For the longest time, traditional hard disk drives (HDDs) were the Achilles heel in terms of performance in a computer system. SSDs (Solid-State Drives) have brought a massive boost in computers, and it's safe to say that once you go SSD, there's no going back. Since its birth, they are now even faster and come in a variety of forms. While the price of an SSD held most people back in the beginning, thankfully now it has become ubiquitous due to affordable pricing. If you are searching for high-capacity SSDs, the prices are still not exactly cheap but are in generally faster compared to models with smaller capacities. Choosing the right one for your new upgrade can be time-consuming and confusing, so here's a quick guide to which is which and what goes where. You can check out a previous article for more details about PCI-Express, M.2, mSATA And SATA Express.
Does size matter?
An SSD is primarily made up of a circuit board, some flash-memory and controller chips, so why are there 2.5" SATA (Serial ATA) SSDs? Basically, these drives are made for compatibility, you can easily slip one into a desktop or laptop without any problems. Chances are, you are ready for it unless you have an ultra-slim laptop, in which case you may need one with an ultra-thin profile such as the one below (thickness being the only difference) or a different type of SSD altogether. The maximum performance is up to 6Gb/s through SATA III, generally you are looking to buy one which is faster than 500MB/s. SATA SSDs will not be disappearing any time soon, they still perform very well and current prices are compelling, especially if you want lots of storage for your games! You can also breathe life into an old system gathering dust, if you haven't tried, prepare yourself for a pleasant surprise! You can save some money here by going with SATA II if that's what your motherboard supports (getting SATA III will be a waste).
Basically it seemed at the time there's no reason for these SSDs to be this big so why not make it smaller? Mini-SATA (or mSATA) did exactly that, and removed the shell. The introduction of the mSATA SSD was exciting, since the small form-factor meant thinner and smaller laptops were possible, and thin laptops with multiple storage options also became available. In terms of performance however, mSATA has the same upper limit as SATA SSDs, which is 6Gb/s. mSATA are by no means extinct, but unless this is the only upgrade option you have, take a look at M.2.
NGFF (Next Generation Form Factor) SSDs better known as M.2 is the successor to the mSATA, and has brought about a significant boost in performance by going PCI-Express (instead of SATA). All ROG Maximus VIII motherboards support M.2 SSDs. In the case of the ROG Maximus VIII Impact, U.2 (more on that next) support was chosen over M.2. ROG Rampage V Extreme first introduced a PCI-Express 3.0 X4 interface that has a potential bandwidth of 32Gb/s, compared to 6Gb/s from SATA. Access time also improved dramatically compared to SATA, PCIe has a direct connection to the CPU while a SATA controller increases the latency. From a PC building perspective, one of the best things about M.2 (and mSATA) is that they don't require separate data and power cables, this essentially eliminates cable management! Anyone looking to build a great looking rig is certainly going to love M.2, as there is currently no other solution both faster and more elegant. These do come in different sizes (length), so do check if that is an issue. When buying a new laptop, definitely look for one or even two M.2 SSDs in RAID 0 configuration (ROG G752 / GX700) already installed or a free slot available for upgrades later. As for real-world performance, some M.2 SSDs are up to four times faster than a SATA III SSD, and can single-handedly beat two SATA SSDs in RAID 0 easily.
Hero, Gene and Ranger use an adapter (ASUS Hyper Kit) for U.2 support. Maximus VIII Hero Alpha has two U.2 ports, and I was excited to test them out by connecting up two U.2 SSDs in RAID 0 for ridonculous speeds (see below). For money-no-object extreme performance, here's what you're looking for.
SFF-8639 later renamed to U.2 (so you actually remember it) is another 2.5" SSD like an SATA Express SSD, except U.2 isn't limited by two lanes (up 10Gb/s performance). U.2 utilizes the PCIe 3.0 X4 (denotes four lanes) interface just like M.2, the main difference is that the capacity for these ultra-high-performance SSDs is not bound by a small circuit board size (more space for more flash-memory chips), so you can get higher capacity SSDs. As you can see below in the design of the outer casing, there is also better heat dissipation as they can get rather warm when running at incredible speeds. All the latest Maximus VIII motherboards have U.2 ports, ida="" unicode="" user-select:="" vertical-align:="">PCI-Express
So to answer whether physical size matters, it really depends on the capacity, and also speed which essentially comes down to which interface - SATA or PCIe (which is faster thus hotter, and may require better thermals).
The bus conundrum
You may have found it confusing to find out why some SSDs aren't compatible even though the physical connector is the same. For instance, mSATA has a cousin called mPCIe, and M.2 comes in both SATA and PCIe variants (find out which is which here). The only thing to remember is that PCIe is faster than SATA, and these protocols are not inter-compatible. In short, there's not point in upgrading to a SATA-based M.2 if you're only going to get 6Gb/s max, unless you just want the smaller form factor and you don't like cable management.
What on earth is NVMe?
NVMe (NVM Express or Non-Volatile Memory Express) sounds fast, but what is it? And how come the physical connector can look completely different? Well NVMe allows software to talk to the latest PCIe SSDs, and is the successor to AHCI (Advanced Host Controller Interface) which talks with SATA devices. NVMe allows PCIe SSDs such as U.2, M.2 or PCI-Express SSDs to run at peak performance five times that of SATA with less power consumption. ASUS was the first to offer NVMe support in all X99 and Z97 motherboards!
Just like dropping in a second graphics card for extra performance, you can do the same for your SSDs, and you can do it by using two of the same (or four for that matter) SSDs in RAID 0 configuration. Check out the difference a second SSD can make when two M.2 SSDs are in RAID 0. Today we test out two NVMe U.2 SSDs in RAID 0!
Test bench specs:
CPU: Intel Core i7-6700K
RAM: G.Skill 16GB DDR4 2800
SSD: 2 X Intel 750 Series NVMe U.2 PCIe 3.0 X4
Benchmark
ATTO Disk Benchmark registered a transfer rate of over 3,500MB/s (read) and over 1,600MB/s (write) , HD Tune registered an average transfer rate of 3,105.5MB/s!
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