How DO Molecules Store Energy?
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- Опубликовано: 4 июл 2024
- Chemistry text books say molecules like glucose store energy in bonds. Are they wrong? What even is chemical energy anyway? And what ARE chemical bonds? And are they JUST abstract concepts? Are Derek Muller from @veritasium and Nick Lucid from @scienceasylum correct when they say bonds don’t store energy? We look at the science and chemistry of molecular energy and answer the question: Where do molecules store their energy?
Kyushu University is one of Japan’s top universities. Check out the link to learn about our science and engineering courses in English: www.eng.kyushu-u.ac.jp/e/u_in...
Derek Muller’s video about chemical bonds and energy: • Bonds DON'T Store Ener...
Nick Lucid’s video about chemical bonds and energy: • Bonds Do NOT Have Energy!
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Three Twentysix Project Leader: Dr Andrew Robertson
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This video was produced at Kyushu University and supported by JSPS KAKENHI Grant Number JP21K02904. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author and do not necessarily reflect the views of Kyushu University, JSPS or MEXT. 
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criminally underrated channel
Agreed
I like his videos which go in depth with explanations, but simplifies them enough for those with basic chemistry knowledge. I hate how some channels act as the viewers know nothing.
Ya
Nice pepe also yes
I just got my bachelors in chemistry. You have by far the highest quality chemistry-information related content on youtube. Your explanations always amaze me. You seem to have such a deep knowledge in so complex topics.
@AIraper i found your next victim
Im thinking of getting a bachelors chemistry, how was it? What are you doing for work now?
@@xxCeCexx14 Biochemistry Major. Have done a couple of Chem courses. Chemistry is fun, the only area of Chemistry that I had challenges with was *Physical Chemistry*
@@xxCeCexx14I am not working yet, in my country opportunities are very limited. I will be starting my masters in September and then I will leave abroad. If you are just trying to do the bare minimum and just pass the courses with low grades, you are not going to face severe difficulties. If you are trying to get good grades though, just like I did, good luck with that. It is going to be really difficult. Labs sometimes are graded based on your yield (in synthetic labs) or your error (in analytical labs). This makes it almost impossible to get good or perfect grades consistently.
In subjects such as biochemistry we needed to know the whole metabolism by heart. They would ask us for example in the finals, if an aminoacid would be radioactive after giving radioactive CO2 to a plant and to name the radioactive carbon of said aminoacid. Madness.
My program was 4 years in duration. During the final year I had to do lab work everyday for my thesis. Since I chose OChem it would usually take me 5-7 hours of lab work daily, without accounting for the courses that I had each day. I would go to the uni for at least 6-8 hours each day, some times even 10+, for the whole last year. It burnt me out.
@@xxCeCexx14not the og commenter but I’m currently doing a chem degree and it’s awesome and fascinating!! A few people I know who graduated with just a bachelor’s now work in the polymer industry, and one person ik who had a bachelor’s in biochemistry worked on genetically engineering fruit using CRISPR. I personally plan on continuing to grad school. There are a ton of areas of chemistry so really you could probably find a way to apply it to any interest!!
1:06 "chubby wittle kitty" is a wild choice for this illustration
*Well done young man!* Carbon dioxide is actually able to release energy if you react it with magnesium metal after ignition. 2Mg + CO2 --> 2MgO + C The loosely held electrons in Mg end up back in the carbon atom or rather between carbon atoms. *The energy is stored in the potential for this rearrangement.* MgO is quite stable and it would of course take lots more energy to move the electrons from O= back to the Mg++. *Mg++ and O= are held tightly by ionic bonding* in a lattice.
It basically boils down to (1) the difference in electonegativity (EN) between atoms and (2) how many electrons are "shared" between the atoms. Since oxygen has the 2nd highest EN, it always favors those atoms with the lowest EN since these atoms beg to give their valence electrons away.
In case of your example above, in CO2 one O-atom "shares" 2 electrons with the C-atom as it is the same within MgO. But since Mg has an EN of 1.2 and C "only" 2.5, Mg can easily reduce CO2 to C by stripping away the 2 O-atoms. While CO2 is held together by polar covalent bonds, MgO is already an ionic bond which is much stronger than the covalent bond.
Actually MgO can also release energy on reaction with acid like HCl
Excellent very clear and deep.
Too many scientific “experts” get a RUclips following by being contrarian and making scientific arguments against commonly held explanations. But they don’t quite get to the full explanation because they lack the depth of understanding for all the topics they cover.
Three twenty six has a deep understanding of its subject and explains it clearly.
Clearly, or with greater clarity? Apologies for niggling, but I think the good doctor is trying to make this point.
@@brucegoodwin634 same thing, mr nitpicker
Hi Andrew,
I am also a chemist here in Brazil, conducting my research using computational chemistry. I’d like to congratulate you on the excellent content you’re creating. Your videos are not only entertaining but also retain the interesting details that make chemistry so fascinating. The presentations are very well balanced (see what I did there?) and are useful even for more experienced chemists.
Whenever I watch such quality videos, I am reminded of why I love this field so much.
Thank you.
To be honest, I think the part at 17:45 - that students end up so confused by the "paradox" of why carbon dioxide and water release energy as they form their bonds, rather than absorbing it - summarizes why "energy is stored in bonds" is such a misleading shorthand. (And don't get me started about similar energy misconceptions when you don't realize kinetic energy is relative to frame of reference in physics!)
But I appreciate the video - even if peoples' confusions are ultimately more about semantics, each non-contradictory viewpoint on the same thing should improve understanding.
basically, when it becomes co2 and h2o the atoms sit closer together than when it was glucose and o2 and that's where the difference in energy come from. I think that is explained very nicely in this channel's video on activation energy? (but just to be safe I recommend watching them all)
We simplify when we teach because it's easier, not necessarily better. Students become empowered because they know the teachings, not necessarily the application of said theories
@@issholland I'm no expert in didactics, but surely there's a retort here on the value of an informed citizenship capable of distinguishing between populist BS and truth.
my words exactly
He is back with another banger
agree
Yes. I want to know more about energy and molecules. Somehow I seem to understand your explanations better than those of Veritasium and that Asylum guy and all the others.
They're more concerned with fluff for views. I ditched "Veritasium" a long time ago, and the ward is amusing and all, but... nah
"and that Asylum guy" haha
The last few minutes of this video explain really well why I watch this channel to begin with! We all need accurate models in our head to understand the world. If you're a chemist this is obviously important for your career. I'm just a huge chemistry nerd and getting this kind of detailed and accurate information on the nature of chemistry is just SO entertaining and fun!
Thanks for another great video!
The best explanation. Even a physicist need to visit this channel for a deeper explanation because chemistry is really a whole complete branch of science on it's own.
I really love the dynamic of this video. Also super informative
Your content is exceptionally clear and invaluable! It's so rare to find on RUclips.
You answer every question that textbooks simply gloss over and don’t even bother to explain it really helps to understand what you’re doing. But I have a question, where does that lost potential energy, that turns into kinetic end up? Who absorbs it? Is it radiated, or converted into heat, or vibrations, etc or does something else happen?
Probably heat. Not an expert but lost every turning into heat is like always the answer. That's also why we can't have nice things like perpetuum mobile. I might be wrong here so wait or search for a better explanation if you want.
Infrared radiation is what much of energy turns into. A collection of infrared photons has a high probability of being produced by many physical processes.
An equilibrium state of photons including those of the infrared radiation exists in blackbody radiation. The scientific study of the spectrum of this radiation emanating from an oven in Berlin ushered in the quantum.
Love love love your presentations. ❤🖤💛💙💜 More more more please.
Your simplicity in explanation indicates the vastness of knowledge you have sir... Keep making good content like there sir
Straight to the point, highly informative, well detailed, lovely animations and images for reference, and most importantly no annoying background music that enhance distractions.
Thank you sir!
So - I’m working on an important theory, and I think it reveals a lot about our understanding on the fundamental nature of energy.
Like you said and correct me if I’m wrong - the potential energy is from the movement of electrons and the magnetic fields generated in quantum mechanics. Doesn’t that suggest we should move away from our ancient thermodynamic roots and into a new age of energy definition related to the discoveries of electrochemistry?
“Heat” no longer applies, and I argue this perspective has insisted that our bodies move directly from the heat energy of the bond breaking - but what if that “heat” is just a side effect of nature.
Muscles can’t move without the catalyst ATPace, and the hydrolysis of ATP happens in the catalyst and away from the power stroke - but what if the catalyst was there to rearrange the ADP and P and connect them to specific regions of the myosin, creating the proper electronegative environment to turn the molecular gears and levers from same electromagnetic potential that you said energy came from to begin with.
I think it’s the only thing that makes sense, and why calories aren’t a reliable scientific model or theory - because they aren’t proven or actual reality, they are just a metaphor of the fire element that breathes life into life (ancient explanations)
Edit: clarity
The question of how much energy is stored is only defined relative to some lower floor. With gravity, it is answered by how much the object hasn’t fallen, but still can. It’s stored in its relationship to the floor,not the chair in isolation. So in chemistry, would the stored energy be in the bonds the atoms have not yet made, but could?
Im fascinated by everything to do with these concepts.
The electrons themselves having momentum and the field from which they emerge.
Thank you for helping me to visualize these ideas on slightly different scales.
Very helpful!
Great channel. Keep yourself well and please do not stop making videos.
This channel will grow, the topics are interesting and research done on them is deep, great work!
"Why did the molecule break up with the atom? Because it was tired of storing all the energy in the relationship!"
😂😂😂 thx!
I recently finished chemistry at A level and will be doing it at university, these videos are great to watch.
Eugene K also has a really nice video demonstrating how to think about temperature as momentum stored in linear + angular momentum
Could you please give its link?
@@satyajeetbose2931 oops, I can't post a link? It is called "Molecular temperature and degrees of freedom"
@@aosidh Thank you🥰
I only recently learned the voice over isn't ai 😂
@@ElPsyKongroo it gives me so much admiration for that woman! Apparently a professional voice actor 🫡
I'm a high school physics teacher. I am always very gratified to see that my explanations are consistent with what I see here. Thank you!
I always liked deep understanding of chemistry and your channel is exactly what I need!! ❤
awesome video and one of my favorite channels! Thanks, Doc!
You are a great teacher ❤
Great video! I’d love to see one on bond hybridisation.
Thank Dr Andrew - I so much disliked basic chemistry as an undergrad. (I think it was the profs and the observation that the near-500 kids in the lecture hall were only there for pre-med, and all of them “collaborated on everything…)
I learned much later in my career that electrochemistry is critical to me understanding my engineering stuff.
chemically underrated channel
I love this explanation. That 2700 kJ/mol in decomposing glucose as a single step is enough to blow apart a cell's membranes. But it's done stepwise in little isomer changes and decarboxylation steps.
This video is a masterclass in good presentation. And I learned a lot too.
I've watched all your videos already, so this one felt like revision, but it was fun to watch while screaming "in the potential energy of the bonds!!!!". Yes I want to learn more about chemistry!!!!
Content aside, I give props to the animation and visuals in the video
Very well done. In the future This video will be played in many High School chemistry and physics classrooms.
another great video, thank you for the upload
Love your channel. I would like to understand this more and how energy can become matter, and how matter can become energy. Knowing this could help me visualize how we get energy from molecules more. Thanks.
Andrew, this is such a wonderful channel 👍. I am learning chemistry again with a different perspective at the age of 72. As a teenage medical student in the Seventies learning was about getting through and there was insufficient time to indulge ourselves in deep understanding unfortunately. Having a deep understanding is much more satisfying and now I have more time 😊. Thank you 👍.
In my day, energy was the capacity to do work. Nowadays you need a degree in philosophy to discuss energy
Hahahahaha
Absoultely yes! How boring video
What is work? What is capacity?
@@bingchilling4717 those questions require some good frosty binchilling to answer
Still is.
He said "elements which could move stuff" and at 1:14.
The video explains from where exactly the "potential to do work" comes.
We usually learn in a more "engineeringy" way. Here we learn about the physics involved.
Your videos are pretty good compared to the other chemistry related channels. You should do a longer video on material science, more specifically, graphene and carbon lattice structures and their potential properties.
I really like your content, are there any chemistry books/textbooks that explain these concepts exceptionally well?
This was a good one 👍 thanks
Awesome video!! Keep up the great work
Very well explained, cheers 👌
Thank you Dr. for this and other amazing explanations. I hope that you make a video of how one bond is influenced by whole molecule atoms.
Really well explained!
Do please more Videos about it
your way of speaking is very awesome
Oooo, I really felt the end of this video was begging for a dive into redox potential xD. Oh well, can't cover everything in one vid!
This is the first video where I didn't learn anything I think. But I do have a BSc+MSc in molecular life science, specialised in organic (and physical) chemistry. So that I learned something new in all your other videos says enough I think.
Nice video. Just wanted to add that every molecule has associated electron energy - this consists of all the the energy of core electrons and valence electrons. In chemical reactions the inner electrons dont change their energy state (or negligibly compared to valence electrons), so one can assume that only the valence electron potential energy plays a role. Now, we can see the total electronic energy as a whole but for us chemists its easier to see it as separate bonds between atoms - there is a mathematical way of converting MO into localized 2-centre bonds which gives same results. What changes during reaction are actually these bonds - they get redistributed, and we all know some bonds have “more energy” than others so if the newly formed bonds (electronic energy of valence electrons) is lower, so excess energy gets released. Now comes the question why are different bonds different in energy - its because in different nuclei rearrangements these electronsare in more stable state than other cases (C=O bond is stronger than O=O bond for example). So if some of this potenital energy is “lost” it is given in the surroundings in the form of work/heat etc. So if You have a molecule with a lot of high energy bonds, if properly triggered, these bonds rearrange in other bonds and excees energy is given off. So in some sense, this energy is stored in the bonds (or valence electrons).
Que vídeo incrível!! muito obrigado por proporcionar isso no youtube!! por favor, não pare!! abraços do Brasil.
always love your channel. Thanks for sharing you got my subscription and like as always.
Just a small correction for 14:25 - the box, when it hits the floor, hasn't lost all of its gravitational potential energy, it's only the amount it gained from when it was originally lifted from the floor - it still has all the gravitational potential energy to fall through to the centre of the earth if only the floor wasn't in the way.
Very insightful!!
Waiting for next video
Great video!
Please do catalyst design! 🙏
I was wondering for a long time why most elements release energy when a neutral atom gains an *extra* electron (a property called "electron affinity"). How can a neutral atom capture extra electron and keep it? Aren't charges supposed to equilibrate? So I dug down and learned that my simplistic imagination of atoms does not iclude the effect of polarization. I tried hard to imagine how could that work to the point of having it in my dreams - I like the lights up moment when it finally clicks. I was stuck on the idea of electrons orbiting nucleus fixed in space while in reality neither are fixed - even though the nucleus is so much heavier than its electron cloud, it's positive charge can be more or less displaced from the "center" - then I finally grabbed the concept of "dielectric constant" and lot of things started making much more sense...
Similarly, I though that electrons are spin-paired as if there was some kind of bond between them - but that's not case! I learned there is even something called "spin pairing energy" and indeed it may take a non-trivial energy to add a second electron to an s-orbital because one have to "flip" its spin in order to coexist in the same orbital (Wolfgang Pauli nodding...).
Here is one idea on video: Could you shine a light on bonding in the oxygen molecule? It is the prototypical molecule for explaining the molecular orbital theory and I was reading and re-reading the explanation of why oxygen is a diradical even in ground state (!) but didn't understood how it works (self-learning chemistry is sometimes tough and I get stuck on some topic -- I must say that AI models are a godsend because who has a personal mentor with PhD in chemistry...).
I would comment to that but you won't reply anyways so...
Learnt more in these videos than 4 yrs high school many yrs ago, BTW noticed the shirt change
You should do a video on super fluids!
thank you!
Great explanation
On energy storage, what about the comparison between single, double, and triple bonds?
I remember that nitrogen N2 triple bond can obtained after nitrogen-containing compounds react, sometimes explosively to produce nitrogen gas. Can it be said then the stronger triple bond actually contains less energy?
Yep. You need to put in a lot of energy to break those triple bonds because the molecule already is at a very low (stable) energy level.
Game Changing Channel 🙌🙌
very interesting content!
This channel should be much more popular then it is right now. Some channels are getting lot of subscriber and views with bunch of craps, where channel like these are not getting proper recognition.
This is great and the instructor's graphics and explanations are really superb. I think I am taking in too MUCH energy. Wouldn't it be great if he could come up with a way to help not breaking so many of those bonds so I could loose weight.
You look and talk like Werner Ziegler from Better Call Saul. Made this great, great video even better
"is energy stored in bonds"
Is like, with your box example,
"Is energy stored in the chair"
Outstanding ❤
I think the simplest way to explain "where is the energy?" is that energy is the potential to do stuff, and that potential is necessarily relative. The energy of molecules is their capacity to rearrange their atoms into arrangements that have less energy -- less potential to rearrange themselves -- and in doing so, they "release" energy. But that energy, of course, doesn't just disappear: it is transferred into something *else*, which then *gains* the potential to do stuff. That potential can then go on to be transferred further and further, often being converted into "heat," i.e. the movement of other molecules, or it's radiated away, or disperses in other ways, at which point we like to say the energy has been "lost." But it's not lost -- that energy is just not in a form useful to *us*.
Amazing video
Just watched a video by Cody’s Lab of him casting iron he smelted from Magnetite (Iron Oxide) and Aluminium using the Thermite reaction. Might be interesting to do a dive into the energetics of that, somewhat exothermic, reaction!
Energy is stored all over the atom or molecule. By definition a chemical reaction involves the breaking or forming of a chemical bond. So when you do chemistry on a compound and energy is released or absorbed , that energy came from the change in configuration(3d shape of the chemical species) , and that physical change in shape came mostly from the areas associated with the bonds. There is also energy exchange from configuration changes on a single molecule or atom that has been exited by radiation. So most of the energy on the atoms or molecules is stored on its electronic configuration. It is when you change the configuration of the electronic clouds that most of the chemistry happens. ls it also very important to understand the concept of "work'. Work is usable energy. Usable energy is what we can actually measure or use.
In the Krebs Cycle there are 20 plus cycles that build up energy. How does this work? Would you please do a lecture on this topic?
Thanks!
i want to ask that how can saltwater liquid with lower temperature have more kinetic energy than pure water ice at 0 degree Celsius?
I would like to draw attention to the end of this video. I am a chemistry major and 100% agree that these theoretical models are there us for to debate and visualize. The reaction mechanisms taught in organic chemistry might not be even true, maybe in reality something much different occurs but we try to explain these as best as we can.
I just stumbled upon your channel and hands-down one of the best science channels I have ever seen in a while. Thank you for the clean explanation and your efforts. Subscribed!
PS: Did you use Spartan program to do these visualizations?
Yes, it's Spartan. Shiny new 2024 version too!
Có 2 chọn lựa : 1 ) tương phản ánh sáng màu sắc ( cofee and nước )hay nhiệt độ ( muối và nước ) )như (nước và dầu) ( âm thanh và im lặng ) ( electron )
Please make video on catalyst design
I genuinely did not know that chemical energy was literally kinetic energy. I always thought that was a metaphor but no. It's literally the movement of particles. Wild
Yes: more please.
Nice job with tough content. Thank you. I’ll consume as much of this as you care to produce. 👍
I’ll jump topics now. (Forgive my lack of transitions…) I’m trying to grasp why we can’t reproduce and experiment with components on the scale of, say, 10 to 20 nanometers. I realize that’s a stupid question but I’d love the stupid answer if you get bored sometime. Obviously “it’s too small” is both accurate and too simple… I understand that we have a pretty good idea of how to model ATP synthase within photosynthesis. But I understand we have a long way to go to understand nitrogenase at the same level of detail…? (So I’m asking why we’re struggling so much…?)
My ignorance comes in part from thinking that we can study subatomic particles in an accelerator, so why can’t we do molecules? This is not a fair comparison, of course. But still it’s frustrating to me that I can’t just open a book and get the answer. Am I just looking in the wrong books, or is there really a gap in our knowledge about how protein chains “hold” a molecule of phosphate in order to push it into the end of an ADP? To ask the same question another way, why can’t we build an ADP synthase unit in a lab, mount it in a lipid, and then feed it phosphate molecules to assemble? What do we need to invent?
Interestingly, right after I posted this note, RUclips gave me a video that referred to the cloud chamber everybody was using in the 1910s and 1920s to bombard everything with x rays! Okay, I knew about the cloud chamber but I am assuming that’s not good enough to use with whole molecules… Is that right? What kind of cloud chamber do we need?
Also, the invention of the cloud chamber was good for a Nobel, but as I understand it, the tool was meant for studying weather phenomena, and it was an accident that it showed what it showed. I saw this in a James Burke BBC series called, “Connections.” What instrument do we need in order to “see” proteins in operation?
Please tell me we have the tool and we’re not waiting for another accident on Ben Nevis?!
Thank you Dr. Andrew
Subscribed and following
thank you for providing this high value content, that is well above some other elf-serving science-fluencers stuff ;)
Thanks
Love your videos.
Wow, absolutely no mention of the energy being photons absorbed and released by electrons.
I think....I love this channel
Love you man
More ENERGY please ❤
Keep it up gentleman 👏 👍
Did the box falling in the example really lose energy?
I thought it would have a normal force equal to gravity acting on it (chair) which sums to zero, so not lost but balanced. Great explanation thanks!
3 26 is Life, y got it
The functional groups doing chemical reactions is the source of redox energy
How do atoms know how to assemble themselves into different elements perfectly, again and again?
Energy itself is an abstract concept.
It's a useful concept for putting numbers to qualitative ideas, like pretty much everything in physics
no
Measurement of anything is inherently abstract, as there are still holes in our understanding of physics, particularly in smaller reference frames, due to the lack of a grand unifying theory between relativity and quantum mechanics. However, we can measure mass fairly reliably, and while mass *refers* to a clearly real thing, it may very well also be an emergent phenomena caused by something we don't understand yet, similar to gravity. All of our attempts to quantify properties of the universe are, while reliable, observations from an outsider's view.
Energy is quite difficult to define. I read a discussion among physicists and they basically landed on “energy is a bookkeeping method to describe a conserved and abstract state of a system”
The concept of energy helps us organize our empirical experiences in an ordered hierarchy so it somewhat "explains" why certain events can happen but others cannot (insufficient energy precludes a hypothetical event from happening).
I'm of Oma's school of "Viel Kuchen." Science is a collection of successful recipes. I pay homage to Grandma's Science if I get to "eat much cake." 😂
🎉🎉
"Think of molecules as tiny, over-caffeinated squirrels. They store energy like squirrels hoarding nuts. When they get excited (like after too much coffee), they release that energy in bursts, causing all sorts of reactions. So, molecules storing energy is basically nature's way of keeping these little squirrels busy until they need to unleash their energetic chaos!"
10:52 “He rightly says that making chemical bonds from _atoms_ results in a loss of potential energy.”