The Samsung SSD 980 (500GB & 1TB) Review: Samsung's Entry NVMeby Billy Tallis on March 9, 2021 10:00 AM EST
The new Samsung SSD 980 is the first retail-ready entry-level NVMe SSD from Samsung. Compared to previous SSDs from Samsung, it lacks any three-letter suffix at the end: it's not a PRO, nor an EVO, or even a QVO drive, because it doesn't fit into the established conventions for those product tiers. The SSD 980 slots into the product stacl at the bottom, but leaves a big enough gap for another, possibly better, model to come in later. Samsung is marketing the SSD 980 as a successor to the 970 EVO.
Samsung's First Push into Entry NVMe at Retail
The SSD 980 is an entry-level NVMe SSD, using TLC NAND with a DRAMless controller. This makes it a new class of product for Samsung in the retail market, one it has never produced before. This kind of drive, with TLC and without DRAM, is already prevalent in the market from other turn-key solution vendors, and this type of drive has been quite popular with OEMs: it allows them to advertise a NVMe SSD without paying the cost of a high-end drive.
The new Samsung SSD 980 will come in three capacities, 250 GB, 500 GB, and 1 TB. In this review we have the two highest capacities, featuring a Samsung custom controller and a variety of TLC NAND (explained more in detail below). As an NVMe drive rated for PCIe 3.0 x4, peak sequential read speeds are rated up to 3.5 GB/s for the 1 TB drive. The drives will be rated up to 0.3 drive writes per day (so 300 GB/day on the 1 TB model) for five years.
|Samsung SSD 980 Specifications|
|Capacity||250 GB||500 GB||1 TB|
|Form Factor||Single-Sided M.2 2280|
|Interface||PCIe 3.0 x4, NVMe 1.4|
|NAND Flash||Samsung 128L 512Gb TLC|
|Sequential Read||2900 MB/s||3100 MB/s||3500 MB/s|
|Sequential Write||1300 MB/s||2600 MB/s||3000 MB/s|
|Max SLC Cache Size||45 GB||122 GB||160 GB|
|Power||Read||3.7 W||4.3 W||4.5 W|
|Write||3.2 W||4.2 W||4.6 W|
|Idle (L1.2)||5 mW|
|Write Endurance||150 TB
The Samsung SSD 980 is built around its "Pablo" controller. This isn't actually a new NVMe controller, but it has has been shipping in the Samsung Portable SSD T7 family for over a year. This controller has half as many NAND channels as the controllers used in Samsung's high-end NVMe drives (four rather than eight), and no DRAM interface. Using the high NAND IO speeds supported by recent generations of 3D NAND, the Pablo controller is able to saturate a PCIe 3.0 x4 host interface with out needing eight NAND channels.
The NAND is the same 512Gbit 128-layer 3D TLC found on the 2TB 980 PRO. Lower capacities of the 980 PRO get the smaller 256Gbit 128L parts, but on the plain SSD 980 Samsung is using the larger capacity die across all three drive capacities. The smaller 980 PRO models need to use the smaller dies in order to make full use of the 8-channel controller, but the plain 980 with a 4-channel controller speed is less of a priority and the 512Gbit dies should be slightly cheaper.
(Note: This review initially stated that Samsung was using 256Gbit 92L TLC on our 500GB SSD 980 sample and speculated that they were doing so on the 250GB model as well. Samsung has since confirmed that it's the 512Gbit 128L on all capacities, meaning we misread a 0 as a D in the NAND package part number.)
Updates with the SSD 980
With the SSD 980, Samsung has shifted to a more aggressive SLC caching strategy, more than tripling the maximum size of the cache as compared with the 970 EVO (Plus). They made a similar shift with the 980 PRO. This is following a general industry trend toward larger SLC caches, most noticeable on QLC NVMe SSDs, which helps improve performance on many benchmarks and some real-world workloads. While good for performance numbers in short burst tests, it typically comes at the cost of performance when the cache fills up, or the drive fills up. For an entry-level drive that isn't intended for heavy workstation type workloads, this optimization toward peak performance makes a lot of sense.
Even though it's a more low-end product than any of their previous NVMe SSDs, Samsung is still giving the SSD 980 a five-year warranty with a 0.3 DWPD endurance rating, the same as all their recent EVO-tier drives.
A key part of Samsung plans to achieve good real-world performance with the SSD 980 is the NVMe Host Memory Buffer (HMB) feature, which we have covered in depth in the past. In brief: the DMA capabilities of PCIe allow an NVMe SSD to efficiently access the CPU's main memory/DRAM. The NVMe host memory buffer feature allows the operating system to give the SSD a small amount of DRAM to use for the SSD's own internal bookkeeping. Performance isn't as good as having DRAM on the SSD itself, and the amount of memory allocated is usually pretty small, default of around 64 MB but up to 1 GB, but it's enough to improve performance on a lot of real-world workloads.
Assuming the drive's Flash Translation Layer has a typical design, a HMB of 64 MB is enough to cache the logical to physical address mappings for about 64GB of storage. That's a very tiny amount of host RAM, but 64 GB of storage is a lot more than typical consumer workloads need to actively use at one time. The key part here is 'in use' - the HMB will only fill (and expand) as data is used in the drive for that session. So even though a top game might be 250 GB to install, it might only use 50 GB to play on a particular level.
|NVMe Host Memory
|Samsung 980||16 MB||64 MB|
|WD Blue SN550||3 MB||32 MB|
|Mushkin Helix-L||32 MB||64 MB*|
|Toshiba RC100||10 MB||38 MB|
The Samsung SSD 980 requests 64 MB of host ram for its HMB, but is willing to make use of as little as 16MB. These values are similar to other DRAMless NVMe SSDs we've tested. For this review, we've run the synthetic benchmarks with HMB enabled (the default on recent operating systems) and with HMB disabled to illustrate its impact.
The exception is the Mushkin Helix-L with the Silicon Motion SM2263XT controller: we didn't see any significant performance differences between HMB on and HMB off even on tests designed specifically to illustrate the effect of HMB, so it's pretty clear that drive's firmware never gets around to actually using the 64MB it asks for.
Samsung and Entry Level: The History
Historically, Samsung has distanced itself from making true entry-level drives for the retail SSD market, preferring to hold onto some degree of premium status and retain a more comfortable profit margin. This is a strategy that it's vertical integration has supported very well.
Samsung has covered some of the low-end before however, with the QLC QVO SATA SSDs. But even here, Samsung has retained slightly premium prices, so the main appeal has been how affordable these drives are at the extremely large capacities. Samsung has not yet brought QLC NAND to their consumer NVMe product line, so the other obvious formula for a low-end drive is to go DRAMless while sticking with TLC NAND.
The break from Samsung's typical PRO/EVO/QVO split is not entirely without precedent: in the past there have been a few other occasions where Samsung has needed an extra product tier, resulting in the 750 EVO and SSD 850. Since then, Samsung has added the QVO tier of products, but the 980 doesn't qualify because it's using TLC NAND rather than QLC. Samsung also doesn't have room to decrement any part of the model number since there's no gap left between their 800-series SATA SSDs and 900-series NVMe. So we're left with the plain 980 while Samsung keeps a spot open for a better 980 EVO.
We weren't able to review the WD Blue SN550 when it launched at the end of 2019, but we obtained a sample to include in this review because the SN550 is the most important competitor to the Samsung SSD 980. The earlier WD Blue SN500 significantly raised the bar for DRAMless SSDs, and the SN550 improves on it in almost every way. The Samsung SSD 980 is rated for much higher peak performance on sequential and random IO, but for more real-world workload the SN550 won't be so easy to beat. We also have results from the older Mushkin Helix-L, though with apparently inoperative HMB support it's nowhere near as competitive. Also in the low-end NVMe market segment we have a pair of QLC drives: the Corsair MP400 with the 8-channel Phison E12 controller, and the Intel SSD 670p with the new Silicon Motion SM2265 controller.
In the more mainstream TLC NVMe market segment, the drive to keep an eye on is the SK hynix Gold P31. Like the Samsung SSD 980 it uses a four-channel controller, but the P31 has the usual full amount of on-board DRAM which makes it a higher class of drive. If Samsung releases a 980 EVO in the near future, it will almost certainly go after the P31's position in the market, though Samsung may also try for a slight performance advantage by including PCIe gen4 support.
We also have results from several other recent Samsung SSDs in different market segments: the 870 EVO TLC SATA, 970 EVO Plus high-end PCIe Gen 3, and 980 PRO high-end PCIe Gen 4. The latter was re-tested with updated firmware a few weeks ago, but we didn't find any notable performance changes with our test suite.
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Oxford Guy - Tuesday, March 9, 2021 - linkIntel is really not the best company to compare with. Intel is obsessed with QLC nonsense even more than Samsung is, it seems. And, Intel is rubbing its mitts together about foisting PLC onto the public, as if its new 9000 series FX CPUs aren't enough of a disaster.
I have had good results with the Inland TLC drives, both in SATA and in NVME format. However, Gigabyte designed one of the motherboards I have so idiotically that the Performance Plus drive can't be used. The NVME slot is too close to the CPU socket (hits my EK block) and the expansion slot (hits that, too). One would think an ATX board with one NVME slot could be done intelligently, especially with what was once the top chipset.
Due watch with Inland, though, because the product naming is not nearly as clear as it should be. There are "Premium" and "Professional" drives, for instance — as if there is some kind of clarity there.
Slash3 - Tuesday, March 9, 2021 - linkI've replied to one of your previous posts about this NVMe issue, but as it seems to be your favorite campfire story so I'll try digging a bit deeper this time.
NVMe M.2 drives fit fine on that motherboard. It's a close fit, but nobody else has had the same difficulties. If the drive doesn't fit, it means it isn't installed correctly or has an oversized heatsink on it. Since the Inland drives don't ship with a heatsink, that means it's not lined up properly in the slot.
That EK uses a weird, oversized mounting bracket isn't Gigabyte's fault. It's not Inland's (Microcenter's) fault. It's an EK problem.
Do you still have the drive? Do you own a dremel? You probably need to shave a chunk out of that waterblock bracket to allow clearance.
Failing that, grab a $13 NVMe M.2 to PCI Express x4 AIC adapter off of Amazon, or the vendor of your choosing. You can mount the drive in the last slot (PCI Express 3.0 x4) with no performance penalty, it'll be far from your cursed EK bracket, and you'll save hours by not having to bring it up in every article. ;)
Oxford Guy - Wednesday, March 10, 2021 - linkIncorrect.
1. The drive’s PCB hits the waterblock bracket.
2. The drive does have a heatsink and it is an Inland.
3. It’s impossible to install an NVME drive incorrectly as long as one know how to push the edge connector all the way in.
4. ‘Oversized’ says who? ATX is a big board. One slot on the board. Gigabyte couldn’t manage to put it in an intelligent place.
Oxford Guy - Wednesday, March 10, 2021 - linkYou seem intent on blaming everything but Gigabyte but the fact is that the drive also hits the slot. It doesn’t just hit the EK bracket. It hits the slot as well!
Gigabyte is at fault.
Slash3 - Thursday, March 11, 2021 - linkNothing of the sort, I'm just mystified as to how a standard NVMe M.2 seemingly won't fit on that board, since it's not at all difficult to find pictures of an NVMe M.2 mounted in that exact slot.
I do owe you an apology, though, with regard to the heatsink statement! If you've got the Inland Performance Plus (Gen4 - on a Z390?) NVMe M.2, they do indeed have a heatsink, similar to that on the Corsair MP600.
That said, it doesn't seem to extend past the edge of the PCB more than a millimeter or so. My assumption is that even without the heatsink, the bracket would still be contacting the PCB from the way you've described it - it might clear the x1 slot side in this kind of stark naked configuration, but the other edge would still be blocked, which wouldn't do you much good.
No argument that the board's got the M.2 slot in a very funky place, but it's absolutely fair to point a finger at the EK bracket, too.
I think I referenced a similar image before, but here's a regular NVMe M.2 happily existing in the troublesome slot via some stock imagery:
Cozy, but it works!
I'd still look into the cheap slot adapter route - it's not an elegant solution, but it'll work just as well and won't keep you up at night cursing Gigabyte into the early hours. ;)
Oxford Guy - Thursday, March 11, 2021 - linkThe EK bracket is just one part of the problem. The PCB also hits the slot.
So, even with no EK bracket the board is unacceptably poorly designed.
edzieba - Tuesday, March 9, 2021 - linkOof, those latencies! For basically the same price, I'd take the "way overpriced" 670p over this any day of the week! Peak transfer rates are worthless, SSDs live or die by their random read latencies for perceived performance.
cyrusfox - Tuesday, March 9, 2021 - linkBut on all the marketable metrics it is a win, Right Brand, highest sequential numbers. Any conversation more nuanced doesn't matter to the majority. They have a hit on there hands and with how economical the design is the margins should be good enough, solid win for Samsung.
GREAT Expectations - Tuesday, March 9, 2021 - linkLiterally in the first paragraph: "product stacl"
XacTactX - Tuesday, March 9, 2021 - linkThe performance send very good with an empty drive but it really drops off when the drive is full of days. In the ATSB Heavy benchmark the performance for from 936 MBps to 496 MBps. I wonder how much free space we have to keep in the drive so the performance will stay closer to 936 MBps