obviously lower than the sun), but you are missing one important temperature: the temperature of the rest of the sky. It is around 3 kelvin.
The idea of these materials is to maximise energy exchange with the sky while limiting the exchange with the sun and the air, and that absolutely is cooling. It is not a misnomer.
Most of James Webb is not actively cooled, it is just the sensors. Those are cooled well below the temperature of deep space, which is why they need active cooling.
If Richard Feynmann has a youtube channel, this would be it. You deserve more subscribers by the way. 😎👍🏾
Chemistry has been on a whole new level for years. It's only a matter of time until a huge amount of these things can scale and totally change our world.
Now I wish my kids were more fluent in english. They would suck this video up! This is so much their jam! They would understand maybe half of it and we would need to pause quite often to answer questions, so we would need maybe an hour to watch this video, but they love such things. Really nicely done! I understood everything perfectly well. It was so well explained, that, like I said, my kids could've able to follow, if they were more fluent. (But they barely speak english, understand a bit more.)
Amazing video. Please don't go the way of clickbaity corporate misinformation like Veritasium.
Clickbaity? yes. Misinformation? where?
That’s a lot of words to describe a shady tree
Too bad I’m not readin’ ‘em
😂 ❤ 👍
Imagine plastic, being one of the key polluters both directly and indirectly, now being a potential cooling solution. 2 birds one stone
If people are disciplined to not throw plastic or ANY trash in to the environment, then there is no big issue. Recycling all the different plastics is not feasible today.
PS there are garbage burning plants in sweden that operates at very high temp thus NO dioxins, then there is a filter that collects the ash in the gas, the ash left in the bottom of the oven is then used as filling material.
Well you subsequently gave me an answer that I'd started to think was just too far above me to ever stumble across or purposefully discover, so a great big thanx for you & aluminum oxide!! Liked & subscribed.
Fabulous scholarly description of a process far too many people don’t even believe in
"Now with raytracing"
Yeah
there a company called 'Skycool systems' That is manufacturing some panels, except they say it works because of a gap in the atmosphere, Which is certain type of wavelength do not get asorbed
Correct! That is the company and tech Arny showed me while we were talking. That is called the Infrared Window and the greenhouse gases aren't excited about those frequencies. The IR window corresponds to wavelengths of ~8-14 microns. So I wonder if they convert the radiation to that ideal frequency. I'm not super certain if they have a special technology or not.
@@ButWhySci The property is florescence; absorb at one frequency, and emit at another. Laser dyes do this all the time. The problem isn't the underlying technology, it's field stability. Dyes in general are light sensitive; flowers are brighter in the morning because the light degrades the dyes.
Nice video as always. Would you look into the claim that the greenhouse effect is the reason traditional greenhouses work? My understanding is that in greenhouses, preventing convective losses is the key ingredient (see for example the wikipedia entry).
Glass greenhouses for growing plants do not operate on the same principle as the so called "greenhouse gases" like CO2 and CH4 (methane). A glass greenhouse gets hot because the sunlight energy is allowed in by the glass, but the hot air that gets produced (after the sunlight photon energy is absorbed by the ground/plants inside the greenhouse and turns to heat energy) is blocked from convectively rising and wafting away, due to the near air tight glass roof presenting a physical barrier.
"Greenhouse gases" like CO2 and methane heat the Earth in the manner described in this RUclips video. The sun radiates much of its energy between around 300nm to 1000nm down to the surface of the Earth. At the surface of the Earth, the sunlight photons hit something like the ground or a tree leaf, and then converts into thermal energy, at a temperature roughly around 300 Kelvin (~25 Celsius). The 300 K earth surface then acts approximately like a blackbody radiator, which re-emits much longer wavelengths of radiation, mostly in the range of 5,000nm to 25,000nm. The so called "greenhouse gases" like CO2 are very transparent to 300nm - 1000nm sunlight radiation, but it is not fully transparent to the 5,000nm to 25,000nm radiation. CO2 has a relatively high absorption of longwave infrared photons in the range of 12,000nm to 25,000nm. Therefore, some of the longer wavelengths of the ~300 K radiation originating from the surface of the Earth end up getting absorbed by CO2 molecules in the atmosphere, and then they get re-emitted in a new and random direction (50% of the time still pointing up towards space, but the other 50% of the time pointing back down towards the surface of the Earth, which causes it to get re-absorbed by the surface of the Earth, thus temporarily preventing the energy from escaping into space).
Thus, CO2 does slow/impede radiative cooling of the Earth, which does result in higher average Earth biosphere temperatures. However, the "heating mechanism" of atmospheric CO2 is not the same as a glass greenhouse for growing plants (which relies on mechanically blocking convection of hot air).
Perhaps a more accurate term, rather than "greenhouse gases" (for CO2 and CH4), would be "weather modifying gases".
@@Fritz_Schlunder Amazing explanation, thank you so much
It has nothing to do with convection. It has only to do with the fact that gases like carbon dioxide and methane are ever so slightly opaque to infrared but much more transparent to visible light, so the light from the sun sees no encumbrance in getting in, but the infrared coming from the Earth sees something of an obstacle getting out.
@@Fritz_Schlunder Yes and No.
There are 3 methods of heat transfer. Conduction, Convection and Radiation. They all affect the final temperature of the greenhouse in significant ways. It depends on the day, the outside temperatures, the wind speed, the opacity of the air, humidity. Just saying it's convection and convection only, is not really accurate. Not saying convection isn't important, just that it isn't the only thing.
@@Fritz_Schlunder N2 and O2 comprise 99% of the atmosphere; 2,500 times more abundant than CO2. A thermometer held in the air will reveal the temperature of all the constituent gases. If N2 and O2 are "non-radiative" and all the energy absorbed by CO2 is immediately re-radiated, how does the atmosphere as a whole warm and cool? In fact, at 1 bar atmospheric pressure, the CO2 molecule will collide with 1,000 other particles in the refractory period following vibrational excitation, whereby the energy goes into heating the atmosphere, not the surface of the Earth. Wrapping the sphere in a blanket of gas, then warming the gas might raise the temperature of the surface but not by bouncing the same photon back and forth. Equally, it might not, since the warmer air will rise more quickly away from the surface and closer to the level at which energy can be radiated to space by, perhaps, a now enhanced concentration of radiative gases.
This is very interesting technology. The first thing I thought of was cooling for PCs and electronic equipment, that may not substitute coolers but may aid in reducing their load and consequently reducing power usage.
Wow, I was completely blown away by the detail and educational value of this video. a sub well earned. I was even more surprised, I understood most of the video! :D
Wow, this was enlightening! And of course, great production quality! I subscribed.
I got an idea from this. We may not be able to make aerogels at home, as NileRed demonstrated how difficult it may be. But PE is very common. And we only need the small particles of it. Then, we can just make dust of it at home using abrasives or crushing, or any way that works. Then, we can either fill it into some microfiber cloth or suspend it in some kind of IR transparent polymer. As a result, we get a DIY cooling material.
IDK if that would work, though. I would love to experiment myself, actually. But IDK if I will do it or not.
We already know how to build sefl sustaining houses, i had a whole semester on it. It's about the angle of windows, roof length over windows and thermal mass of the house and the position. Most architects don't care for ecology, they just design by looks and make inefficient housing.
I'd love to look into this, would you mind sharing the name of the course or pointing me in the direction?
@@kobold_sushi_executive_chefShould look into earthships.
Awesome.
It's possible that these new materials might cause a new form of pollution? They say plastic is bad. Would these be worse over the long run?
Most of the volume of aerogel is made up of microscopic holes. A very small amount of plastic will produce a very large amount of aerogel. The amount of plastic in the aerogel required to cool a building would be less than the amount of plastic in the paints or tiles that would have made up the facade of the building anyway. If it ever does cause an issue, other polycarbonate molecules such as lipids or cellulose would be fairly easy and renewable replacements/alternatives.
A continuation:
Aerogel or other hyper-porous materials could however be prone to shedding micro or nano-particles as they wear under exposure to the elements. For instance, under direct sunlight and wind, it is possible that aerogel could start releasing airborne microplastics, which are known to be harmful to both people and animals. Lipid or cellulose based aerogel alternatives would likely do the same, but, being common organic materials, the particles given off would be less harmful than sawdust
Indeed.
Teflon is toxic.
Titanium is a heavy metal.
And nano particles of these 2 elements would be very volatile and dangerous.
Easily inhalated.
Organisms can't get rid of nano particles.
We will have the same kind of sanitary issue as the one caused by asbestos.
The animation is interesting, especially the dancing electron
This gave me an idea about a way to generate electricity using the difference of temperature of a building with its environment. Really cool concept! Thanks!
What you're thinking of is called a thermopile, in the off chance you didn't know. They're pretty neat!
ALL NOTIFICATION-GANG ASSEMBLE
Really cool technology 👍
But please whatever you do don't turn it into a gas and release it into the atmosphere to prevent climate change.
Snowpiercer reference
@@somenameidk5278 I think it was more a joke than an argument
I wrote a book about space based mirrors that are used to cool the planet, how they preform as a heat engine that shunts heat back into space, but one could also run the engine in reverse and cook your enemy with a death ray. You know, that old chestnut.
So, remove the heat pollution and introduce chemical pollution to replace the heat pollution, clever.
Exquisitely beautiful video! More, please! 🎉❤😊
Thank you for digging that out directly from science papers to youtube :) That's really valuable stuff.
U really needed to go through the history of physics just to get this video to 10+ minutes didn't u? 🤦♀️😭😭
TikTok attention span
When talking about human consumption of electricity, and how much of it will be consumed in the future, I will always assume the answer is "More". That said, this looks like an incredible idea; using specific material and their inherent molecular makeup to expel light is far more efficient than air conditioners.
Material science is so interesting, I'm always excited whenever a new material is discovered or invented.
Great video. Examples and graphics and art really help the understanding
I like to listen and learn while I work. This one I'm going to have to go back and actually watch.
At 10 sec into your video, I already stopped to give you a LIKE! You just jumpled right into the most important info without boring us or wasting our time. I wish all videos did that. I can't wait to push play again....
What a nice way to make science divulgation, I am amazed
This is very interesting and enlightening. I have known for 40 years that radiant heat management is a very underdeveloped area of the construction industry, but didn’t know this type of work was ongoing. Thank you very much for the video
You somehow just made sense of my breathing exercises. And no, I can't explain it, but thanks for this video!
Amazed that I found this channel. Looking forward to bring inspired
This video was so interesting to me that I created a new playlist just to save this and not loose it in a variety of fun stuff
Damn, this is one of those videos which make me smarter whilst being interesting af. Great job!
Thank you for presenting this in a way a non-scientific mind can understand. I'm always interested in science and its application to real, common life. Two ideas beyond this which might be worth investigating for any who are interested:
1. I saw a segment about 15 years ago where some university students were developing solar paint. (Stuff to absorb and then transform to power.) I have no idea how far they got. They probably ran out of funding but it would be worth checking out.
2. I've always wondered why we can't take our plastic trash, which I've seen it densely compacted into great 'walls' before being sent elsewhere to be trashed. Why can't these walls be used in communities that currently use bits of tin for walls and rooves? Surely they'd provide some insulation whilst letting in some light? It has to be better than tin which can rust over time? Run some giant steel pegs down through them for stabilisation (in the same way foam walls or straw bale walls are built). Render them in mud or concrete for more aesthetic appeal. Who knows- perhaps the odd, random formations or pockets of space contained within these plastic bottles and products will be enough to reduce the heat in the buildings?
Aren't more trees a better way to reduce our heat issue.
I am a fan of science and really like this video. When I look a nature, there is a nice solution for the heat. Under a tree it is a lot cooler and it is very green. We just should stop cutting them down and learn how to live with nature.
I experience a tree is a inverted greenhouse.
The idea that you've explained something so complicated to a 7th grade science experiment makes listening to Freeman that much more important.
Dude, I study materials science, I'm definetively propposing this to my teachers for a thesis proposal!
Great video! You make physics understandable. Well done 👍
This makes sense. Waves can be “knocked” off course by bubbles tuned to the wavelength. Very cool!
Passion, research, presentation. Superb
I'm not properly processing how interesting is this. Let's hope it becomes something reliable (and safe) fast.