But HOW Does Carbon Dioxide Trap Heat?
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- čas přidán 11. 04. 2023
- Check out NOVA's video on cloud seeding and the PBS Earth Month Playlist:
• How the West Is Making...
We all know about the greenhouse effect, but how many of us actually understand it? Turns out, CO2 is not a “blanket,” and saying it “absorbs” heat is barely half the story. In today’s episode we figure out what’s so special about this one molecule that allows 0.04% of it to change our entire planet.
For more on the Heisenberg Uncertainty Principle: plato.stanford.edu/entries/qt...
1959 Video about Vibrational Modes:
• Vibration of Molecules...
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Credits:
Executive Producer:
Matthew Radcliff
Producers:
Elaine Seward
Andrew Sobey
Darren Weaver
Writer/Host:
George Zaidan
Scientific Consultants:
W. Paige Hall, Ph.D.
Leila Duman, Ph.D.
Brianne Raccor, Ph.D.
Executive in Charge for PBS: Maribel Lopez
Director of Programming for PBS: Gabrielle Ewing
Assistant Director of Programming for PBS: John Campbell
Reactions is a production of the American Chemical Society.
© 2023 American Chemical Society. All rights reserved.
Sources:
docs.google.com/document/d/16... - Věda a technologie
Let me just add one more comment praising the quality of your videos. This video made an important, and frankly complex, topic very accessible and intelligible. And you did it with great charisma and editing to pull us all in.
Hey thanks for the kind words
@@ACSReactions Since 280ppm we have added on 1,8W/m2 due to increased CO2? True?
What is the variability of the albedo? I assume clouds are not constant. What is the +- w/m2 if we change albedo by 1%?
Thank you! I've been trying to wrap my head around this concept to teach others and this video just made it a whole lot easier for me to understand. I love the metaphor too, will definitely be using it when explaining to others.
Your editor deserves a raise.
Shhh. We don't want Andrew's head to get any bigger! J/K. Thanks for the kind words.
@@ACSReactionsyou deserve a raise too. 🤔😏
Dude what a great video. I could see the amount of work and effort put into every single detail and the cut was seamless. I needed this video.
This is exactly what I've been trying to understand. Thanks!
Finally I can feel like I really understand this. Thanks for the excellent explanation.
Keeping my attention with constant match cuts definitely worked. Thanks for the phenomenal video
This is amazing content. Just shows how Physical Chemistry applies to our day-to-day life, like meteorology.
Hey thanks--we appreciate it.
@@ACSReactions
Extremely interesting thank you.👍
🤔 I was wondering if you would do a video on the difference between methane and carbon dioxide🤔 monoxide?
I've heard methane is worse.
Physical chemistry is _much_ more applicable to ordinary life than meteorology! Meteorology only explains the weather and how we predict it. Physical chemistry explains why things are the colors they are, and why some materials are conductors of heat or electricity while others are not, and why some materials are hard, or soft, or brittle, or tough, or translucent, or transparent. Everything you see, and the fact that you see at all, are results of physical chemistry.
@@ColonelFredPuntridge Yep. I took biophysical chemistry in undergrad. Possibly my all-out favorite class. Water's high heat capacity (due to it's molecular geometry) explains why it's the "universal solvent," standard state delta G's explain why ligands always bind to the right biopolymers, kinetics applies to enzyme catalysis, the list goes on and on.
@@JaxesGame’ll have to wait for the video, but the one thing I do know about methane that explains part of why it’s so bad is that when methane breaks down molecularly, it _becomes_ carbon dioxide, which is one of the reasons it’s so bad. It effectively does “double damage” because of that, although it isn’t numerically double, it’s several multiples more than double.
One of the other problems with methane is that most of it on earth is actually frozen underground where it’s not doing anything. But as global warming increases, more of that frozen methane thaws out and eventually becomes a gas that goes into the atmosphere where it first acts as a greenhouse gas for a while, and then eventually breaks down into even more CO2, adding more heat to the atmosphere, causing more methane to thaw and become a gas and then become even more CO2. It’s an extremely detrimental process.
this was the best educational video ive ever seen. you managed to entertain me but also provide an extremely simple to understand explanation as someone who struggles with math. thank you
Wow, for years I've tried to understand the greenhouse effect and global warming. I heard about it in primary school all the way to college, yet, I never understood as I understand it now after watching your video. So, thank you. And you know, that last example with the nuclear bomb was just jaw dropping, and perfectly reflects how crucial action on carbon emissions is.
@@seanleith5312 Fact 5: you are a lier. Watervapour only stays a few days in the atmosphere unlike co2. Warmer air lifts off with watervapour (aerosols) to form clouds and finally transforms to snow or rain or hail. Watervapour is an temporary greenhouse so there will be no effect for climate change.
Well, I saw it and I see what he's saying, but I see many holes in that argument, can't you?
@@stofjes4204 I felt it was just pushing an agenda, I get what he's saying, but it doesnt make any sense, he's making out this is some regenerative action akin to a lasers cavity, sounds like BS to me.
@@seanleith5312 Fact's 1 and 2 - Correct. Fact 3 - Incorrect (Debunked in this video). Fact 4 - not a fact, just a misspelled accusation levelled without the support of evidence.
@@seanleith5312 Sure dude.. If you actually studied like presenter has, you would understand that it's water vapor that is the greenhouse gas, and water is continually moving between it's 3 phases. So what's one of the main drivers of heating that causes water to evaporate? CO2 temperature forcing..
But seriously, why should we believe you over this guy, or any climate scientist for that matter?
great audio mixing with the scene switches, i hear no change or interruption, amazing!
For explanation 10/10. For good natured humour 10/10. Thank you. 🙂
This video is so well produced. Absolutely amazing video
Great video; yet the atmosphere is not warming.
@@arthurfoyt6727 there is so much evidence that contradicts that. Would you like me to walk you through it?
I also noticed your other comment about IR and the glass box. It’s the comment where you provided the time stamp. I think you are mixing up or misunderstanding the transmission spectrum of soda lime glass. You are mistaken about IR not being able to pass through glass (+80% transmission up until the far end of middle infrared, where the transmission drops to about 30%). However, most of UVB and the majority of UVA can’t pass through glass (soda lime glass has high absorbance for UV). Maybe you confused UV and IR or Transmission and Absorption?
@@anon69_q Plenty of data that shows NO WARMING in the atmosphere over decades, just surface warming.
And there is a reason real greenhouses are glass; to trap infra red.
damn! studied BSc physics and have been watching sci edu content for many years but have only understood this now. Such a clear fun video - thanks!
This explanation was absolutely amazing, thanks!
I am going to show my class this video. Fantastic.
Same. Good timing as we go from spectroscopy to the teeny tiny bit of stat mech we can still cover in the last couple weeks.
Make sure and tell your students that humans have only added 1.4 parts CO2 to 10,000 parts total atmosphere, and that Mythbusters had to add 523 times MORE CO2 in order to get the temperture to rise 0.9 degrees in their test chamber. Then they will understand that climate change is giant lie.
This is a good Part 1 because it includes 9:37 to 9:56 instead of the usual annoying irrelevance "absorbs and then re-emits 50% back down to the surface". This is Part 1 which is only ABSORPTION in the air. There's a required Part 2 that is absent from this video. Part 2 is MANUFACTURE in the air. Hint: Presenter never states the phrase "tropospheric temperature lapse rate", but it's ESSENTIAL because, guess what, ..... cooler parcels of matter radiate less than warmer parcels of matter (the stratospheric "greenhouse effect" is backwards).
Very nice! I just want to point out one thing. Vibrations of a molecule on their own can't raise the temperature. They have to transfer to the translational motion of the gas molecules in order to raise their temperature, probably through collisions.
Nicely explained! 👏🏼👏🏼👏🏼
Nicely commented!
Brilliant .... Fun, full of information put simply...Very well organized.
I guess methane has more vibration modes to cause the dipole effect so it absorbs more IR energy? Is this what causes it to be a more intense greenhouse gas? I think some of us would like a short video on how these other greenhouse gases such a methane, CFC and HFCS differ from CO2. Thanks for your great chemistry videos. Very informative.
Amazing episode. Funny and informative.
Thank you so much! This is perfect for my GHG lab!
Great explainer video for the process (although the final example ignores the fact that roughly half the CO2 we put in the atmosphere is sucked out and buried by the oceans). Can you do a similar video that explains (or unravels) the CO2 absorption saturation effect?
it is always so hilarious when people explain what they don't understand!
Who are you talking about? The presenter?
@@MrRadbadger HINT: open your 1st grade textbook and find the DEFINITION of temperature.
meditate.
@@sillysad3198 So his definition of temperature was wrong? Sure Einstein.. How so?
@@MrRadbadger if you live in the world of "wrong" definitions. i rest my case.
@@sillysad3198 I'll reword the question so there's no ambiguity.. What is the right definition?
I love your videos! You guys rock! Or is it vibrate. You guys vibrate!
😂😂
Well done!
"uses the energy from photons to make nearby molecules move faster". . Energy states (the O-C-O relationship) in CO2 are quantum. They only change in quantum amounts. That is why CO2 has only a few narrow bandwidth of photons it can absorb. In fact, each bandwith would be a thin line (not a tiny normal distribution of frequencies around that thin line) if it wasn't for the Doppler effect (molecules are moving at about the speed of sound). A crash between two molecules isn't quantum (think about the infinite number of ways that N2 can approach CO2 as the Oxygen molecules vibrate towards and away from the incoming N2). So, no energy is transferred because a higher CO2 state can't collaspe to its stable state. It's all or nothing. The change in energy (potential to photonic) has to be exact (quantum). That is why a crash results in nothing or it results in the only quantum action available--creation of nearly the same photonic energy that was absorbed. So at about a billion times a second (how often crashes occur), the energy from a photon is converted to potential energy inside a CO2 molecule and then back to photonic energy.
So what causes the air to warm if not from Kinetic transfer? IR ends up taking a tortured path to space (it takes a few weeks). Pinballing between H2O and CO2 molecules until, a few weeks later, the energy finally escapes to space. But in the meantime, incoming irradiation doesn't stop, waiting for the IR to reach space. So IR accumulates for a while causing temperatures rise until a new balance is achieved (higher temperatures support higher levels of IR).
Notes: (a) Air molecules can crash all they want but the net Kinetic Energy is conserved (doesn't change). (b) There are also momentum transfers between a photon and CO2 molecule but those are net zero (adding as often as subtracting). (c) A quantum collapse of a higher unstable state (resulting in a photon and stable state) doesn't require a crash. Decay can be spontaneous.
I really loved this video, it has helped me to better understand the underlying science of climate change. There are still questions that I have, but this video has helped me a lot.
One question that I would like to be answered is whether the level of CO2 in the atmosphere will ever reach a point that the greenhouse effect becomes saturated. Is there a point at which adding more CO2 to the atmosphere makes no difference?
In a word: No.
At the current level of CO2 (420 ppm), infrared light can travel about (let's say) 10 meters before it hits a CO2 molecule. If we double the concentration (840), that distance is cut in half. Keep doubling and we keep halving. At 99% CO2, there's still some distance the light could go before hitting a molecule. So by that simple measure, you're still not fully saturated.
@@richardseymour7162 Thanks Richard. One of the arguments climate science deniers use is that the level of CO2 is such that it now makes no difference if we add more CO2 as it will not have any effect, due to its being at saturation point. I have seen some arguments refuting this claim, but I have not really been able to quite get my head around them. For example, it is stated that the upper layer of CO2 gets higher as more is pumped into the atmosphere, and the consequent lower temperature at this level means that heat can not be radiated away into space so quickly. I am sure this is probably true, but my level of thermodynamics knowledge is not quite sufficient for me to appreciate this explanation.
The argument that you have given is the most easily understood one I have seen and I appreciate you taking the time to reply to my question.
Davidpotter3717. I think yes, there must be, simply because if there wasn't, back in the past , especially Cambrian times when the CO2 was nearly 6000 ppm the earth would have been awfully hot, and this was a time when according to scientists there was an explosion of life . Think about it, if we have approx a 1c increase in temp caused by an increase of 150ppm, imagine if it increased 40 times that?
@@denzilpenbirthy5028 Millions of years ago in the Cambrian the Sun was less powerful. Therefore, it was hotter than today but not as much as one would expect given the CO2 levels. Also that "explosion of life" occurred in the sea and mainly among invertebrates. Atmospheric CO2 continues to rise, global temperatures continue to rise. The suggestion of saturation is at best wishful thinking.
@@denzilpenbirthy5028 The fact you won't be losing sleep worrying about it is irrelevant. Particularly, as are you clearly have some major gaps in your understanding (or are intentionally posting nonsense gish gallops in bad faith).
The "explosion of life" you're talking about was over 500 million of years ago when there almost no life on land let alone humans.
CO2 levels are over twice as high as the lowest they've ever been so... no, not close to the "lowest they've ever been": 180 ppm vs 419 ppm.
Yes, we live in an ice age. Many of the alpine glaciers are crucial sources of fresh water for many major cities and farming communities. Scientists have studied the glacial and interglacial cycles in great detail. Scientists have studied how they are related to the orientation (or wobble) of the Earth that change Solar irradiance slightly. Given that we know the current orientation of the Earth and the timing of previous cycles we know that we are not due to come out of the current ice age for another 7000 years. It should not currently be warming.
CO2 has followed temperature in the past at certain points during the orbital cycles. However, again we know the current orientation of the Earth and it cannot explain the current increase in CO2. The recent upward spike in CO2 is not due to extra volcanic activity either (see e.g. Gerlach 2011). The recent upward spike in CO2 is due human activity. We know this because:
1, the amount of extra CO2 in the atmosphere fits with estimates of how much fuel we burn,
2, satellites and ground stations can measure CO2 due to dimming and they find the greatest current sources of hotspots are cities, industrial areas etc.,
3, the isotope ratio of atmospheric CO2 is getting lighter (more C12, as you would expect from burning fossil fuels, not more C13 as you would expect if the source was volcanos or weathering).
It is true some increase in temperature and CO2 can be beneficial for some commercial plants and crops. However, increase in temperature and CO2 can also lead to increases in pests and weeds which are much harder to control outside a greenhouse. Moreover, plants don't just need CO2. They also need fresh water and appropriate topsoil. Both these things are likely to be less available in a warmer world. Moreover, global warming causes climate change not simply warming. It reduces long term regional predictability which has been necessary for growing the correct crops in the correct places for centuries. There is already evidence that shows the speed and extent of climate change is having a negative impact on some agriculture and broader ecosystems.
Here are some sources if you actually care about evidence and facts:
- Gerlach, T., 2011. Volcanic versus anthropogenic carbon dioxide. Eos, Transactions American Geophysical Union, 92(24), pp.201-202.
- Hausfather, et al. 2020. Evaluating the performance of past climate model projections. Geophysical Research Letters, 47(1), p.e2019GL085378.
- Lacis et al. 2010. Atmospheric CO2: Principal control knob governing Earth’s temperature. Science, 330: 356-359.
- Osman et al. 2021. Globally resolved surface temperatures since the Last Glacial Maximum. Nature, 599(7884), pp.239-244.
- Rae, J.W., Zhang, Y.G., Liu, X., Foster, G.L., Stoll, H.M. and Whiteford, R.D., 2021. Atmospheric CO2 over the past 66 million years from marine archives. Annual Review of Earth and Planetary Sciences, 49, pp.609-641.
- Supran et al. 2023. Assessing ExxonMobil’s global warming projections. Science, 379(6628), p.eabk0063.
- Weyhenmeyer et al. 2016. Sensitivity of freshwaters to browning in response to future climate change. Climatic Change, 134, 225-239.
- Winkler et al. 2021. Slowdown of the greening trend in natural vegetation with further rise in atmospheric CO2. Biogeosciences, 18(17), 4985-5010.
would be great to explain why CH4 is ever worse than CO2 regarding greenhouse effect
Regarding your description of CO2 increasing in KE (around 10:15) and transferring that increase to O2 and N2 via conduction, thus increasing atmospheric temperature: This is a misconception and entirely incorrect. Warming occurs via a disruption to the earth's energy equilibrium. Yes, the absorbed IR will increase GHG KE, which has two results, either a release of IR, which brings the GHG KE back to pre-absorption KE, or a transfer of KE to surrounding molecules. The latter can result in a momentary localized warming. Momentary due to eventually (and quickly) tranferring, via conduction, that energy back to a GHG, which will then emit it as IR. All localized increases in KE eventually end up at a GHG that will emit IR. Of course the GHG can start a new cycle of conduction, but it always comes back to a GHG, which at some point releases the energy as IR, which is eventually either lost to space or lost to the earth via IR absorption at the surface. There is no net change in KE in the atmosphere. The consequences of increasing CO2 and other GHGs in the atmosphere is to disrupt any established energy equilibrium between incoming solar energy and outgoing IR energy. The increase in atmospheric temperature that we call global warming comes from the earth retaining more solar energy to increase IR output in an "effort" to reestablish the equilibrium that has been lost through increasing atmospheric GHGs. As the earth retains more solar energy, much of that is transferred as heat to the atmosphere via conduction, and so the atmosphere increases in temperature. CO2 and other GHGs do not trap heat in the way you describe. They trap IR energy, which does not translate to higher KE beyond a short moment as described. Global warming is a phenomenon of disrupted energy equilibrium, not a phenomenon of simple energy collection. The warming occurring in a bottle with more CO2 in it is due to the localized increase in KE being trapped, via conduction, by the material of the bottle itself, whether glass or plastic, and conducting KE back into the bottle (as well as out).
This video is just pure quality
I love the editing
The speaker recommends reading the 14K-word _Encyclopedia Britannica_ article about the Heisenberg Uncertainty Principle, in order to understand what it is. That's one idea. A better idea, which might unfortunately take a little longer, would be to learn calculus (that's a math course), and then learn a bit about differential equations (that's another math course), and then take a course in quantum mechanics (a physics course). It'll take longer than reading a 14K-word article, but you'll know the subject better when you're done, and you'll be able to do several kinds of engineering as well.
Did I miss something? I understood that methane with virtually no dipole moment is worse than carbon dioxide as hren house gas. So did you explain that somewhere in the video? If not please make another video.
I am not a chemist, but considering how CO2 molecular vibrations can make it assymetric and therefore transiently dipolar, similarly vibrations of the CH4 molecule probably induce assymetry and dipolarity. Indeed, there are many more ways that such assymetry can occur in CH4 because it has more components to vibrate than CO2
What an amazing video! You deserve much more attention for your hard work!
We're just glad people are appreciating it.
The quality of videos on this channel is amazing💯Great work.
We aim for excellence--and are glad you like it.
Thank you so much for this video!
Well done (no pun intended)! Next question: why is CH4 a greenhouse gas far more potent than CO2?
Because methane reacts at wavelengths not already saturated. It is also less dense and reaches higher altitudes and stays for a lengthy period of time.
Could you please make videoi explaining how SO2 gas causes opposite to greenhouse effect?
Wondering why the question .. maybe because most of the temp rise from the bottom of the mini ice age in the mid 1700's happened before 1940 .. before we really got industrialized... and the cooling from 1930 till mid 1970's while CO2 rose dramatically had to be explained some how ?
Is there a video comparing dry (co2) ice & water ice?
It also works the other way around: oxygen and nitrogen molecules can bump into CO2, transferring heat to CO2, after which CO2 can radiate that energy out. So CO2 is also a cooling gas at the same time.
4:48 love that cat!
Wait, so the energy a photon gives to a molecule is not by having it exite electrons to other orbits? Or did he just skip that part to make it simpler to understand? And another thing when I watches Sabine Hossenfelder talk about this she did not mention this , she had more focus on the altidude of the molecules in the atmosphear emittet energy. Could someone help clear things up for me?
No scientist here, but I think you got it. The electron _is_ excited, but you still have conservation of momentum, so the molecule also feels a "photon pressure" like the way a solar sail works, or one of those glass bulbs with the black and white spinning blades. So there is additional motion from the momentum of the photon (hf), which the CO2 molecule can then give to another molecule by bumping into it.
EDIT: People don't like my answer, but if we're talking about UV photons, I think this is still valid (with the energy delta being a Stokes shift). For the "bumping" I was referring to the general scenario at 9:40 though I acknowledge that's talking about IR explicitly.
As a previous commenter stated, molecules can partition energy across four different types of quantum states: translational, rotational, vibrational, and electronic. Energy gaps between electronic states are large, so to excite an electron you would need more energy than an IR photon can provide -- you would need a UV or visible photon. Vibrational energy gaps are smaller, so a vibrational transition can be caused by an infrared photon, which is the process described in this video.
There is no electronic excitation happening during infrared absorption, nor is the photon simply "bumping into" the molecule to give it momentum. The photon's energy is being absorbed by the molecule, which causes the molecule to vibrate at a higher frequency.
As a retired chemist who has done IR spectroscopy, I can tell you that water vapor is at least an order of magnitude more IR absorbent per mole than CO2. It is also present at a much higher concentration in the atmophere than CO2. It functions exactly like CO2 in your explanation. So what makes CO2 so special?
exactly!
@@radugurau335
That's what I don't get... If CO2 is heavier than air, how can it be related as being a green house gas?
It is special because it doesn’t absorb it, it merely transfers photon energy to other molecules, so that they vibrate faster
Hello. Thank you for your explanation. I have a few questions. You mention that the water molecule can absorb a photon, while CO2 works more like a "conduit", is there also a cycle in which the water molecule that absorbs a photon, causing it to vibrate faster, collides with other O2 or N2 molecules making them have more energy? Why, if there are more H2O molecules in the air, isn't this the main greenhouse effect?
Sorry for the slow reply, but this is a great question! The reason CO2 is the bigger concern is that we aren't increasing the amount of H2O in the atmosphere. H2O is widely present on Earth-there are whole oceans of the stuff!-so the amount of H2O in the atmosphere is mainly dependent on temperature. CO2, on the other hand, we're constantly _creating_ and adding to the atmosphere, increasing its concentration. So while it's true that H2O has a more significant effect on the temperature than CO2, that effect is stable, whereas CO2 is very much not.
Great video. You explained short wave radiation dynamics, which is about half of planetary thermoregulation, which in the end does not stays trapped in the atmosphere resulting in climate cooling; but, What about long wave radiation? It gets trapped and results in climate warming. Climate cooling and warming maintains a balanced temperature in the planet that has allowed life to thrive. The problem that we have currently is the excess of carbon dioxide concentration that has not been seen in about 10 million years; this gas is effective in trapping long wave radiation. We would need a video about this to explain Climate Change. Thanks.
Thx for your scientific information & explanation ^ ^
Wow, wasn't expecting that. That's new knowledge to me
Is the basement is the only place you are allowed to put up a whiteboard?
Geeez,
That end of the video was a bit scary.
And I half expected a segue into kurzgesagt!
At 1:02 "fill up a glass box" means that IR does not get into the box; the GLASS prevents it. Hello?
👏Brilliant video!👏
I feel as if I am not the target audience for this kind of explanation video because the constant jumps and scene/lighting/tone changes made it a bit hard to keep up. I do know that you put so much effort into this and I’m glad to see all the commentators say this helped them, but maybe in another video the pacing can slow down a little? 🥲 great job though 👏
You can change the playback speed to 0.75x in the video settings and watch at a more sedate pace.
I studied some chemistry and wonder now if CO2 can be compared to a coloring substance in water where the concentration is according to the law of Lambert Beer. I guess not but it's an example of the many very difficult question which can be asked, going deeper into what actually happens.
I wonder if a new photon is released, it will have a lower energy. That seems normal. However would there also be a rare process leading to the creation of photons with slightly higher energy?? How ? No idea, perhaps a collision of a CO2 molecule with two oxygens at once or so leading to the absorption of extra energy.
"If a new photon is released, it will have a lower energy". I've also idly wondered about whether there's partial gain and partial loss of vibration, but not enough to study and I've not come across anything definitive reliable.
Meanwhile I looked further and "elastic collisions" (wikipedia) seem possible in the molecular world. It's so much against our experience in the macro world that I have trouble believing it ;-) @@grindupBaker
Mad props to the Stanford encyclopedia of philosophy! It explains so much. Also, your videos are great.
Oh I loved the demonstrations and performances of the energy transfer in atmospheric heating. But... CO2 has two double bonds--that's the correct term?--while CH2 has two single bonds. So is methane behaving like H2O or like CO2 when methane is considered a greenhouse gas?
Not quite, what you showed would be Methylene (CH₂) which does not exist in nature. Methane is CH₄, four σ-sp³ single bonds. It is symmetric like carbon dioxide and therefore needs an induced dipole moment to absorb or remmit infrared radiation.
@@BioTechproject27 Thank you for correcting me and explaining the behavior I intended to ask! I must have had an un-caffeinated moment when I wrote CH2...
@@GeneShiau No worries, you made a funny carbon dioxide-water hybrid as it looked like :D (and technically methylene does exist and is a gas, it's just synthetic and unstable, so lucky points I guess?)
Something that should be also discussed and you already said it but not that clearly when the CO2 heats up the lower part of the atmosphere (CO2 is heavier than air) and by lower I mean about 10 km or so then the higher part of the atmosphere must get cooler. This is very important because the earth does not consume energy it always wants to stay in an equilibrium. The only thing that changes is the entropy! And this has already been proven but I can't find the article if someone knows it please share.
Are you suggesting that the total energy on Earth doesn't change? I doubt that because the stratosphere has a much lower mass than the troposphere, so the only way the total energy would remain equal is if the stratosphere decreased in temperature much more than the troposphere warms.
That explanation was very thorough but easy to understand. Thanks!
This is so interesting!! One question I still have is: why doesn't UV light play a role here? UV light has much more energy than infrared light, and so I'd think it's effect would be much greater. Is it just that CO2 can't interact at all with UV light? Are there are compounds that do?
In order to be absorbed, the energy of the photon has to precisely match the energy gap between two different states in the molecule. A UV photon has the amount of energy needed to excite an electron to a different orbital in CO2 (or any other molecule). The effect of that electron excitation would be to make the molecule less stable and more reactive, but its impact on vibrational frequencies (and therefore temperature) is usually negligible. In contrast, an IR photon does not have enough energy to excite an electron, but can excite a vibrational transition because the energy gaps between vibrational states are smaller. In other words, although the IR photon has less energy, it has the exact right amount of energy needed to change the kinetic energy of CO2.
Check out 3:30 in the video to see this acted out :)
@@paigehall2667 Ok, I think I sort of get it! Thanks so much for explaining this! 🙂I've been confused about this for a while haha. So can UV light heat up any molecules, or not? Like when you're standing outside in the sun, is the heat you feel from only infrared light or also visible and UV?
O3 (ozone layer) interact with UV light at 100 000 feet
So UV light is heavily absorbed because it would damage all leaving things on the ground.
An even better question to ask is why can't these climaphobics do an apples-to-apples lab experiment whereby they add 1.4 parts CO2 to 10,000 parts (total atmosphere) and show any measurable rise in temperature.
@@YourInvestmentAdvise Did you know that 99.8 of air is DIATOMIC molecules like N2, O2 and Ar BUT else is more than 2 atoms like CO2, H2O, CH4, N2O etc
And you know that ONLY with more than 2 stops infrared radiation back to space, so when you have more GHG like those above you get slower cooling of the planet so it get hotter.
Also just if something is so small doesn't mean it can't have huge effect like poisons etc.
What percentage of the time does it reemit the photon? I thought that this was a mechanism for scattering infrared radiation.
Thanks well explained
well understood
The last 50 seconds had my brain vibrating like a CO2 molecule hit by a photon thaks!
I like the way you teach vibrational rotational IR . Thanku for educating this universe. And salute for vedio editing skills. Thanku for every single infographics..
Watching from india 🇮🇳
I love the jump cuts, they're sooo clean :D
Man, this was, by far, THE BEST explanation have I ever seen about why temperature is increasing on Earth and what role CO2 plays in tha game. Thanks a lot for that!
Sound BS to me, the part at 10mins in, look again.
@@engjds Sounds BS? How do know?
Where did you study physical chemistry?
@@MrRadbadger you first?
@@engjds You're the one refuting the science and the presentation so you need to explain how it's wrong. Why would I go first if I don't see that there's nothing wrong?
@@MrRadbadger Here is an analogy:
Cary eats some of the cake, passes some of the cake to Orwell, Orwell then eats some of the cake and passes some back to Cary, who then eats more of the cake before passing some back to Orwell, does the quantity of cake increase or decrease?
Nice, brings back memories. Physical chemistry was the end of many students at our faculty, but is the most interesting (opinions will differ ^^).
So basically CO2 acts like a kind of randomised windmill. Could this effect be used to harness kinetic energy and generate electricity by channeling or focusing that energy?
CO2 is already causing massive cyclones in the atmosphere (Coriolis effect??) and jetstreams in the upper atmosphere, so we know that it works on the large scale.
Can we make it work on a micro scale? Greenhouses work to heat up horticulture. Can we harness the effect for electricity generation?
Great content! Now explore, explain and suggest what this means for temps rising at the Earth's SURFACE. Because that IS the concern and CO2 absorbing light in the atmosphere doesn't completely explain how temps at the surface are rising.
No. There's a required Part 2 that's absent from this video. Part 2 is MANUFACTURE in the air. This is Part 1 which is only ABSORPTION in the air. Hint: Presenter never states the phrase "tropospheric temperature lapse rate" (but it's ESSENTIAL).
You have described how stuff heats up genius, Now explain all the thermodynamic laws that describe If it heats up or cools down.
Good description. Now address balancing energy received from the sun to that radiates into space.
Enjoyed...got new ideas 💡
soooo, can we extract that energy?
That was an excellent video wity an intuitive explination which changed my view of reality as I understand it! It is a lot like filling windows with varying sizes of molecules so their ability to transmit heat is diminished due to mass, and velocity transfer inefficiencies.
Really awesome video
thank you so much for this video
What would be the perfect percentage of co2 in the atmosphere? What was the percentage of co2 100 and 1000 years ago?
The greenhouse effect is a positive not a negative.
Love this channel!!! Great work guys!
My notifications didn’t go off for this vid
Thish is amazing contact 🎉🎉 thank you 🎉 i am from India
Yes indeed the video was fantastic .
Really underrated channel. Great explanation!
As stated in the video, water is a more potent greenhouse gas. But I assume the slight heating caused by CO2 would also cause more water to evaporate (since warmer air can hold more water). How do these two relate?
That's exactly right. Increased water vapor in the atmosphere is a consequence of warming. For every 1° C of warming the amount of atmospheric water vapor increases by up to 7%, which in turn increases the amount of IR radiation that gets converted to kinetic energy in the atmosphere.
Yes water generally is more of an accelerator, as it can be found in the three basic phases.
When carbon dioxide generally absorbs more IR, this in turn reduces the amount of energy that leaves the planet through radiation, causing more water to evaporate, which also reduces the amount of energy that leaves the planet through radiation.
On the other hand, when carbon dioxide levels fall, more water can condense (thus less is there to absorb leaving radiation) or even freeze and actively reflect sunlight.
Do does that mean that the radiation or radiant energy radiated by Sun towards the earth is a photon? Basically is radiation = all photons?
How hard is it to separate carbon and oxygen from CO2?
Pretty hard, not even plants can do it: the oxygen they release comes from water, and in glucose (which plants turn into cellulose) there's still some oxygen. Once you have sugar, you can release the carbon by adding concentrated sulphuric acid (don't try at home, I guess).
Therefore, if CO2 releases infrared photons then it is possible to see CO2 say in a forest?
Does night vision work near a forest?
Infrared is a pretty wide band, nightvision goggles can't detect it (given how you can't see anything that's warm)
But some infrared cameras do. Although usually everything else gives off more radiation.
@@BioTechproject27 eventually someone has to assume the responsibility of the climate crisis narrative. I am happy to accept that everything else gives off more radiation... but then how does it work with the global warming claim from the manmade CO2 (literally 0,01% of the earths Atmosphere)!?
5:18 N2 and O2 6:19 electric field dipole moment 10:00 CO2 as a conduit
Why is the Venusian atmosphere at 1 bar at an equivalent temperature to Earth's at the surface after factoring in distance from the sun and the very high CO2 concentration?
Very high quality. Great explanation even when you dont dive deeper as you did with the schrödinger equation.
Great video and editing on point!
Except that most of the energy reaching the Earth is in the visible (non-greenhouse) spectrum and is absorbed by the ocean. Gasses, meanwhile get most of their heat from convection, not radiation. Radiation by greenhouse gasses is how most energy LEAVES the Earth.
The whole AGW theory is completely back-asswards. Non-greenhouse gasses trap heat absorbed through convection because they don't radiate (much) in the IR spectrum.
You've almost got it.
You correctly pointed out that the Earth, which includes the oceans, is mostly heated with visible light from the sun. What you are leaving out is that once heated, the Earth (and nearly everything else) sheds heat via the emission of IR photons. You can see this with night vision googles or measure it with an IR thermometer. Those emitted IR photons, rather than shooting straight out into space, end up colliding with greenhouse gas molecules in the atmosphere thereby warming it.
As you also correctly pointed out, excess heat is radiated out into space. Global warming happens when the number of IR photons entering the atmosphere via the Earth, exceed the number leaving the atmosphere via radiation into space.
Does that make sense?
@darkwingscooter9637 No the NET transfer is mostly evaporation latent heat, the LWR, then thermals convection-conduction. KT97 was ad hoc, Costas & Shine 2012 is from satellite and is 20 w/m**2 direct to space, not 40.
@@grindupBaker I suppose I should have been more specific in saying "non-greenhouse gasses" get most of their energy from convection-conduction. That's mostly by definition considering the phase diagrams and emissions spectra of of N2 and O2.
The general point is the confusion about greenhouse gasses as merely absorbing thermal radiation. They emit thermal radiation too, something that non-greenhouse gasses do not do (to the same extent).
We are happier with the longer shirt.
It doesn't trap heat. It just makes more of it?
The question is how does heat normally escape from earth?
CO2eq at 523PPM (2022 number) CO2eq is all greenhouse gases (except water vapor) normalized at CO2=1.
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Climate change is a fraud. Humans have only added 1.4 parts CO2 to 10,000 parts total atmosphere. Mythbusters had to add 523 times MORE CO2 in order to get the temperture to rise 0.9 degrees in their test chamber.
I'ld like to see more of those vibration options animations!
This is similar to Paul Beckwith's You Tube channel video where he reviews a paper "Heat stored in the Earth system (1960-2020): Where does the energy go?" on the EEI (Earth Energy Imbalance) that the earth has gained 0.48 W per square meter between 2006 to 2020. This extra energy is distributed thus: 89% to water, 5% to land, 4% to cryosphere and 2% to atmosphere. So the 21 trillion J per second increase over the US since 1750 is then distributed to the Ocean, land and cryoshere? I would assume so and heats the Oceans terribly.
Amazing!!!
Ok, how can we slow those molecules down again?
this was great