Back in March, Intel unveiled its 11th generation of desktop processors codenamed Rocket Lake. In its lineup, the flagship desktop chip is the Core i9-11900K, with eight cores, sixteen threads, and a current selling price of $545 at Amazon. Along with obvious performance advantages that come with the flagship model, including higher turbo frequencies, Intel has put a lot of its latest technologies into Rocket Lake including Thermal Velocity Boost (TVB) and Adaptive Boost (ABT) - the idea here is to to give the best possible performance out of the box. In this article, we take four retail Intel Core i9-11900K processors and four premium Z590 motherboards, including the ASRock Z590 Taichi, the ASUS ROG Maximus XIII Hero, the GIGABYTE Z590 Aorus Master, and MSI MEG Z590 Ace, and overclocking them. Is overclocking worth it on Intel's Core i9-11900K? Let's find out.

The Core i9-11900K: Intel's Flagship Desktop Processor

Before launching in March, there was a lot of discussion about Rocket Lake's potential performance. On the one hand, it looked just like another 14nm design refresh such as Skylake. While this is somewhat true, the reality is that it provides an advancement incrementally in terms of Intel's research and design model; Rocket Lake is actually retrofitted its 10nm design onto 14nm, for multiple reasons, including CPU core frequency (it's higher on 14nm), cost (14nm is cheaper to manufacture), and peak thermal window. The last point has been another talking point as Rocket Lake runs warm. One of the reasons for this, outside of refinements and improvements to turbo frequencies and internal automatic overclocking technologies, is Intel's move to PCIe 4.0 which comes directly from the CPU. As we found out in our initial Core i7-11700K review (and verified on the Core i9 and Core i5 models), if you blast this chip with a strong AVX-512 workload, you can draw near 300 watts, however day-to-day running at half that is easily par for the course. 

While there are many options on Intel's 11th generation for desktop, including various Core i5, Core i7, and Core i9 processors, the current flagship in the line-up is the Core i9-11900K. The Intel Core i9-11900K features 8 cores and 16 threads. In terms of specifications and operating frequencies, the Core i9-11900K has a base frequency of 3.5 GHz, while it has a 'turbo' which tops out at 5.3 GHz. At present, Intel's interpretation of Turbo is rather complex and requires digesting in different ways than previously thought.

Intel Thermal Velocity Boost (TVB) Versus Adaptive Boost Technology (ABT)

As it stands, Intel's Core i9-11900K has five levels of automatic overclocking. This includes the base frequency at default settings, Turbo Boost 2.0 (TB2), Turbo Boost Max 3.0 (TBM3), Thermal Velocity Boost (TVB), and Adaptive Boost Technology (ABT). Below is an overview of what each means:

Intel Core i9-11900K Frequency Levels
Base Frequency The base frequency is the clock speed that the processor is guaranteed to run at under warranty conditions with a power consumption no higher than the TDP rating of the processor (125W).
Turbo Boost 2.0 (TB2) When operating in turbo mode, this is the frequency all of the cores will run at. TB2 has different levels of variation depending on how many cores are being used.
Turbo Boost Max 3.0 (TBM3) When in turbo mode, the best cores (typically one to two) get boosted with extra frequency when they are the only cores being used.
Thermal Velocity Boost (TVB) If the peak thermal temperature is below a given value (70°C for i9-11900K) in turbo mode, all the cores will boost by +100 MHz. This also follows the TB2 frequency depending on how many/what cores are loaded.
Adaptive Boost Technology (ABT) If 3 or more cores are active in turbo mode, the processor will attempt to provide the highest frequency with the remaining power budget. This is regardless of the TB2 frequency. This is typically the same when 2-cores are loaded, as ABT overrides TVB when 3 or more cores are loaded.

In our launch day review of Intel's Core i9-11900K, Core i7-11700K, and Core i5-11600K processors, we analyzed all of the turbo variants. Focusing on the Core i9-11900K, which we will be overclocking and testing in this article, we can see below that the Thermal Velocity boost enabled two cores to operate at 5.3 GHz. In contrast, the remaining cores fluctuated between 5.1 GHz and 4.8 GHz with what Intel calls Adaptive Boost Technology (ABT).

Looking at the Turbo Boost 2.0 frequencies on the Core i9-11900K, every core will operate a 4.7 GHz when all cores are loaded. If there is power and thermal budget available to use, then it will attempt 4.8 GHz, then 4.9 GHz, and so forth. This is what we like to call a 'floating turbo' as it is influenced by thermal and power budgets, which means users with more aggressive CPU coolers are more likely to see higher performance than those using more modest forms of CPU cooling such as smaller air coolers. This is a very similar method and implementation to AMD's Precision Boost 2 technology, which was introduced in April 2018 with Zen+.

If Intel's Turbo Is So Good, Why Manually Overclock?

Back in the 'good old days' when overclocking a processor could yield a 30-50% improvement in core frequency, the truth today is that both Intel and AMD are understanding how to get the most from the silicon straight from the factory. This also includes motherboard vendors who also make adjustments in its own Multi-Core Enhancement (MCE) implementations, making them not worth much over the standard feature set. This makes manually overclocking more of a conundrum than ever before, with fewer gains than previous generations. 

Taking all the turbo boost technologies away from the equation and instead focusing on the base frequency, an overclock of 5.1 GHz all-cores on the Core i9-11900K over the 3.5 GHz base frequency equates to around 45%, which could be impressive if ABT wasn't involved. If using the Turbo Boost 2.0 (TB2) of 4.7 GHz all-cores, the same 5.1 GHz overclock on all-cores is around 8-9%, which is meager in comparison. This is beneficial for novice users that intend to run the processor without making any out-of-the-box adjustments. Still, there's very little headroom in the grand scheme of things for the true enthusiasts among us due to these implementations.

Pushing The Limits of Silicon

Similar to how people 'tune' car engines for maximum power and performance gains, many people within this industry use their skills and talent to push computer hardware to the limits. Usually tied to motherboard manufacturers for the most skilled overclockers, people such as HiCookie (GIGABYTE), and Kingp!n (EVGA), actually compete at a high level on the world stage at overclocking events over the year for world records, and in a lot of cases, bragging rights for their respective affiliations. 

Overclocking with Liquid Nitrogen (LN2) during The Big Freeze UK overclocking event in 2016
(hosted by me!)

While it is entirely possible to get a decent overclock using ambient cooling methods such as water cooling, air cooling, and by using closed loop liquid coolers, the limitation here is never being able to cool below the ambient room temperature. Overclocking by increasing voltages and frequencies generates heat, and you need something to remove the heat, and sometimes the ambient temperture just won't do, even in the Swedish mountains (or Sheffield). The biggest overclocking records come when using more extreme methods such as sub-ambient cooling, the most popular of which includes Liquid Nitrogen (LN2) and dry ice (DICE), which are pretty chill, but also Single-Stage and Multi-Stage Phase Change Change coolers, which use refrigeration equipment to keep the silicon cold. 

The Cooler Master Masterliquid ML360 Sub-Zero: Cryo Cooling Technology for the Masses

As we're overclocking using a warm running platform, we felt it appropriate to get some upgraded cooling that's currently available at retail to all users. Our cooler of choice is Cooler Master's Masterliquid ML360 Sub-Zero edition cooler, which uses Thermoelectric Unit (TEC) technology to help achieve the lowest possible temperatures. This uses 'Intel's Cryo Cooling Technology' which it states is intelligent sub-ambient cooling with a dynamically managed condensation risk. It adapts around temperatures to avoid this and protect the hardware. Intel and Cooler Master built this together as a way to push processors like Rocket Lake further for end users.

The Cooler Master ML360 Sub-Zero with Intel Cryo Cooling technology

The Cooler Master ML360 Sub-Zero includes a 360 mm aluminum radiator, and on the surface, looks like any other regular AIO. The special sauce comes in the form of an integrated TEC, which uses electricity to create a plate with one side cold (on the CPU) and one side warm. The warm side is attached to a closed loop liquid cooler. In order to cool a 200W CPU, this means you need 200W of cooling from the TEC, and that also has to be powered. As a result, the ML360 Sub-Zero is that it requires an 8-pin PCIe cable, so one thing to take into consideration is the additional power draw from the cooler. We measured up to 200 W additional power from the cooler alone in our testing, so if someone is looking to purchase this cooler for their Rocket Lake setup, leave an additional 200 W of power headroom from the power supply. 


Thermoelectric cooling, or TEC by name, is a solution that applies voltage to generate heat across a TEC plate made of a conductive material and coated in layers of ceramic. One of the plates is warm, while the other is cold. Intel's technology has a constantly variating power usage controlled by both the firmware and software and includes a humidity sensor designed to detect and alleviate condensation build-up.

What's In This Article

Over the next few pages, we intend to overclock four Intel Core i9-11900K processors on four different but OC capable motherboards: the ASRock Z590 Taichi ($430), the ASUS ROG Maximus XIII Hero ($472), the GIGABYTE Z590 Aorus Master ($360), and the MSI MEG Z590 Ace ($500). All four of our processors are retail stepping models.

Four Intel Core i9-11900K processors are ready to be binned and overclocked.

Not only is this article design to show variances between different Core i9-11900K processors, but it allows us to show that not every processor is the same. We will show results from all four of the Core i9-11900K processors at peak performance and show variances in the silicon from both a power and a performance perspective. This also includes testing each processor on four different Z590 motherboards to show which has the better potential to push each of the processors to its maximum potential.

Test Bed & Setup​

For our testing, we have the four Z590 motherboards (one from ASRock, ASUS, GIGABYTE, and MSI) and four Intel Core i9-11900K processors. Three of the processors are from the same batch of silicon, while the fourth is from a completely different batch. We use our regular motherboard test bench, including the Corsair Crystal 680 X chassis, but with the Coolermaster Masterliquid ML360 Sub-Zero, which uses Intel's Cryo cooling technology.

Processor Intel Core i9-11900K, 125 W, $374
8 Cores, 16 Threads 3.5 GHz (5.3 GHz Turbo)
Motherboards ASRock Z590 Taichi (BIOS 2.20)
ASUS ROG Maximus XIII Hero (BIOS 1007)
GIGABYTE Z590 Aorus Master (BIOS F5)
MSI MEG Z590 Ace (BIOS v11)
Cooling Coolermaster Masterliquid ML360 Sub-Zero
Power Supply Corsair HX850 80Plus Platinum 850 W
Memory G.Skill TridentZ DDR4-3600 CL 16-16-16-34 2T (2 x 8 GB)
Video Card MSI GTX 1080 (1178/1279 Boost)
Hard Drive Crucial MX300 1TB
Case Corsair Crystal 680X
OS Windows 10 Pro 64-bit: Build 20H2

We did plan to use our Corsair Vengeance LPX DDR4-5000 memory kit for this article, but we hit immediate stability issues from the get-go, as it turns out none of these boards have been validated for that kit. Instead, we opted for a 2 x 8 GB G.Skill TridentZ DDR4-3600 CL16 kit, which is pretty much the sweet spot for both Intel and AMD platforms regarding a combination of price and performance.

G.Skill TridentZ DDR4-3600 CL16 2 x 8 GB memory kit we used for our testing

On the next pages, we'll take a quick look at each of the four motherboards and the relevant sections within the firmware and put them to the test with four i9-11900Ks per motherboard.

Table of Contents

  1. An Introduction to Overclocking With Rocket Lake
  2. The ASRock Z590 Taichi: A Quick Recap
  3. The ASUS ROG Maximus XIII Hero: A Quick Recap
  4. The GIGABYTE Z590 Aorus Master: A Quick Recap
  5. The MSI MEG Z590 Ace: A Quick Recap
  6. Overclocking Our i9-11900K's, Binning For Core Frequency
  7. Core i9-11900K Overclocking Results
  8. Core i9-11900K Overclocking Results Cont.
  9. Overclocking With Rocket Lake: The Conclusion
The ASRock Z590 Taichi
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  • StevoLincolnite - Monday, August 30, 2021 - link

    I just upgraded from my 10~ year old Core i7 3930K Sandy Bridge CPU, 6-cores, 12 threads. Overclocked to 4.6Ghz with 16Gb of Quad-Channel Ram...

    Haven't noticed much of a difference when upgrading to the Ryzen 9 5900X and 64GB of 3600Mhz Ram in the games I play. (Mostly just eSports titles)

    But hoping this rig lasts 10~ years like my last one.

    Sold my old system in parts and so far made about $1,000 AUD back, which is definitely a good return on investment... Enough to buy a Radeon RX 6700XT.
  • lemurbutton - Monday, August 30, 2021 - link

    Buy Apple Silicon. Pretty soon, no amount of energy-wasting, environmentally unfriendly overclocks can match the speed of a 35w Apple Silicon thin and light Macbook Pro.
  • TheinsanegamerN - Monday, August 30, 2021 - link

    > suggesting an apple ARM device for the enviroment.

    My sides have entered hyperspace. How can one be so dense?
  • bigvlada - Monday, August 30, 2021 - link

    That's what we were hearing about slow and melting Pentium 66 MHz and lightning fast and cool 90 MHz PowerMac.

    And no, "This time it will be different tm" won't work, because just like in 1984. and 1994. majority of people do not want a closed, barely repairable system. In those early days, you needed a bayonet sized screwdriver and soldering iron in order to expand memory on Apple machines.
  • joelypolly - Monday, August 30, 2021 - link

    I mean... look at the smartphone market. It's a good indication that the market has changed and most people are just looking for a computing appliance.
  • M O B - Monday, August 30, 2021 - link

    Oh really. Do people normally want to swap out the GPU, RAM, disk, or WiFi/BT card in their android phone? Of course now. Phones, despite their computational power, are not computers. You fail at analogy.
    Every company except Apple at least makes it possible to swap out several components, granted that soldered RAM or PCIe SSDs are common in certain compact form factors.
  • vshade - Tuesday, August 31, 2021 - link

    Smartphones are computers for most of the world, is the device they will communicate, make planning and game on.
  • whatthe123 - Monday, August 30, 2021 - link

    It's an indication of an entirely new premium market that relies on subscriptions to mask costs. Macs continue to dominate in profitability but they always trail in marketshare because the upfront costs are too high, and nobody can really even get that market except Apple since Apple is the only one that has successfully created and maintained a lifestyle culture around their products. In order for Apple's CPUs to sweep the rest of the market they'd need to sell their chips directly or macs would need to overtake everything else in volume, neither of which Apple seems interested in doing or is really able to do since they're capped by TSMC's output.
  • Exotic - Tuesday, August 31, 2021 - link

    On Desktop I agree as people generally want easy upgradability. Where Apple Sillicon will shine and be very impressive to a lot people will be in laptops. In 99.99% of laptops the CPU and GPU is soldered and is not user upgradeable and the same is to said for ultrabooks regarding RAM as that too is getting soldered onto the mainboard.

    Laptops also sell more than desktops these days.
  • Wrs - Tuesday, August 31, 2021 - link

    Being closed and barely repairable is a side effect of tight integration, not necessarily with being Apple. It is true that Apple tends to be associated with pushing the curve on engineering/miniaturization and naturally this results in a higher price, but they don't have a monopoly on integration and neither does the PC side have a monopoly on expansion and the use of commodity parts.

    I remember Macs from the 90s, as well as Mac Minis in the 2010s that incorporated tool less entry to the RAM slots, and with just a few regular screws you can access the same on Intel iMacs. Hard drives were just more screws. That's leaving aside the Mac Pro lineup. Yet no modern smartphone lets you upgrade the RAM or internal storage because it takes a lot more effort to design user serviceability into such a tiny yet functional form factor.

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