# The Most Realistic Fire Simulation Ever ## Метаданные - **Канал:** Two Minute Papers - **YouTube:** https://www.youtube.com/watch?v=B6GJjvR6txg - **Дата:** 19.02.2026 - **Длительность:** 11:38 - **Просмотры:** 53,300 ## Описание ❤️ Check out Weights & Biases and sign up for a free demo here: https://wandb.me/papers 📝 The paper is available here: https://helgewrede.github.io/firex/ Our Patreon if you wish to support us: https://www.patreon.com/TwoMinutePapers 🙏 We would like to thank our generous Patreon supporters who make Two Minute Papers possible: Adam Bridges, Benji Rabhan, B Shang, Cameron Navor, Christian Ahlin, Eric T, Fred R, Gordon Child, Juan Benet, Michael Tedder, Owen Skarpness, Richard Sundvall, Ryan Stankye, Steef, Taras Bobrovytsky, Tazaur Sagenclaw, Tybie Fitzhugh, Ueli Gallizzi My research: https://cg.tuwien.ac.at/~zsolnai/ ## Содержание ### [0:00](https://www.youtube.com/watch?v=B6GJjvR6txg) Segment 1 (00:00 - 05:00) Previous works have shown us that fire  simulation is possible. You can set a   virtual tree on fire and see what happens.   Or, on a bigger scale, simulating wildfires!   But what about extinguishing the  fire? Not like this. With water! Well, I found an amazing research  work on that too! Yoohoo! Now, there are different types of flames,   depending on what kind of chemical created  them. This incredible work models that too,   that is already stunning. But it’s  nothing compared to what it can do. So the main problem is that fire simulations  are like the ones in video games. It’s like a   plastic display burger in a restaurant  ad. It looks fine, until you touch it,   or if you throw a bucket of water on  it, nothing happens - the water just   clips right through it! This problem goes  way beyond games, such a thing could be   amazing for fire safety training too! You could  actually try to train firefighters by putting   out realistic fires in VR. But you can’t do  that if the fire is ignoring the water hose! So, how do we fix this? Well, this new research  work says just give it the geometry of the scene,   a fuel source, and a water source. And it  promises a chemically rigorous simulation   where the fire actually dies if you  starve it of oxygen or cool it down. Here is the crazy thing. You can even mix  different fuel types and fuel-oxygen ratios   and they create completely different kinds of  flames. How an Earth did they do that? Wow. And when we hit the fire with water, we finally  get some vapor! So cool. It’s really tough to   put out though, look, even if you aim at  the base… it didn’t do a great deal. Why? Because a laminar flow is essentially a solid  beam of water with minimal surface area,   which limits its ability to  absorb heat from the flames. Now let’s try a proper spray instead. Does this  work better? Oh my, you bet it does! Why exactly? This works beautifully because breaking  the water into thousands of tiny droplets   increases the surface area for heat absorption.   This cools the area down instantly while, look,   the huge expanding steam suffocates the fire. Now this is a virtual world, so we  can try funny things. You often hear   the term adding fuel to the fire. So  why not do that? Oh wow, look at that! Now note that the visuals are not the  state of the art. I need to mention that   simulation and visualization are different  disciplines. The true treasure here is the   accurate chemistry simulated under  the hood, and not the pretty pixels. Now it advects the fire, and also starts scorching  this wall next to it. Look closely at how the wall   darkens over time - this is not just some  pre-computed color being slapped on it! The   simulation actually tracks the formation of soot  during incomplete combustion and even deposits   them onto the object's surface. It simulates the  environment having a memory of being burned. Wow. Now, real life firefighting gets so much  more intricate than these toy examples,   so let’s put it to the real test. Can it simulate  this? Okay, wait, so what is happening here?    This is a brilliant application of the Venturi  effect. They are spraying water not into the   window. But out of the window, that is the key.   Why? Well, if you do that at a high speed, you   lower the air pressure there, which essentially  vacuums the smoke and heat out of the room. It is like a massive truck speeding  down a highway. This creates a gust   of wind that pulls dry leaves behind it. The simulator cannot possibly be so  smart to understand this right? Let’s   see…I can’t believe my eyes. This is incredible! Now one other detail that completely blew  me away is the annealing simulation. Here   they heat up a metal rod, and when the  flame is removed, the rod stays glowing   and slowly cools down. It even creates  its own light source! This wasn't even   the main point of the paper, but it adds  so much realism. I absolutely love this. Okay, now, the two final boss scenes,  and then I’ll tell you how it works. Boss level 1. Three cars burning with massive  flames. Yes! Finally! This puts it all together.    This is a multiphase experiment. This is a  fancy way of saying that the Holy Trinity ### [5:00](https://www.youtube.com/watch?v=B6GJjvR6txg&t=300s) Segment 2 (05:00 - 10:00) of physics states are all fighting each other:  solids, liquids and gases. All at the same time. You see that this is not just deleting the  fire. The liquid water hits the hot gas,   absorbs the heat, and transforms into white  steam that mixes with the black smoke. It is a chaotic, beautiful mess of  thermodynamics! The water fights the fire,   the fire fights the air, and  the steam fights for space.    The simulation is calculating the chemistry  of extinction. And now hold on to your papers   Fellow Scholars, because all this happens  in real-time. Yup. I am out of words. Now let’s demonstrate how this  kind of knowledge can save lives. Here we have a kitchen fire starting on a  stove. We activate the sprinkler with just   a tiny bit of delay. A tiny bit. And look. Oh  goodness! The fire grows, climbs the walls,   eats the ceiling, and fills the whole room with  thick, black smoke. It is a total disaster. Now a simulation technique like this can help us  imagine a what if scenario. What if we activated   the sprinkler just a bit earlier? Probably  doesn’t matter right? Well, hold on to your   papers Fellow Scholars, yes, again, and look at  the difference! In the second timeline, the water   spray cools the reaction instantly. You see the  fire turn into a puff of white vapor and die out. This proves why this isn't just a toy for  making video games look cool. No! This is   a virtual safety lab. Don’t forget,  this is accurate and fast. With this,   we can test millions of what if scenarios  - different sprinkler positions,   different delays and fuels. All this without  ever having to burn down a single house. Okay, so how is all this magic possible?   How did they do that? Dear Fellow Scholars,   this is Two Minute Papers  with Dr. Károly Zsolnai-Fehér. Well, first of all, this doesn’t use any AI  whatsoever. Only human brilliance. Okay. The   reason previous techniques failed is that fire  and water in a computer speak two completely   different languages. The fire lives on  a grid - imagine a giant 3D spreadsheet   of boxes that calculates airflow and  temperature. But the water…the water   lives as particles - like millions of tiny sand  grains floating freely. In older simulations,   these two worlds couldn't talk to each other  fast enough, so the water particles would just   fly through the fire grid like ghosts. To fix  this, these amazing scientists built a high-speed   translator that sits between these two worlds  and forces them to interact. That is brilliant. Okay, so why is that important? Well, here  comes the magic. Because of this new translator,   the water and fire can finally speak to  each other. When a droplet hits a hot spot,   it demands some heat from the fire,  and because they are connected,   the fire has to give it up. The water  uses that stolen heat to turn into steam. This creates a chain reaction where the fire  cools down, and the new steam crowds the room,   pushing the oxygen away to suffocate the  flames. And now all of these speak the same   language. The water can finally extinguish  the fire instead of just passing through it. But that’s not all. Not even close. Under the  hood, the simulation uses a famous mathematical   formula called the Arrhenius equation to control  the fire. Think of this as the fire's gas pedal.    It calculates exactly how fast the fuel should  burn based on the current heat and the available   oxygen. Because this equation is super sensitive  to temperature, even a small splash of water that   lowers the heat causes the math to slam on the  brakes, instantly stopping the chemical reaction.    So, the fire physically stops burning  simply because the math says it is too cold. Now, surprisingly, there is so much more to learn  here. Not just about simulation techniques, but   about life itself. You see, the simulation proves  that a solid beam of water fails, but a spray   succeeds because it maximizes contact area. That  is great life advice! Sometimes you don’t need to   solve a crisis with one huge heroic effort. Break  the solution down into many tiny droplets. Tiny   little tasks. You might find that they absorb  the heat of the problem much better. So good. Also, remember, the paper simulates the kitchen  disaster before it happens. You can do that too! ### [10:00](https://www.youtube.com/watch?v=B6GJjvR6txg&t=600s) Segment 3 (10:00 - 11:00) Imagine yourself in the future and imagine  that your friendships, marriage or career   has already failed. Now the question is, if  it failed, why did it fail? Work backwards to   find the cause. Then, like the sprinkler, you  can fix the problem before it even happens. Okay, with all that said, let’s not  overstate things. Yup, not even this   technique is perfect. The authors note that  the solids in the simulation are static. The   geometry has to be fixed, so that’s why you  are seeing simulations with lots of metal,   and not elastic trees burning. I think that  is an acceptable tradeoff. But of course,   here we invoke the First Law of Papers, which says  that research is a process. Do not look at where   we are, look at where we will be two more papers  down the line. And in two more papers, baby,   I am sure this is going to simulate an entire  city. Now that would be incredible. And super   useful too. Subscribe, hit the bell and leave  a kind comment if you enjoyed this. Thank you! --- *Источник: https://ekstraktznaniy.ru/video/11381*