Intel’s 13th-Gen Raptor Lake processors will bring more cores, more connectivity, a revamped core architecture, support for PCIe 5.0 SSDs, and even an officialy-verified 6.0 GHz peak boost clock to bear. Intel claims that Raptor Lake will have a 15% gain in single-threaded performance and a 41% gain in multi-threaded compared to Alder Lake, and an overall ‘40% performance scaling.’ These chips will arrive in October to square off with AMD’s Zen 4 Ryzen 7000 processors, setting the stage for a fierce battle for desktop PC supremacy — particularly for the crown of the best CPU for gaming as the Intel vs AMD rivalry enters a new stage.
Intel’s Alder Lake brought the company back from what had been a slow erosion of its leadership position in our CPU benchmarks rankings as AMD relentlessly iterated on its Ryzen processor lineup. AMD’s string of innovations eventually culminated in an embarrassing loss of the performance crown for Intel as the Ryzen 5000 processors outclassed Intel’s chips in every performance, price, and power metric that mattered back in 2020, capping Intel’s decline from grace after incessant delays moving to its oft-delayed and seemingly doomed 10nm process node.
Alder Lake righted the ship. These chips brought the best of Intel’s newly re-worked 10nm process, now re-named ‘Intel 7,’ enabling higher clock rates and lower power consumption, paving the way for Raptor Lake. Intel will etch the Raptor Lake processors on a refined version of that same process node and pair it with its newly-revamped x86 hybrid architecture, a design that combines a mix of larger high-performance cores paired with smaller high-efficiency cores.
Like its predecessor, Raptor Lake will also support disruptive new features like PCIe 5.0 and DDR5 but preserves DDR4 support for less-expensive build options. Raptor Lake will also drop into existing motherboards to offer an upgrade path for Alder Lake users, but there will be new 700-series motherboards at launch that offer better connectivity options. Intel is also introducing more CPU overclock features for Raptor Lake, too.
Even though Raptor Lake is clearly on the cusp of coming to market this year — we’ve even seen chips sold at auction and benchmarks in the wild — Intel has been uncharacteristically silent about its pending line of chips for desktop PCs. In fact, the company has said more about its next-next-gen Meteor Lake chips than it has about Raptor Lake. That hasn’t stopped us from gathering all of the information we know from official and unofficial sources into this article. We even have pictures of the new processor die. We’ll update the article as we learn more, but here’s what we know so far.
Intel 13th-Gen Raptor Lake Series at a Glance
- Codename Raptor Lake
- Desktop and mobile launch in Q4 2022 (October 20)
- Up to 24 cores and 32 threads on ‘Intel 7’ process node
- Up to 8 Raptor Cove Performance cores (P-Cores) and 16 Gracemont Efficiency cores (E-Cores)
- Raptor Lake-S (65W to 125W desktop) and Raptor Lake-P (15 to 45W mobile) confirmed
- Rumored 5.8 GHz boost
- Up to 36MB of L3 Cache (20% increase), up to 32MB L2 (2.3x increase)
- Dual-Channel DDR4-3200 and DDR5-5600 memory support, x16 PCIe 5.0 and x4 PCIe 4.0 interface, Thunderbolt 4 / USB 4
- Support for PCIe 5.0 M.2 SSDs and AI M.2 Module
- “Up to double-digit performance boost”
- Socket LGA 1700, backward compatible with existing coolers, mobile chips are BGA compatible
- 700-Series Chipset: Z790, H770, B760 Motherboards
- Chipset: Up to 20 PCH PCIe 4.0 and eight PCIe 3.0
- Enhanced CPU overclocking features, including per-core and Efficient Thermal Velocity Boost
Intel 13th-Gen Raptor Lake Release Date Window
Intel hasn’t given an official launch date for Raptor Lake yet, but all signs point to a Q4 2022 launch for the desktop processors. Intel has also announced that it will bring the Raptor Lake mobile CPUs to market this year, too. Our own sources tell us that we’ll see an announcement for the desktop chips in late September, but the launch will land in mid-to-late October. Naturally, this is early information and subject to change — vendors often push back timelines — but the chips are said to be currently scheduled to launch in that timeframe.
Our information was subsequently backed up by info from Enthusiastic Citizen, a leaker with a stellar track record, that claims Intel will announce the full Raptor Lake details at the Intel Innovation event on September 28 in tandem with reviews being published that same day. Preorders will purportedly begin on October 13, and retail availability for the K-series SKUs will arrive on October 20 along with the Z790 motherboards. Non-K CPUs and the B760 and H760 chipsets reportedly won’t be announced until January 5, 2023, at CES, with retail availability in the second half of that month.
Intel is also accelerating its mobile launch, with CEO Pat Gelsinger recently announcing that the mobile platforms will launch this year. We’ve even seen benchmarks emerge from the mobile Raptor Lake processors. An engineering sample of the flagship Core i9-13900K has been auctioned online, and several reviews of production-quality silicon have leaked online. We’ll cover those benchmark results below, but all of these signs point to an impending launch.
Intel 13th-Gen Raptor Lake Specifications and Features
Intel recently disclosed that its top-end Raptor Lake processors will reach up to 6 GHz at stock settings and have set a world overclocking record at 8GHz – obviously with liquid nitrogen. Notably, the peak of 6 GHz is 300 MHz faster than the 5.7 GHz for AMD’s Ryzen 7000 processors, but Intel hasn’t announced which product will hit that peak speed. We also aren’t sure if a 6GHz chip will arrive with the first wave of chips or be a special edition ‘KS’ model.
Intel also recently accidentally listed the Raptor Lake specs on its Canadian site, and then quickly removed the listings. This comprehensive official listing of features touts up to 24 cores and 32 threads with the Core i9-13900K, 16 cores and 24 threads with the i7-13700K, and 14 cores and 20 threads with the Core i5-13600K. The listing also included Turbo Boost 2.0 speeds, but not the more comprehensive peak boost clocks. We have all of that information in the table below.
The Raptor Lake chips are fabbed on the ‘Intel 7’ process and will have a 15% gain in single-threaded performance and a 41% gain in multi-threaded compared to Alder Lake, and an overall ‘40% performance scaling.’ Raptor Lake also comes with enhanced overclocking features, support for an AI M.2 module, and the chips are compatible with Alder Lake systems.
The Raptor Lake chips will have Performance Cores (P-cores) with a purportedly new microarchitecture, rumored to be named Raptor Cove (more below). These cores are designed for single- and lightly-threaded tasks, like gaming and productivity workloads. The Efficiency Cores (E-cores) also bear signs of a revamped microarchitecture, but these cores are still rumored to have the Gracemont design. These cores step in for heavily-threaded workloads, background tasks, and multi-tasking.
| Price | Cores / Threads (P+E) | Base / Boost Clock (GHz) | Cache (L2/L3) | TDP / PBP / MTP | Memory | |
| Ryzen 9 7950X | $699 | 16 / 32 | 4.5 / 5.7 | 80MB (16+64) | 170W / 230W | DDR5-5200 |
| Core i9-13900K / KF | ? | 24 / 32 (8+16) | 3.0 / 5.8 | 64MB (32+36) | 125W / 253W | DDR4-3200 / DDR5-5600 |
| Core i9-12900K / KF | $589 (K) – $564 (KF) | 16 / 24 (8+8) | 3.2 / 5.2 | 44MB (14+30) | 125W / 241W | DDR4-3200 / DDR5-4800 |
| Ryzen 9 7900X | $549 | 12 / 24 | 4.7 / 5.6 | 76MB (12+64) | 170W / 230W | DDR5-5200 |
| Core i7-13700K / KF | ? | 16 / 24 (8+8) | 3.4 / 5.4 | 54MB (24+30) | 125W / 253W | DDR4-3200 / DDR5-5600 |
| Core i7-12700K / KF | $409 (K) – $384 (KF) | 12 / 20 (8+4) | 3.6 / 5.0 | 37MB (12+25) | 125W / 190W | DDR4-3200 / DDR5-4800 |
| Ryzen 7 7700X | $399 | 8 / 16 | 4.5 / 5.4 | 40MB (8+32) | 105W / ? | DDR5-5200 |
| Ryzen 5 7600X | $299 | 6 / 12 | 4.7 / 5.3 | 38MB (6+32) | 105W / ? | DDR5-5200 |
| Core i5-13600K / KF | ? | 14 / 20 (6+8) | 3.5 / 5.1 | 44MB (20+24) | 125W / 181W | DDR4-3200 / DDR5-5600 |
| Core i5-12600K / KF | $289 (K) – $264 (KF) | 10 / 16 (6+4) | 3.7 / 4.9 | 29.5MB (9.5+20) | 125W / 150W | DDR4-3200 / DDR5-4800 |
| Core i5-13400 / F | ? | 10 / 16 (6+4) | 3.4 / ? | 24MB | 65W / ? | DDR4-3200 / DDR5-5600 |
| Core i5-12400 / F | $199 – $167 (F) | 6 / 12 (4+0) | 4.4 / 2.5 | 25.5MB (7.5+18) | 65W / 117W | DDR4-3200 / DDR5-4800 |
| Core i5-13100 | ? | 4P + 0E | 4 Cores / 8 Threads | ~3.4 GHz / ? | ? | DDR4-3200 / DDR5-5600 | 12MB |
Above, we can see the Core i9, i7, and i5 flagships from Intel’s previous-gen family, along with what we know about the new Raptor Lake models from the various leaks and information we’ve collected. These specs were later corroborated. Be aware that not all of the Intel 13th-Gen info in the above table has been officially confirmed. We’ve also added in the newly-announced Ryzen 7000 processors.
Intel will purportedly only release Core i9, i7, and some i5 models with the Raptor Lake die, while some i5 and all i3, Pentium, and Celeron will leverage refreshed previous-gen Alder Lake chips (Intel took a similar approach with its 11th-Gen Rocket Lake processors).
The Core i9-13900K will come with a total of 24 cores representing a mix of eight P-cores and 16 E-cores. That’s an additional eight E-cores over the previous-gen flagship (but the same number of P-cores). These additional E-cores come from a new larger 8+16 die (8 P-core + 16 E-core) that Intel will use for the Core i9, i7, and K-series i5 chips only. This larger die comes with additional cache capacity for the cores (more on that in the architecture section), but Core i3 and below will have the same amount of cache as found with the existing Alder Lake models.
Intel’s Core i7-13700K recently emerged in the Geekbench database, showing the chip has eight P-cores and eight E-cores, for a total of 16 cores and 24 threads, paired with 30MB of L3 cache. Those basic specs match the previous-gen Core i7-12700K, but we aren’t aware of any differences in the official clock speeds yet. However, this processor has been overclocked to an excellent 6 GHz and 6.1 GHz, as seen in two separate benchmarks, the latter with liquid cooling.
It’s clear that Intel has changed its Core i5 E-core strategy. The current K-series Core i5, the Core i5-12600K, comes with four E-cores, but a recent leak points to the Core i5-13600K having four additional E-cores, for a total of eight. Traditionally, the rest of the non-K Core i5 models, like the Core i5-12400, don’t have E-cores. Intel is said to be adding E-cores to the non-K Core i5 Raptor Lake chips, which could make its mid-range Core i5 all the more potent [Edit: as you can see below, this has proven to be true].
Above we can see leaked Raptor Lake specs for the entire 13th-Generation Intel family. Take these with a grain of salt, but this comes from a known leaker with access to early hardware. You’ll notice the non-K Core i5 models have been revamped with e-cores, but they are bolded on the chart because these will purportedly also come with previous-gen Alder Lake dies, just like the i3 models. Time will tell.
We don’t have any concrete clock speed information on the Raptor Lake SKUs yet, as the benchmarks we’ve seen of Engineering Samples (ES) chips aren’t representative of the final clock speeds. These chips go through different revisions, like ES1, ES2, and so on, and the rumor mill points to up to 5.5 GHz with the ES3 version of the Core i9-13900K — but bear in mind that these are not the final clock speeds. We’ve since seen a 5.7 GHz peak clock rate in a leaked benchmark, and that was later eclipsed by a 5.8 GHz sample.
As a reminder, Intel has redefined its power terminology to have a ‘Processor Boost Power’ (PBP) value representing the guaranteed base performance level (PL1). This replaces TDP. CPU-Z entries show the Core i9-13900K with a 125W PBP, along with screenshots for a 65W variant with the same 8+16 core counts that is likely the 65W Core i9-13900. Intel also lists a ‘Maximum Turbo Power’ (MTP) specification that quantifies the power consumption during Turbo Boost (PL2). This is rumored to remain at 241W for the Core i9-13900K. By assigning the same peak PBP for the Core i9, it’s fair to assume that the Core i7, i5, and i3 ranges will have similar power limits as the Alder Lake processors. That means we’ll see 125W, 65W, and 35W versions for desktop PCs and sub-45W for the mobile chips.
There are also rumblings of a 350W ‘Turbo Mode,’ but take these reports with some salt. It’s notable that Intel’s current chips can also operate at such high wattage if the power limits are removed. As such, this might be some sort of new marketing tactic of an existing feature, but it feels doubtful that Intel would call attention to egregious power consumption.
Intel has confirmed that the Alder Lake chips will drop into the LGA 1700 socket, meaning they are backward compatible with the existing 600-series chipsets, and older coolers are also forward compatible with the new Raptor Lake motherboards. In addition, the 16 PCIe 5.0 PCIe lanes coming off the CPU can now be split into dual x8 arrangements, thus enabling support for PCIe 5.0 M.2 SSDs. We’ll dive much deeper into this topic in the motherboard section.
The above slide was recently leaked, confirming the details we’ve already shared in this article. The Raptor Lake chips support DDR4-3200, just like the previous-gen chips, and are currently qualified for DDR5-5200, which is faster than the DDR5-4800 with previous-gen chips. However, we’re told that Intel is working on getting DDR5-5600 qualified in time for launch, so memory data transfer rates aren’t final.
Intel’s previous-gen Alder Lake chips marked the industry debut of DDR5 memory, but the new memory often doesn’t provide big speedups over DDR4, especially at stock settings. That could change, though, as two individual sets of benchmarks have shown impressive gains, with the Core i7-13700K being either 20% or 60% faster than DDR4 in several leaked benchmarks. We’ll have to wait to see how that looks in the real world, but DDR5 does look promising on the Raptor Lake platform.
As before, Raptor Lake will have a dual-channel memory interface. Intel will also carry over ECC memory support for its consumer-class W-series motherboards. We will still also see a complicated DDR5 memory support matrix that sees speeds decline if the motherboard has more than one DIMM slot per channel (SPC), if you populate more than 1 DIMM per channel (DPC) on boards that have two SPC, or based on varying DIMM ranks. However, you can now expect increased speed with each type of configuration. Non-K and Core i3 chips will also have slower supported peak speeds than the K-series chips.
As evidenced by Intel’s own statements, Raptor Lake will continue to have a heavy focus on CPU overclock features. Tantalizing unofficial details recently emerged via an update to Intel’s own eXtreme Tuning Utility (XTU). Intel has added support for ‘future platforms’ to leverage added support for per-core and package-level Thermal Velocity Boost (TVB) tech, which allows the processor to boost higher than the base specification if the chip is under a certain temperature threshold. Intel also added support for a new type of TVB, called ‘Efficiency TVB.’ We’ve also heard rumblings of a 6 GHz clock rate for a Core i9-13900KS, the successor to the Core i9-12900KS, enabled by this new boost. Take this with a grain of salt, as it is based on a single claim.
The Raptor Lake iGPU is said to be based on the same Xe-LP Gen 12.2 architecture found with Alder Lake. A recent benchmark emerged showing the Raptor Lake Core i9-13900’s iGPU with 32 EUs running at 1.65 GHz in an OpenGL benchmark. That means the iGPU has the same number of cores but runs 100 MHz (6.5%) faster than the previous-gen version. Aside from minor clock speed improvements, we don’t expect any meaningful architectural changes to the iGPU. Intel did recently add support for Raptor Lake-P (mobile) and Raptor Lake-S (desktop) processors to its media driver, thus tipping its hat that mobile variants of Raptor Lake are also in the works.
Intel has also teased a new AI accelerator that will slot into an M.2 slot. It’s hard to tell what practical purpose this would serve for most uses, though some edge use-cases might benefit. Intel hasn’t shared any more information about this product, and there hasn’t been any other information, so we’ll have to wait to learn more.
We have plenty of other architectural information to share in the sections below. But first, let’s take a break to look at the leaked Raptor Lake benchmarks.
Intel 13th-Gen Raptor Lake vs AMD Zen 4 Ryzen 7000
| AMD Zen 4 Ryzen 7000 | Intel Raptor Lake | |
| Release Date: Rumored | September 27th | Mid- to Late-October |
| Node / Design | TSMC 5nm Compute die, 6nm I/O DIe | Intel 7 – Monolithic Die |
| Cores / Threads | Up to 16 Cores / 32 Threads | Up to 8P + 16E | 24 Cores / 32 Threads |
| Peak Clocks | ~5.7 GHz | 5.8 Observed / 6.0 Rumored |
| TDP / PBP / MTP | 170W / 230W | 125W / 241W |
| Memory | DDR5 Only (No DDR4 support) | DDR4-3200 / DDR5-5600 |
| PCIe | PCIe 5.0 – 24 Lanes | PCIe 5.0 x16, PCIe 4.0 x4 (SSD) |
| Graphics | ? | ? |
Here’s what we think the Raptor Lake vs Ryzen 7000 competition will look like, though bear in mind that not all specs are confirmed. Both chipmakers are pushing clocks to the highest we’ve seen with their modern chips, and that will naturally come with increased power consumption, particularly in multi-threaded work.
AMD’s Zen 4 Ryzen 7000 chips only support DDR5 memory, while Raptor Lake supports DDR4 and DDR5. That gives Intel a leg up in the overall system cost category, as DDR5 still commands a price premium. However, we no longer see DDR5 shortages, and prices continue to plummet as more supply comes online and demand recedes. That means the pricing delta should get noticeably slimmer, though we fully expect DDR5 to always command a premium.
Intel 13th-Gen Raptor Lake Die Pictures
We’ve already seen plenty of 13th-gen Intel Raptor Lake benchmarks emerge (more about that below), so it’s clear that plenty of Raptor Lake chips are floating around in the wild. Now we have pictures of the actual die, too.
A video posted to Bilibili shows the dimensions of the Raptor Lake die, which measures 23.8 x 10.8mm. That means the chips have a slightly wider and much longer die than the 12th-gen Alder Lake processors.
| Die Area | Die Dimensions | Cores | Process | |
| Raptor Lake Core i9-13900K | 257 mm^2 | 23.8 x 10.8 mm | 8 P-Cores | 16 E-Cores | Intel 7 |
| Alder Lake Core i9-12900K | 208 mm^2 | 20.4 x 10.2 mm | 8 P-Cores | 8 E-Cores | Intel 7 |
| Rocket Lake Core i9-11900K | 281 mm^2 | 24 x 11.7 mm | 8 P-Cores | 14nm |
| Comet Lake Core i9-10900K | 206 mm^2 | 9.2 x 22.4 mm | 10 P-Cores | 14nm |
Here we can see the 11900K, 12900K, and Raptor Lake Core i9-13900K together. Intel increased the core count for Raptor Lake by moving from a peak of eight E-cores to 16 by adding two more quad-core clusters, increased the L2 cache by 60%, and also increased the L3 cache capacity (more details below). All of these factors necessitated an 8+16 die that is 49mm^2 larger than the previous-gen 8+8 die. Each E-core cluster weighs in at roughly ~8.65 mm^2, meaning only 17.3 mm^2 of the die increase is dedicated to the E-cores, while the rest is allocated to the larger L2 and L3 caches. That’s a real testament to the incredibly area-efficient nature of the e-cores.
The larger chip size amounts to more costly manufacturing because a larger die results in fewer dies per wafer. Intel has said that it will raise chip prices due to inflation, but it isn’t clear how that will impact the Raptor Lake family — Intel will either increase pricing even more to offset the larger die, or it will raise prices further to offset the increased manufacturing costs.
Intel 13th-Gen Raptor Lake Benchmarks and IPC
Intel demoed Raptor Lake at its Investor Day 2022 using a chip with eight P-Cores and 16 E-Cores, so it was a flagship Core i9 model. The demo of a Blender and After Effects workload didn’t give us any performance data to work with. Luckily, we’ve seen plenty of leaked benchmarks that give us a better idea of what Raptor Lake will look like. However, as with all leaked test results, take all of the benchmarks below with a grain of salt — they are often conducted with pre-production silicon and unoptimized platforms, meaning final results could be materially better.
The best comes from a Core i9-13900K video review posted in China that you can watch here. For non-Chinese speakers, we have the rundown of those tests below:
| Benchmark | Core i9-13900K | Core i9-12900KF | Percent Change |
| CPU-Z bench 1T | 892.2 | 815.5 | +9.4% |
| CPU-Z bench nT | 16,606 | 11,348 | +46.3% |
| Geekbench 1T | 2,133 | 1,939 | +10% |
| Geekbench nT | 23,701 | 19,304 | +22.8% |
| Cinebench R23 1T | 2,206 | 1,940 | +13.7% |
| Cinebench R23 nT | 37,385 | 26,939 | +38.8% |
| 3D Mark Timespy CPU | 23,839 | 20,121 | +18.5% |
| PugetBench Premiere Pro | 1,213 | 1,003 | +20.1% |
The tested 13900K is a Qualification Sample (QS), meaning it is nearly identical to the retail models. The 13900K had a 3 GHz base and 5.8 GHz boost for the P-cores and was tested on a ROG Maximus Z690 Extreme, but without optimized firmware. The chip was dialed into the correct 125W/250W power range for the tests.
On average, across a broad variety of tests, the 13900K was 10% faster in single-thread and 35% faster in multi-threaded workloads than the previous-gen 12900K. That’s quite an impressive multi-threaded gain given that it stems almost entirely from the extra eight E-Cores and cache. The tests expose even higher gains in some of the individual threaded benchmarks, like CPU-z and Cinebench, which registered a whopping 46% and 40% improvement, respectively. The outlet later added power measurements with the correct power settings, showing a more realistic power draw of 253W. That resulted in the chip running at 77C during an extended test.
| Core i9-13900K | Core i9-12900K | AMD 5950X | |
| Cores / Threads | 24C/32T | 16C/24T | 16C/32T |
| 1T score | 2,133 | 1,987 | 1,686 |
| Multi-thread score | 23,701 | 17,272 | 16,508 |
Above, we can see the results from a different Geekbench 5 test submission that showed the Core i9-13900K, which was paired with 32GB of DDR4-6400 memory, boosting to 5.7 GHz. This test showed the 13900K as being 7% faster in single-thread and 37% faster in multi-threaded tests than the previous-gen 12900K. More importantly, it was 26% faster in single-and 43% faster in multi-thread than the Ryzen 9 5950X. Geekbench later removed this result from its database due to a timing error during the benchmark run, so it might not represent the actual performance or boost clock speeds. Given the test results we saw in the full review we shared above, this appears to be close to accurate.
| Core i5-13600K | Core i5-12600K | Core i9-12900K | Ryzen 9 5950X | |
| CPU-Z 1T | 830 | 753 | 803 | 684 |
| CPU-Z nT | 10,032 | 6,692 | 10,921 | 12,078 |
| CB23 | 1,387 | 1,886 | 1,965 | 1,652 |
| CB23 nT | 24,420 | 17,161 | 27,287 | 26,271 |
The Core i5-13600K has purportedly been tested by a known leaker with access to early hardware. These results point to an exceptional amount of performance gains from the extra four e-cores over the previous-gen Core i5. The Core i5-13600K is 8% and 44% faster in the CPU-z single- and multi-threaded tests, respectively, than the previous-gen i5-12600K.
Additionally, the chip beat the Ryzen 9 5950X in both single- and multi-threaded CPU-z benchmarks, and only lagged ~7% in the Cinbench threaded benchmark. A subsequent listing in the GeekBench database was just as impressive, showing similar gains. Bearing in mind that the Core i5 will retail for around $300 and the 5950X retails for over $500, these results are impressive. Overall, the Core i5-13600K is in the range of the current-gen Core i7 in these tests.
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Finally, EXP Review also posted a full review, but it used an Engineering Sample (ES) Core i9-13900 to compare to a Core i9-12900K locked to the same frequencies, thus giving us an idea of potential IPC gains. However, remember that this is still not final silicon, and the chip was tested on a motherboard that isn’t optimized for Raptor Lake yet. The big takeaway is that, at the same clock speeds, the Raptor Lake model was roughly 20% faster in non-gaming multi-threaded work than the Core i9-12900K.
More impressively, the Raptor Lake chip took a 12% lead in single-threaded applications, suggesting we’ll see a significant IPC performance increase that will extend Intel’s lead further over the Ryzen 5000 chips and possibly preserve the lead when AMD’s Zen 4 comes to market. The outlet also ran gaming benchmarks, but the difference between the two chips fell within the margin of error.
Several other rounds of gaming benchmarks have emerged, with one series of tests showing appreciable gains in minimum frame rates, but no significant gains in other metrics. This is hardly surprising because games are very sensitive to poor latency of any sort, like unrefined memory support or motherboard BIOSes. As such, we wouldn’t take the gaming results too seriously until we see the final silicon emerge.
Intel 13th-Gen Raptor Lake Architecture
Intel hasn’t shared the names of the chip microarchitectures that it will etch onto the Intel 7 node for the Raptor Lake CPUs, but rumors indicate the P-Cores will use ‘Raptor Cove’ naming while the E-Cores will stick with Gracemont. However, both cores do have significantly more L2 cache, suggesting a re-working of the underlying designs. We caution that we can’t find any indication of the ‘Raptor Cove’ codename being real, so take that particular naming with a pinch of salt. We do know that software will address the Raptor Cove cores the same as the Golden Cove architecture found on the previous-gen Alder Lake processors, but we’ll have to wait to see if Intel uses a different naming convention.
One thing is for sure: Intel has significantly re-worked the cache hierarchies of both types of cores, so we should expect new code names. The Raptor Lake chip will now share up to 36 MB of L3 cache, representing an increase of 6MB over the previous generation. However, this simply represents the addition of two more 3MB L3 cache clusters and not an increase in per-core cache capacity.
As you can see in the image of the Alder Lake die above, the hybrid architecture pairs a 3MB slice of L3 cache (labeled as LLC) next to each ‘block’ of cores. The P-cores, in dark blue, each have an L3 slice nearby, while the E-cores, in light blue, come in quad-core clusters that also have a 3MB slice of L3 cache nearby. These slices of cache are shared among all cores.
The new Raptor Lake 8+ 16 die (covered in the previous section) comes with 16 E-Cores. Those additional E-Cores would equate to the above Alder Lake die being stretched to accommodate two more light blue quad-core clusters of E-Cores. Those two clusters would come with two more 3MB L3 cache slices, bringing the total capacity to the 36MB we see with the Core i9-13900K.
Interestingly, Alder Lake’s cache scheme introduced a new way for Intel to disable cache for lower core count SKUs. In the past, to create lower-end SKUs with fewer cores, Intel disabled entire slices of L3 cache (the LLC blocks in the image) in lockstep with any cores it disabled. With Alder Lake, Intel transitioned to not disabling any entire slice of L3, instead merely disabling some banks in each slice, thus reducing per-slice capacity (from 3MB to 2MB, for instance). This makes plenty of sense as it keeps stops on the ring bus active, and it also allows for creating SKUs with higher cache capacity than we would typically expect based on the number of disabled cores.
As such, we can’t simply guess the amount of L3 cache per Raptor Lake chip based on the core count alone. Instead, we’ll have to wait to see more detailed information. For now, we simply have confirmation that the Core i9-13900K and Core i9-13900 will come with 36MB of total L3 cache. However, Intel’s new L3 cache policy leaves room for cache capacity improvements on all SKUs that leverage the 8+16 die.
Intel has increased per-core L2 cache capacity for both the P-Cores and the E-Cores. The E-Cores see an increase to 2MB of private L2 cache per core, a 60% increase over the 1.25 MB per core found in Alder Lake. Intel also boosted the amount of L2 cache shared among each quad-core cluster of E-Cores to 4 MB, a doubling over the 2MB with Alder Lake. That means we’ll see up to 32MB of L2 cache. As we’ve seen with Intel’s previous chips that got a big increase in L2 capacity, this type of improvement tends to result in better performance in multi-threaded workloads, but it is possible that it could result in higher IPC in some workloads due to keeping the cores fed with more data. It should also help free the ring from some traffic that would otherwise be present for shuffling around L3 data, thus allowing greater scalability.
The L1 cache for both types of cores remains the same (L1i$ 32kB, L1D$ 48Kb for P-Cores — L1i$ 64kB, L2D$ 32kB for E-Cores).
A leaked roadmap listed a new feature, a Digital Linear Voltage Regulator (D-LVR), alongside the Raptor Lake chips. According to an Intel patent, this feature helps reduce the CPU VID and power consumed by the cores, possibly reducing power consumption by up to 25% in some cases. Naturally, given that it is in a pitched battle for performance supremacy in the desktop PC space, we would expect Intel to use the headroom afforded from those power savings to deliver yet more effective power to the cores. We aren’t sure of this tech’s role in the Raptor Lake chips yet, or how effective it will be (if present). We aren’t sure if this will be used for the desktop PC or mobile chips, or both, but it could be part of Intel’s recipe to improve Raptor Lake’s performance-per-watt.
Raptor Lake’s E-Cores still do not support AVX-512, so we expect that Intel will keep the feature disabled, which is odd given that AMD’s Ryzen 7000 will fully support the extensions. As before, AVX2 and VNNI remain enabled for the E-Cores. We have much more to learn about the Raptor Lake design, but details are still scarce. We’ll update this section as we learn more.
Intel 13th-Gen Raptor Lake 700-Series Motherboards, Z790, H770, B760, H610
The Raptor Lake chips will use the same LGA1700 socket as Alder Lake, meaning they have the same socket and pinout, and both Raptor and Alder will be compatible with both the 600- and 700-series motherboards, providing quite a bit of flexibility for both generations. However, if you use a Raptor Lake chip on a 600-series motherboard, you’ll lose the improvements in PCH PCIe lane configurations that we’ll outline below. All LGA1700 coolers are compatible, so you won’t need a new CPU cooler for Raptor Lake. Naturally, existing 600-series boards will require a BIOS update to support Raptor Lake, and several motherboard manufacturers, like Asus and ASRock, have already released the updates.
Raptor Lake brings a significant number of big steps forward in connectivity. The previous-gen Alder Lake chips support 16 PCIe 5.0 lanes for a discrete GPU and four PCIe 4.0 lanes from the CPU for an M.2 SSD. Those same lanes are still present on Raptor Lake, but a new connection scheme allows for expanded functionality.
For Raptor Lake, motherboard vendors can now split the 16 PCIe 5.0 PCIe lanes from the CPU into dual x8 arrangements, thus enabling support for PCIe 5.0 M.2 SSDs. This does mean that the connection to the discrete GPU will be split into a x8 connection (a switch could be used here), but the existing PCIe 4.0 link from the CPU for an M.2 SSD will also remain active, providing a total of three M.2 SSD ports that hang directly off the CPU.
| PCH Connectivity (up to) | 700-series (Raptor Lake) | 600-series (Alder Lake) |
| PCIe 4.0 | 20 | 12 |
| PCIe 3.0 | 8 | 16 |
| USB 3.2 Gen 2×2 (20G) | 5 | 4 |
Intel itself leaked the 700-series chipset changes. The x8 DMI 4.0 connection between the CPU and the chipset (PCH) remains present, but the chipset also has improvements. In the past, the PCH supported up to 16 PCIe 3.0 lanes and up to 12 PCIe 4.0 lanes, but Intel has increased the number of PCIe 4.0 lanes to 20 and reduced the number of PCIe 3.0 lanes to eight, thus expanding connectivity. Intel also increased the number of USB 3.2 Gen 2×2 (20G) connections from a peak of four to five.
All other PCH connectivity options found with the Alder Lake motherboards remain unchanged with the Raptor Lake chipset itself. However, we will see somewhat different allocations with the Z790, H770, and B760 motherboards based on the new features. You can see Intel’s accidentally-released breakdown, which we’ve independently confirmed, above. The highlighted regions list the changes (Z690 = Z790, H670 = H770, B660 = B760).
Intel Raptor Lake Thread Director
Alder Lake pioneered the hybrid era for x86 desktop PCs, and Intel’s Thread Director, which ensures that threads are placed on the correct cores, is the magic that glues the design together. It’s likely that Raptor Lake will come with improvements to the Thread Director technology, a result of what Intel says is an upgradeable and tunable design that will improve over time.
Just like we saw with Alder, Raptor Lake will use both faster and slower cores that are optimized for different voltage/frequency profiles. As such, unlocking the maximum performance and efficiency requires the operating system and applications to have an awareness of the chip topology to ensure workloads (threads) land in the correct core based on the type of application.
That’s where Intel’s Thread Director technology comes in. This hardware-based technology provides enhanced telemetry data to Windows 11 to assure that threads are scheduled to either the P or E cores in an optimized and intelligent manner, but in a way that’s transparent to software.
This technology works by feeding the Windows 11 operating system with low-level telemetry data collected from within the processor itself, thus informing the scheduler about the state of the core, be it power, thermal, or otherwise. Alder Lake chips will also work fine with a bog-standard Windows 10 operating system – existing thread-scheduling techniques continue to work with the processors, just not as well. While the chips work, you’ll miss out on the enhanced capabilities of Thread Director (that’s Windows 11 only), which will have a varying impact on performance and power consumption based on instruction type and application usage models. In other words, your mileage will vary.
Intel 13th-Gen Raptor Lake Pricing
| Core count | Listing Price, After Conversion – Rumored | Generational Price Increase | |
| Core i9-13900K / KF | 24C / 32T | $725 / $695 | +15% / +18% |
| Core i7-13700K / KF | 16C / 24T | $511 / $483 | +17% / +17% |
| Core i5-13600K / KF | 14C / 20T | $355 / $327 | +16% / +19% |
Intel hasn’t released any official pricing information yet, but we have seen listings at a Canadian retailer. After converting from CAD to USD, we can see that the chips are roughly 15% more across the board (as compared to the listing for the current-gen models at the same retailer). These could be placeholder values, so take them with a grain of salt. However, a price increase wouldn’t be entirely surprising – Intel has announced that it will increase its pricing due to various factors, like inflation and the increasing costs of materials due to supply chain disruptions. Overall, we could see the K-series Core i9 models peaking at~ $725, Core i7 K’s at ~$511, and Core i5 K’s at ~$355, but Intel hasn’t confirmed pricing yet.
Intel has already taken a no-holds-barred bare-knuckle approach to pricing with Alder Lake as it attempts to steal back market share from AMD, so the company does have some room to maneuver. However, Intel recently announced that it would increase pricing due to the increased cost of materials, supply chain disruptions, and inflation, so we can expect Raptor Lake to carry a premium over the prior-generation models. AMD has announced pricing for its Ryzen 7000 processors, and aside from shaving $100 off of its flagship 16-core Ryzen 9 7950X, it remains mostly similar to the previous-gen models. AMD has a high $299 bar for entry to its newest family of chips, showing that the company will continue to prioritize selling its priciest high-margin silicon. Intel hasn’t fully quantified its planned price increases yet, but AMD’s Ryzen 7000 pricing sets a tough bar.
In the end, a lot of the difference in pricing between Intel’s Raptor Lake and AMD’s Ryzen 7000 will boil down to platform costs. We can expect some of the same trends that we saw with Alder Lake motherboards: DDR5-supporting boards will carry a premium over their DDR4 counterparts due to the more expensive manufacturing techniques and materials required to support the faster interface. However, the option for DDR4 motherboards will be a significant advantage over competing Ryzen 7000 platforms, which are DDR5-only. We do expect DDR5 pricing to recede significantly by the time both of these platforms are on the market, but the jury is still out on DDR5 pricing.
AMD’s AM5 motherboard product stack will include provisions for PCIe 4.0-only motherboards, another way to save on cost, while Intel’s lineup won’t have that option. That will provide two tiers of motherboard pricing for AMD, too, but costs will be adjusted on a different axis. It will certainly be interesting to see which approach offers the biggest pricing deltas between the full-fledged implementations.