Watercooling Loop Order... Does it REALLY matter?? Here's Proof

Hi Jay, physics major here. First of all, thank you for actually conducting the experiment. I don't doubt your results, but I have to correct you on your explanation. You seemed to be suggesting that there's a fundamental law of thermodynamics that implies loop order shouldn't matter. There isn't. In fact, the basic argument in favor of loop order mattering makes sense, though it depends on several parameters whose effects are hard to quantify.
It is absolutely true that as the coolant fluid passes through a component which introduces heat into the loop, the fluid will get warmer and be less effective at cooling the next component it comes into contact with (and the opposite is true for fluid that passes through a component which extracts heat). The only question here is the effect size. That is to say, "will the difference actually be noticeable?"
As you've shown here, the difference isn't noticeable, but it's not due to the laws of thermodynamics. It's due to the fact that the coolant fluid is passing through components quickly enough that the exchange of heat doesn't cause the temperature of the fluid at any specific location to deviate much from the average coolant temperature (though it does still deviate by some small amount). If the coolant were to be pumped through the tubes slowly enough that the exchange of heat resulted in a sizable change in coolant temperature, the difference in loop order would be noticeable.
Bottom line is that the combination of fluid dynamics and thermodynamics required to fully understand cooling solutions is not at all trivial, even for people who understand physics, let alone armchair physicists who try to make proclamations without actually doing experiments. The fact that you actually did the experiment is more helpful toward answering this question than my physics degree.

When I was building my custom loop PC I used to lie in bed thinking about different loop orders to send myself to sleep. True story. Not sad at all.

Being someone thats about to do his first loop this saved me a massive headache thank you.

*our bodies are water cooled and no one moans about the order of that*

When your psu is so powerful it doesn't spin under load 😂

You guys are badass. I search every question I have about PC building and your videos always pop up with answers presented in an entertaining way.

Jay with the Linus ad transition

I have run multiple loops in different configurations. Bottom line, it does matter, but not the way you think. No matter what order I ran, CPU temp never varied more then +/-4 degrees Celsius.
What DOES matter is running the cooled water into your pump first! This is the main source of cooling for your pump. This can GREATLY extend pump life. I have seen pumps fail in less than 6 months because of this.

To be honest, I'd love to have the differences in running parallel vs serial(like when you have more then one graphics card) explained/tested and why you might go with one over the other.

This was a great video. Being a car mechanic myself I've always wondered how a water cooling loop on a computer would be different compare to a car. I know the temperatures on a car are more extreme, but the same concept still applies. Great video here!

those quick disconnect things are cool

Now THIS is a JayzTwoCents video, wooo!

Thanks for dispelling another myth that people seem to never understand Jay. Nice work! Keep schooling the noobs!

0:56 Okay Linus, thanks for the uncanny transition from your topic into a sponsor xd

I appreciate this a lot. I'm slowly expanding my loop and I'm wanting to add the GPU block without adding a second radiator temporarily. It will only be a couple of weeks and I don't really game or do any major overclocking anyway. My loop is purely for aesthetics. I just get the bonus of lower temps.

Love your content, Jay. What I really like is that it is always helpful & informational (instead of just trying to be funny, showboating, etc.). Over time yours has become my favorite tech/hardware channel. Specifically, your videos were super helpful as I was getting started with water cooling. Thanks for all you do!

wow those GPU temps are really impressive . I know it's not in a closed case but nonetheless . One day I will maybe do it . Good work Jay

Do parallel loop testing!

Still one of my favorite videos, and I share it with friends whenever they ask me questions about how to determine loop order or how I determined my loop order lol.

Getting your computer temps in Celsius and your ambient in Fahrenheit .. NICE!

I wanna see a loop with a rad before and after cpu,thus having a rad for each component in a single loop. Just for comparison.

A better experiment would have used two machines and two loops, each loop with one GPU and one CPU from each system. That way you can put load on one system and leave the other completely idle, and see how much each component in the idle machine increases in temp. If one increases more than the other, your claim is false. If they both increase by about the same amount, then your claim is true.

at normal pressure:
0°C: Water starts to freeze.
100°C: Water starts to boil.
1°C difference is 1 Kelvin difference. Very easy if you compare it to fahrenheit ;)

Don't know much about physics, but that part about the radiator being the cooling part of the loop is what made this whole thing make sense before he went to demonstrate it empirically

It's literally thermodynamics, specifically the Zeroth Law of Thermodynamics, which is if two systems are each in thermal equilibrium with a third, they are also in thermal equilibrium with each other.
At the end of the day, physically, the loop order literally does not matter. As Jay said, having the reservoir feed the pump, and having a radiator with enough thermal mass to dissipate the heat, will ensure that the system will find thermal equilibrium at idle and load.
It's simple and demonstrable physics. Great video, Jay!

It is called Equilibrium.

"You know what does matter? Protecting your internet experience!"
Wow he's really turning into Linus

I had thermal sensors in my loop back when I had a loop. Going through two GPUs and the CPU raised water temperature by 3 degrees under heavy load. It was good proof that in a loop with proper flow, the water doesn't heat up significantly at each block.

You are absolutely correct. As long as the loop is flowing, it WILL cool everything. The fluid will not be there liong enough to really heat up is the radiator is working.

I was wondering about this. Very helpful to know order does not in fact matter (working toward first water cooled)

You learned a lot from Linus, especially the way of introducing a sponsor

Thanks for this, I’ve never even thought about this but I’m new to the pc building community and it’s nice to pick up the right knowledge and useful tips straight away

I've done tests with loop order with a 2600k and a HD 5970.
the GPU being first or last didn't make any difference.
and an overclocked 5970 is possibly the HOTTEST GPU ever made.

The Celsius scale is very easy to navigate, Jay: 0 deg. - water freezes, 100 deg. - water is boiling. This is convenient for figurative perception. But on the Fahrenheit scale it is already difficult, so I have never seen either frozen or boiling alcohol in my life. 🤔🧐🙂

This maybe the best jayz vid I've seen. Learned a lot here. Thanks.

I don't think Jay recognizes the magnitude of the pun he made when he said "it's *cool* and all".

What would be more interesting to know is the difference that radiator fan orientations can make in a case. For example if a front intake radiator feeds hot air to an exhaust top radiator, compared to both radiators blowing air in or out. Practically all Jay's builds I've seen have one radiator pushing hot air to another, which I've heard actually makes a noticeable difference in overall water temperature. Would love to see more tests on this.

Jay remember this. Room temp usually 72°F ~ 22°C
Great vid comparison with data. Thanks!
Hope this helps. Cheers*
*added tip: °C=(°Fx2)+28 Little trick to do in head and is pretty accurate. I know ppl, correct formula is C=(Fx1.8)+32, but multiplying 1.8 in head is something "don't wanna think about" even though can do, lol.

Infrared imaging camera can provide a pretty nifty visual representation of where the hot spots are in various setups.

Agreed.Thermal gradient in most liquids is minimal so steady state temps are what matter. This is dictated mostly by the cooling performance of the radiator.There is a prerequisite. You need sufficient rate of flow to push the fluid around the loop for the rad to do it’s job.Then the sequence, (to all intents and purposes), does not matter.

0:56 doing it the cool linus way !
=)

Loop order
>implying each component in my rig doesnt have a 360mm rad

insta-liked for the smugface in the thumbnail!

I´m sorry Jay, as much as I like you, as an energy and thermals profesional, I really think you´re partially wrong on this one, but it is all about context and math.
In summary, by doing a CPU-GPU in series loop you´re just decreasing the 2nd component cooling efficiency, just because the conduction-forced convection heat transfer rate is directly proportional to the temperature delta between the cooling fluid and the heat exchanger(block). By even adding a fraction of a degree to the fluid from the first component, you´re directly decreasing the fluid-2nd component temperature delta, which decreases the heat transfer rate efficiency by the same proportion.
Now, it is imperative to state the coolant has a masive heat capacity itself, it is capable of absorbing masive amounts of energy as heat every second 4.186J/g°C for destiled water for example which is the second best heat capacitor just under Amonia (4.6-7 J/g°C), enough to get the job done by far margin.
Lets take the Ryzen 7 5800x as an example, with 105W of TDP, meaning it can deliver up to 105 Joules of heat every second. With such TDP, you´ll at least need around 25g of coolant every second (0.03L/sec) to incrase the coolant temperature more than 1 degree, and since water loops should be no less than 120L/H (0.03L/s,33.3g/sec) flow/mass rate, we gotta say the coolant fluid itself gives a lot of room to play between order and pump head/flow rate configurations.
Having said that, again, topic goes back to its usual genesys, use cases and budget; for the vast majority, the coolant heat capacity will get the job done by itself regardless of the configuration, since they wont be squeezing power to its limits, but for those who need max power for long lasting periods of time and longevity, parallel loops (ideally redundant) grant the highest cooling effiency overall since the requirement is to have the biggest temperature deltas between coolant/components, the highest flow rate and least head resistance through the system.
And since we´re talking about budget now, even a sub-ambient temperature and dew point asymptote gradient cooling system should be worth the investment for the one who really REALLY needs it.
At the end, limits are defined, Ambient temperature, dew point function and TDps; everything else such as system configurations is up to how creative we can get.

Drinking game of death : take a shot every time Jay says CPU or GPU

OCCT is rendering the Graphs @JayzTwoCents
Thats the spiking

I understand loop order in a single rad setup does not matter however, it follows the laws of thermodynamics to come to the conclusion a greater temperature difference will increase the cooling effect. (More heat can be dissipated with a larger temperature differential). This is because there are two heat generators (A B) and one heat dissipation element (C). No matter how you order these ABC, ACB, BAC, BCA, CAB, CBA hot water from one component will flow into the radiator be cooled then be warmed by another component which then flows to the first component again.
The following assumptions apply (CPU is 80deg C, GPU is 60deg C, ambient is 20deg C, at all times, heat dissipation causes temperatures to balance in exactly the center of the two temperatures eg 60 deg coolant with 20 deg ambient through rad => 40 deg coolant as a result ). What may be interesting to test is the following:
CPU, RAD, GPU, RAD vs CPU, GPU, RAD, RAD.
In the latter setup the CPU may heat the coolant up to 50 deg C, that then flows to the GPU where the coolant balances between 50deg (coolant) and 60deg (gpu) at 55 deg. This coolant then passes through two rads to reach back down to 20deg.
VS
In the former however, the coolant cools the CPU down to 50deg (20deg, vs 80deg) then passes through rad to become 35deg (20deg vs 50deg). The coolant then flows to the GPU and cools the GPU to 47.5 deg (35deg vs 60deg). The coolant finally passes through the final rad and reduces to 33.75deg this then repeats until the coolant settles at ~34.5deg with the same effect. This means the former setup reduces the temperature of the GPU by over 7deg. A considerable amount (~15%) difference

I'm here from the future, Jay... and NordVPN is a no go!

If using 2 Radiators, there will probably be a difference where you place them Res>GPU>Rad>CPU>Rad is one of the best options i guess...
If you put the radiators after each other the last component wil be warmer, if you split the rads you basicly have somewhat 2loops in the same loop...

With only 1 small radiator u are correct. With 2 big and a high end setup I bet the sound would come down if mounted correctly. And vice versa.

Private internet access vs Nord VPN ? I can't decide .

I totally agree with you on this Jay. I got a Core P5 and my loop runs from my CPU to GPU to Pump to Rad. I have zero issues with heat, period. Loop order does NOT matter. 6600k delided @ 4.8 GHz (1.3975 V) running 60°C max and Strix 1080TI O8G oc'ed further running max temps of 44°C.
Thanks for all you do. Your the Real Tech Jesus....

What about multi rad setups? gpu -> Rad ->cpu ->rad -> pump/resivior ->gpu

Thanks for this, my take away lesson is to strategize tube trajectory to avoid bends as much as possible whether it be from CPU to GPU or vice versa.. Removes a little stress!

Very valuable info - even 4 years later. I have always said the same thing, order doesn't matter. But I had no stats to back that up (I am an engineer - I knew I was right without stats). This is a very good confirmation that I will share with the haters that occasionally cross my path.

Thanks for the vid Jay! Can you do a video on whether running a loop in parallel is no worse than in serial as long as flow is ok? So I have something to send people when the say my loop sucks.

Yoooo that nordVPN transition !!! He just did it linus style !!!!!!

This is even more confusing than the time I locked myself in my car.

Ran my custom loop in reverse order for six years with no issues with temps. Gonna switch things up and go reverse reverse order after I’ve finished deep cleaning it.

Great video, i was racking my brain about this. This will simplify my life during my current build for sure.

Hey Jay, is there a cooling difference when water cooling multiple gpus in series vs parallel?

Can't stop staring at his amazing hair.

So if you've got heating problems then just add more radiators!

12:22 If you have no patience, like Jay..watch from here. Error of margin is usually 1-2c, he says room increases as SoCal is HOT AF. It doesnt truly matter your loop order...just res feeding pump. Thank for all your hard work Jay and Nic!

I'm making my own out of oak, aluminum and plexiglass. I'm parting out a Koolance ERM and Exos2 for the controller and startup system and some of the trimmings and using al Alphacool XT45 1080 radiator, an EKWB 400mm reservoir and a Koolance PMP-600 pump. 9 Aerocool fans and 4 mcpctech fan grills for blowholes in the plexiglass on each side. I'm taking a lot of pictures of my current ERM system setup so I can repurpose the startup circuitry and controller in my homebuilt system.

Jay 70 F is about 20 C.

0:57 Man, that was smooth, but you've still got a long way to go to catch up to Linus on the $hilling department, lol.

Fahrenheit really is the worst unit on earth. I mean imperial length and weight also are very "unscientific", but Fahrenheit is just a complete mess. Anyway, nice video!

Thanks Jay. Your series of water cooling loop videos has been very helpful.

Thank you sir. I did see. a lot of general criticism as to how the loop should be set up, however looks like science proves the point. Get a 360-420 radiator and feed the liquid through as you indicated.

Haha.....he said “huge load” haha haha 🤪🤣

For those of you that still believe this myth here is some science why it doesn't make any sense. Lets say your GPU the moment it gets under load goes to 100C. The fluid will then take the thermal energy because it is at a lower temperature. thermal energy goes from High to Low. (this is also why heat death is inevitable). the GPU then cools down to 70C. that fluid is not 100C, it is far less. The fluid has a high specific heat. This means it take more energy to raise the temperature. So the fluid lets say is 50C. it then goes tot he CPU. the CPU is temperature is HIGHER than fluid temp so it actually gives the fluid more energy. but if the CPU is lower than the fluid temp in theory the cpu will heat up but in practice it doesn't. this is because the block is design to facilitate thermal energy transfer in 1 direction. there is an imbalance of surface area between he cpu and the fins in the block. This on top of the fact that the fluid is moving so fast that a section of water doesn't have time to heat up the cpu.

You moved the Rad, tests are invalid.

I have been using Corsair 280 AiOs for 10 years and they worked just fine top mounted. Last week, my i7 6950x decided its time to go to digital heaven. I upgraded to i9 12900k and that AiO was no good, so did research on custom loops. This video was helpful as I thought order of things were critical and you have proved that not to be the case. Thank you. I have never cooled my graphics card and never found it necessary on my system. Today I installed all Corsair Hydro components into my 10 year old box which is a full tower, but now used 3 radiators all with push and pull fans for each rad and Corsair Hydro pump reservoir combo XD5. BTW I also used the water block JTZ edition and apologies as I had no clue it was related to your channel. I only got it as it's the latest in the series and read reviews that earlier blocks didn't help 12900k very much. My loop is currently in drip test mode, so have no clue yet as to performance. My loop order is pump, 140 rad, cpu block, 140 rad, 280 rad, then back to pump. I'm looking forward to seeing this work later once no leak system is ensured. Thank you again, your videos have been instrumental in getting my custom loop in place.

I watched the first minute, believed that I can't mess up the loop direction, build a custom loop for a 4090 in 7h (case mill&drill incl.) and booted Cyberpunk (4k/ultra) for an hour:
Water temp max. 48°C, GPU max. 62°C. I can finally play at full load while hearing absolutely NOTHING from my PC. I love it😎👌

It does matter... when you have small water flow. I tested my loop with 25 litres / hour (from 500l/h) and then it really mattered. Because you have so small body of water to heat up per second, so the water is actually hotter aftter exiting the block. I got 5°C higher at the exit of a loop cooling 300W.

The real question is, why do people state their opinions as factual when that's not how it works?

Good to hear you use Fahrenheit not C I'm English and still use Fahrenheit.
Great videos I get a lot of information thanks

The best order for your loop is whatever is most convenient for your configuration. The differences between order is so minimal that it doesn't matter, and if you can get by with shorter runs (or more fancy runs) or more direct runs, go for that. I ran pump -> cpu -> rad -> res -> rad -> gpu -> pump for over a year with no problems.

I literally had to send this to a mate i build a pc with watercooling for the past 3 years and still wouldnt believe me... am so tired of having to tell people it doesnt matter the order....its about letting the water reach equilibrium over time...

The tempaturediffrence on my loop is 1°C - 2°C idling and 3°C - 5°C under full load, messured betwen Radiator in- and outlet. My rad is a Mora 3 and the flow is 100l/h (1,6l/h)

People think about this incorrectly because they ignore equilibrium. When you initially add a load to your system, yes, the first component in the loop will cause the second one to be slightly warmer than it would if it were the other way around. But this only holds true until the system reaches equilibrium, which in most systems is only a few minutes.

This was really helpful for me. After 10+ years I want to build a water loop and these type of video helps take care of some of my questions.

I shared this video with a guy on reddit and all he could do was insult me and say he did not care he knew different from personal experience. I share even more things that proved him wrong and he just started trying to reword what i was saying to make it sound like i thought the rads did not even cool the loop. I kept coming at it with proof and he kept coming at it with insults to me. Got to love people.

"it's not necessary but it's fun", probably the most honest water cooling comment ever.
the maintenance is what kills it for me. with air cooling, all you have to do is blow it out once in a while and occasionally replace a fan, but many fans still last a decade+

I'm late to the game but I agree though I didn't think so at first. Let's say, you put a RAD between the CPU & GPU, I'd think it only make a difference if the water stayed in the rad long enough to get drastically cooler so that when it leaves it makes a drastic and immediate difference. But, even if it did, the CPU would still gain the benefit as well...what was I trying to say?? LOL.

I built a loop with a coolant temp sensor on the inlet and outlet of each component in the loop. 1 degree difference at most between any given sensor.

I love this plug n play connections

True story, Jay! The most impact on a system would NOT be component order, but indeed the routing and bends. Keep it more straight, simple, it will optimize temps.

I think the reason for this is just the high heat capacity of water and the relatively fast flow of water from the pump. The water temperature does not appreciably increase as it cools one component, and the small temperature increase would not make the water differ from the next component to have a significant change in heat transfer for the next component.

Like jayz says when its about the temps loop order doesn’t matter. When it does matter its about the looks. The only reason to have loop order matter i can think of is a very restrictive loop that needs a second pump.

this helps beginners like myself

It's amazing that people think the order matters... learn some basic physics or engineering... for all intents and purposes, this is a closed system. It's energy in vs energy out. Loop order doesn't matter in this case.

That setup would make it very easy to setup liquid cooling in an office situation. If you set it up right you could have a number of systems rads all blowing the warm air out a vent and keep the office temp much or stable. Also you could shut off the vent in cold weather and reap benefit for the warm air from your rads.

Just making my first loop… thanks for this video 👍

What about 2 loops.
Pump>gpu>cpu>rad and back to pump.
Pump>gpu>rad1>cpu>rad2 and back to pump.
Will 2 radiators will make a big difference on hard load?

Loop order only matters when your flow rate is so low that you have a significant increase through one component. Usually not the case in a cooling-only loop where piping head losses are the only loads left on the pump after priming.

I think the message should be that the difference it makes is not considerable in most scenarios.
...However if the first component due to lower flow was say raising the water temp that passed it to near the temperature the next device needed to be below, then this could have a negative effect on the waters ability to cool the following device potentially reducing its lifetime or causing a failure/overheat.
The rule of thumb is to cool the device that needs to be kept lowest first and then step through devices in the order of their max expected and safe operating temps. The benefits of this are that "each component stays as far below its high limit temperature as possible on average" and "creates a balanced contribution from each component towards the coolants temperature rise" which of course is cooled relatively by its differential to the air being blown through/across the radiator.
For proper testing of this you would need to show on and off temperatures of each device, also to consider other variables like different flow rates, split loops through multiple GPU coolers and of course more devices than just CPU and GPU etc.
On top of that a great trick would be to go into more optimisation of your system such as varying water flow rate to maximise your results via pump speeds, possibly as well as your fan speeds, considering measuring electrical consumption for both also. i.e. first ramp up fans, then ramp up pump (as water pumping/moving usually uses more electricity than air moving due to weight) as temp off radiator water raises to near lowest devices desired feed water temperature.
Then of course compare to a traditional air cooling system and then realise you can run all the kit at higher temps fine like that and not worry about water loops as it'll last long enough until your next upgrade anyway.
...oh and another thing, put it in a case please when you are testing all sat in the same space really gives my OCD a rattle, for probably silly reasons :)

Loop orders definitely matter. If you have your 450W GPU before hour 400W CPU, there will definitely be a difference in the coolant temp unless there is a radiator between them.

Did my first one today, did it by pump to rad, to cpu block back to pump and repeat... I thought of a car cooling system and went by that and then found I had a instruction manual telling me (pump to cpu, cpu to rad, rad to pump and repeat???) Thought it was odd but meh it still goes... and now I've seen you talk about it lol no worries at all and for my first crack nor bad... set up I got is a c360 thermaltake pacific soft tube kit, goes hard 👌