While there are merits to both Solid State Drives and Hard Disk Drives, the choice at this point is clear — you need an SSD. The price advantage HDDs once held is quickly slipping, and unless you have 1TB or more of data to store, you should buy a system with an SSD. They provide a noticeable bump in performance during boot-up times and data movement, often clocking in at five times faster than the speeds possible on an HDD.
First, let’s take a look at the difference in size — meaning data capacity — between hard drives and solid state.
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It isn’t difficult to find HDDs with several terabytes worth of storage. In contrast, SSDs don’t hold quite as they become prohibitively expensive over 2TB, and are more expensive along the way. When comparing storage capacity, HDDs currently beat out SSDs. Of course, SSDs come with their own advantages over HDDs, which we’ll discuss more later.
HDDs have been the standard for desktops and many laptops, as their large storage capacities mean one doesn’t have to worry about running out of storage space too quickly, and their magnetic storage method means they have near-infinite read/write capabilities.
Storage capacity — while certainly the most important criteria to consider when buying a hard drive — is not the only difference between these two technologies. On the next page, we cover how HDDs and SSDs differ in terms of speed, form factor, and durability.
Speed, Form Factor, and Durability
When discussing the speed of HDDs and SSDs, what is being referred to is the speed at which they can read and write data.
For HDDs, the speed at which the platters spin helps determine the read/write times. When accessing a file, the “read” part of the read/write head notes the positioning of the magnetic sections as it flies over the spinning platters. As long as the file being read was written sequentially, the HDD will read it quickly. However, as the disc becomes crowded with data, it’s easy for a file to be written across multiple sections. This is called “fragmenting” and leads files taking longer to read.
With SSDs, fragmentation is not an issue. Files can be written sporadically across the cells — and in fact are designed to do so — with little impact on read/times, as each cell is accessed simultaneously. This easy, simultaneous access to each cell means files are read at incredibly fast speeds — far faster than an HDD can achieve, regardless of fragmentation.
This faster read speed comes with a catch. SSD cells can wear out over time. SSD cells push electrons through a gate to set its state. This process wears on the cell and over time reduces its performance time until the SSD wears out. That said, the time it would take in order for this to happen for most users is quite long; one would likely upgrade their SSD due to either obsolescence or a desire for more storage space before a normal SSD would fail. But it’s still something to keep in mind.
The risk for failure is not unique to SSDs. In fact, SSDs are considered far more durable than HDDs, due to a lack of mechanical parts. The moving mechanisms within an HDD are susceptible to not only wear and tear over time, but to damage due to movement or forceful contact. If one were to drop a laptop with an HDD, there is a high likelihood that all those moving parts will collide, resulting in potential data loss and even destructive physical damage that could kill the HDD outright. SSDs have no moving parts so, while they hold the risk of a potentially shorter life span, they can survive the rigors we impose upon our portable devices and laptops.
Another thing to be mindful of is the form factor of these devices. HDDs are almost always a 3.5-inch or 2.5-inch disk, while SSDs are spreading out into a variety of shapes and sizes. The most common is still the 2.5-inch drive, a slim plastic board with two plugs on one side. Newer desktops are fitted with a place to mount these specific drives, but they can also be mounted into the 3.5-inch brackets with an adapter. While there are SSDs that mount into the PCIe slot, many are now compatible with the relatively new M.2 slot. This thin port, found on the motherboard, allows placement of the drive without cables, and enables extremely high transfer speeds.
Next, we’ll look at how the two drive types compare in pricing.