In December, Intel announced a wave of new products based around its 144-layer 3D NAND and second-generation 3D XPoint memory, however these were all enterprise focused, and we've been waiting for a consumer variant to come to market. That product has now arrived: the Intel SSD 670p.

This is Intel's third generation of consumer NVMe SSD to use QLC (four bit per cell) NAND flash memory. The new 670p is the biggest update yet, bringing not only the next generation of QLC NAND, but also a major upgrade to the SSD controller. The Intel SSD 670p is launching today as a retail product, and will be used by major PC OEMs starting in April. Based on the pricing, it looks like Intel is solely targeting OEMs with this device. Update: Prices have been slashed just one day after launch, to very reasonable levels for a newly-launched retail product.

Intel's QLC Efforts: Past to Today

As a brief refresher, the first consumer QLC SSD was the Intel SSD 660p, launched in 2018 and based on their 64-layer 3D QLC and the Silicon Motion SM2263 controller. This drive (and the similar Crucial P1) proved that QLC NAND was a viable choice for entry-level consumer NVMe SSDs. Since then, that market segment has been largely divided between DRAMless TLC drives that are preferable at lower capacities, and QLC SSDs with DRAM caches that are competitive at and above 1TB.

In late 2019, Intel introduced a follow-up 665p. This upgraded to 96L QLC to provide slightly improved performance and endurance. The 512GB capacity was dropped and the firmware was tweaked to allow for larger SLC cache sizes on partially-filled drives. The 665p turned out to be a pretty short-lived drive: Intel announced in August 2020 that the 665p would be discontinued with a last-order date at the end of January 2021. Meanwhile, the 660p is still on the market.

Intel 670p: A New Budget QLC Offering

Bringing us to the present, the new Intel 670p is rolling out with Intel's latest QLC NAND as well as a much-needed update to the SSD controller. Because the 665p is already off the market, Intel's marketing materials for the 670p take the unusual approach of comparing the 670p against the earlier 660p and largely ignoring the existence of the 665p, allowing Intel to slightly overstate the generational improvements and re-announce some advances (such as the larger SLC caches) that were already introduced by the 665p. The 670p brings back the 512GB capacity (ill-advised as it may be) and appears to be intended as a more complete replacement for the 660p.

The 670p is PCIe 3.0 x4 drive, desite it being new to market. This is because it reimagines Intel's positioning in the budget NVMe market, and going to something faster is seen as a premium play today.

Intel SSD 670p Specifications
Capacity 512 GB 1 TB 2 TB
(tested)
Controller Silicon Motion SM2265G
NAND Flash Intel 144L 1Tbit 3D QLC
DRAM Nanya 256MB DDR3L-1866
Form-Factor, Interface single-sided M.2-2280
PCIe 3.0 x4, NVMe 1.4
Sequential
Read (MB/s)
QD64 3000 3500
QD1 2200 2200
Sequential
Write (MB/s)
QD64 1600 2500 2700
QD1 1250 1700
Random
Read IOPS
QD64x4T 110k 220k 310k
QD1 20k 20k 20k
Random
Write IOPS
QD64x4T 315k 330k 340k
QD1 54k 54k 54k
Warranty 5 years
Write Endurance 185 TB
0.2 DWPD
370 TB
0.2 DWPD
740 TB
0.2 DWPD
SLC Cache Minimum 6 GB 12 GB 24 GB
Maximum 70 GB 140 GB 280 GB
Recommended
Customer Price
$89.99
(18¢/GB)
$154.99
(15¢/GB)
$329.99
(16¢/GB)
Updated Retail Price $69.99
(14¢/GB)
$129.99
(13¢/GB)
$249.99
(12¢/GB)

As we detailed last month, Intel's new 144L QLC NAND is a considerable improvement over their 96-layer generation. Aside from the density increase, it brings slightly lower read latencies, more significant improvements to write latency and throughput, and a few other features to improve performance. The density increase should help further reduce costs, but Intel has fallen behind the rest of the industry in the layer-count race and had to adopt triple-deck string stacking in order to reach 144 layers, so their cost savings won't be as significant as competitors who should be able to reach similar QLC densities with their double-deck designs of 162-176 layers.

Terminology Info: NAND companies build 'decks' of 32-96 layers of bits, and then combine decks to get a total number of layers. Building more layers in a single deck is difficult, and so combining decks gives a higher total number of layers. Typically the companies that can put more layers in a single deck are said to have a more advanced process. Most companies use two decks to reach 150+ layers, while Intel uses 3 decks of 48 layers in this product to reach 144 layers .

The new 144L QLC has also enabled Intel to increase their write endurance ratings again. The 670p's write endurance is 23% higher than the 665p and 85% higher than the 660p, at roughly 370 write cycles. Which spread out over 5 years, works out to 0.2 drive writes per day (DWPD). More importantly, at 0.2 DWPD Intel's QLC SSDs aren't that far behind the 0.3 DWPD that most consumer TLC SSDs are rated for.

Intel QLC SSD
Write Endurance
  512GB 1TB 2TB
660p 100 TB 200 TB 400 TB
665p   300 TB 600 TB
670p 185 TB 370 TB 740 TB

While the new NAND in the 670p certainly helps, it owes most of its improved performance to the upgraded SSD controller. The SM2263 controller used in the 660p and 665p is a low-cost 4-channel controller, appropriate for the entry-level market segment but seriously outdated. In particular, it is limited to IO speeds of 667 MT/s between the controller and the flash, which means that even with the fastest flash it cannot come close to saturating the PCIe 3.0 x4 host interface and struggles to go beyond about 2.4GB/s.

For the 670p, Intel has switched to the Silicon Motion SM2265. This controller hasn't been officially announced or documented by Silicon Motion, but a few references to it have popped up previously (though half of them are typos of the SM2256 SATA SSD controller). During the press briefing Q&A for the 670p, Intel stated the controller was a SM2262—the 8-channel controller from the same generation as the SM2263. So it's possible that the SM2265 is a more compact packaging of an SM2262 variant, much like the Phison E12S that's now used on many drives to make room for four NAND packages on the top side of the M.2 PCB.

Also possible is that the SM2265 may be more closely related to the SM2264 and SM2267 PCIe 4.0 controllers. The SM2267 is a four-channel controller and one of the first shipping PCIe 4.0 SSD controllers that is aimed at mainstream market segments rather than the high end. The package size for the SM2265 is the same as the SM2263 and SM2267 which suggests it's a four-channel controller (though the SM2267 actually has a higher pin count than the SM2262), and the performance means it would have to be supporting a higher IO speed on those four channels: closer to the SM2267's 1.2 GT/s rather than the 667 MT/s supported by the SM2263. In terms of features, the SM2265 seems to be a better fit with the SM2262/2263 generation: PCIe 3.0 instead of PCIe 4.0 and 8 queues instead of 15. The SM2265 may have inherited the upgraded error correction capabilities that Silicon Motion developed for the SM2264/2267 generation to better support QLC NAND. Overall, the SM2265 appears to be a mix of old and new, producing an updated low-cost controller that's better-suited to the remaining use cases for PCIe 3.0.

The layout of the Intel 670p is a lot less crowded than the 660p/665p: they're now using only two NAND packages to reach 2TB rather than four packages. Since the new 144L QLC is still manufactured with the same 1Tbit capacity per die, Intel's simply stacking more dies in each package. With this layout, Intel could have easily fit a controller the size of the 8-channel SM2262, but for the upcoming Optane Memory H20 they'll need to fit all these components into half the space to make room for the Optane half of that device.

Top: 1TB Intel 660p, Bottom: 2TB Intel 670p

 

The Competition

Aside from test results for the earlier Intel SSD 660p, this review includes results from the following competing products:

  • Phison E12 SSDs with QLC NAND, represented here by the 1TB Corsair MP400 and 8TB Sabrent Rocket Q
  • Mushkin Helix-L 1TB: TLC NAND and Silicon Motion SM2263XT DRAMless controller
  • HP EX950 2TB: TLC NAND and Silicon Motion SM2262EN 8-channel controller
  • SK hynix Gold P31 1TB: Probably the best 4-channel NVMe SSD on the market
  • Samsung 970 EVO Plus 1TB and 980 PRO 2TB: High-end TLC SSDs supporting PCIe 3.0 and PCIe 4.0 respectively
  • Samsung 870 EVO 1TB and 870 QVO 1TB: The latest TLC and QLC SATA SSDs
  • SK hynix Gold S31 1TB: Mainstream TLC SATA

 

Trace Tests: AnandTech Storage Bench and PCMark 10
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  • bananaforscale - Wednesday, March 3, 2021 - link

    Fascinating. I have a Netgear GS810EMX connected to an Aquantia AQC-108, and the NIC has issues in Linux when it's receiving lots of data, but works fine in Windows.This requires further research.
  • justaviking - Monday, March 1, 2021 - link

    A MATTER OF PERSPECTIVE...

    Billy wrote: "More importantly, at 0.2 DWPD Intel's QLC SSDs aren't that far behind the 0.3 DWPD that most consumer TLC SSDs are rated for."

    A 0.1 DWPD difference might not sound like it is "that far behind," but on the other hand that is 33% behind, and 33% *is* significant.
  • Billy Tallis - Monday, March 1, 2021 - link

    My thinking is that the 33% difference on paper is a lot less significant than it looks at first glance, because most consumers won't come close to crossing either limit. If 0.1 DWPD is probably sufficient for your usage and 0.2 DWPD definitely is, then 0.3 DWPD doesn't really have much added benefit.
  • frbeckenbauer - Monday, March 1, 2021 - link

    I bought a Samsung PM9A1 for 115€. What is intel doing with these prices? A 1TB QLC SSD should be the price they're offering here for the 512GB version.
  • Machinus - Monday, March 1, 2021 - link

    You can still run linux on an X-25E RAID for the next 100 years.
  • MDD1963 - Tuesday, March 2, 2021 - link

    Intel does not Eff around when you have used up your allotted writes....; good or bad still, you are damn well done writing once you've used them up!
  • Hifihedgehog - Monday, March 1, 2021 - link

    Hey Billy. What is the best 240-256GB NVMe today? I am looking for something under $50 that is the fastest there is currently for system boot times and mixed I/O.
  • Tomatotech - Tuesday, March 2, 2021 - link

    To start with I wouldn't buy a 256GB NVME. Speed scales with size quite well for NVME, and the difference from 256 -> 512 -> 1TB is astounding. Go for a 1TB. This is going to be the fastest drive on your system by far, and more fast space is always useful.

    The next thing is make sure you get a drive that folds *all* (or almost all) unused space into SLC space. This means that with an empty 1TB TLC drive, you get 330GB of high-speed SLC space. Smaller drives give you far less cache space. My 1TB is about 500GB full, means I still have about around 150GB SLC storage left. (it's a 2018 Adata SX8200 1TB, non-pro).

    Beyond that, eh, from a user perspective they're all roughly equal, look at the table on the last page of the article. Used 1TB NVMe drives are a good buy too, there's not much that can go wrong with them, and if there is, you'll find out on first boot. The only things I would check for in a used working NVME drive is a) total writes, but it's extremely rare for that to be excessively high; and b) run a speed test - if that seems slow, then do a full secure erase and the SSD should be back to full performance, but even that is rarely needed with modern OSes.
  • Hifihedgehog - Tuesday, March 2, 2021 - link

    My price point was $50 and under so you ignored a key point from the very beginning.
  • abufrejoval - Tuesday, March 2, 2021 - link

    USB sticks are used all over the place for booting.

    And you get relatively fast µSD-cards which you could combine with a USB reader-stick.
    A "class 10/A2" rating card can be had at many capacity points where NVMe no longer goes.

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