Ssd is heating up. Will an SSD prevent my laptop from overheating? Solutions collect form web for “Will an SSD prevent my laptop from overheating?”

For greater convenience for site visitors, we have combined all the important aspects into one single material, in which you can find answers to most questions related to SSDs.

F.A.Q. is in a constant and dynamic growth mode. The number of questions and answers will expand as new materials are added! But if you are sure that there are certain questions that are undeservedly left unanswered, then send your wishes to the email address. Where possible and based on appropriateness, all important comments and questions will be added to the global F.A.Q.

Theory:

IN: What is it anyway?SSD?

ABOUT: SSD is a solid-state drive, that is, a storage device based on semiconductor elements. Read about the history, differences from HDD and advantages in the material “”.

IN: What are thereSSD?

IN:I often see things being discussed whereSSD, abbreviations are also found thereSLC/MLC, what is it and is it important?

IN: What is the TRIM command and similar?

ABOUT: Due to the specific operation of the device, in order to maintain its speed characteristics, it is highly desirable that it support TRIM or similar technologies. You can find out what TRIM is.

IN: I had a hard drive all the time and there were no problems, I don’t know why I need itSSD?

ABOUT: An SSD outperforms a hard drive in many respects; however, there are situations when it is really not needed or is not suitable for the user as a storage system; we recommend that you read the article “”.

IN:How can I find out what I will get approximately if I change the hard drive toSSD, without the vague concept of “faster”?

ABOUT: The material “” has been written especially for you, which discusses very specific situations of using SSDs in home system of the average user.

IN: I have an old computer (or netbook), it works quite slowly, would it make sense to installSSD in it?

ABOUT: Yes, it will. Despite the fact that, of course, a semiconductor drive will not be able to fully “open up” while being in the same simple netbook, it still significantly increases the speed of the device.

IN: It’s easy to restore information from a hard drive in the service if it breaks, but they say that this cannot be done on an SSD?

IN:I don't need a big oneAn SSD, but perhaps a small one won’t be enough, does the volume of the device affect anything important?

ABOUT: Yes, it does. Small-capacity SSDs are the weakest in the line and are significantly reduced in terms of write speed, which can “harm” adequate operation of the OS, especially since SSDs cannot be filled to capacity, nothing good will come of it. The operation of cleaning algorithms and the wear resistance of the device will become more complicated.

IN:Why someSSDs have capacities of 40 GB, 60 GB, 90 GB, 120 GB and so on, and some are 32 GB, 64 GB, 128 GB...

ABOUT: This may depend on the number of memory chips installed. For example, a 40GB SSD is obtained because it uses 10 4 GB chips, or 5 8 GB chips. It also happens that the developer installs “spare chips”, or uses some of those already available as a reserve, which will be used, over time, to maintain the speed and reliability parameters of the drive. There are cases when the developer refuses this, releasing firmware that opens all available memory to the user.

IN:Which controller should I choose an SSD on?

Practice:

IN: Which operating system is best to use to work withSSD?

ABOUT: It is best to use Windows 7 starting with SP 1 and subsequent OS versions.

IN: And I need to putWindowsXP! Is it possible to install it onSSD?

ABOUT: It is possible, but there is a nuance (C). Windows XP was not designed to work with SSDs. For example, it does not include the execution of the TRIM command, as well as disabling some options when working with a solid-state device, which can cause some harm to the drive.

IN: MyThe SSD gets very hot during operation, is this normal?

ABOUT: Solid-state drives are much more temperature-resistant than traditional hard drives, however, on some (mostly capacious and fast) models, serious heating has been observed during operation, to the point that the SSD is unpleasant to hold in your hands. The issue of the influence of temperature on new drives has not been fully studied, so you should not take risks and it is better to place the SSD in a ventilated basket.

IN: Computer withThe SSD suddenly began to issueBSOD and sometimes during startup it does not find the drive at all.

ABOUT: Try following the “5 steps” from the article “”.

IN: How to check speedSSD?

ABOUT: Use free utilities, information about which can be found in the ""..

IN:Which controller mode should I choose, IDE or AHCI, and what is the difference between them?

IN: How to flashSSD?

ABOUT: Different firmware methods are used for different drives. The best place to find instructions is on the manufacturer's website. But we also have examples:

IN: A follow-up question: is it worth flashing at all?SSD, everything seems to work fine?

ABOUT: The firmware needs to be changed. New versions do not appear on their own; manufacturers do not just improve the device, providing faster operation, but most often fix it critical shortcomings that led to errors and sometimes loss of information.

IN: I want to replace the hard drive in my laptop, but at the same time I want to transfer the OS to it so as not to reinstall anything. How can this be done?

ABOUT: The easiest way would be to purchase a device with a special cable and software to create a clone of the system image. Drives with this configuration cost on average 200-600 rubles more than their analogues, but they come with guaranteed working and compatible software/hardware. Very often the programs there are designed to work with this operation, so you can do it simply and quickly, as in. As an alternative, you will have to look for similar SATA-USB adapters.

It's no secret that high-speed NVMe models such as Samsung 960 Evo(Pro), Plextor M8SeGN and others like them are susceptible to overheating. Moreover, some models are produced with a pre-installed radiator, while others are produced without. And this may cause concern, given the high read-write speeds specified in the specification. Large numbers, unfortunately, not only warm the soul and stroke the ego, but also warm the device itself. So I came across a material on the resource uk.hardware.info, where SSD cooling is discussed, radiators are tested for, the results of which I suggest you familiarize yourself with.

The essence of the problem

The issue of heating and, accordingly, cooling did not arise when it came to drives on the SATA bus. The operating temperature in them is good in any conditions, even in the absence of airflow. Heating began to manifest itself when switching to the much faster PCIe bus, when read or write speeds exceeded 1 GB/s.

Update. 10/24/2018. By the way, this is not entirely true. Still, even some drives on the SATA bus, albeit in the 2.5-inch form factor, tend to noticeably heat up, as shown by testing results, for example, or. Thermal padding on the controller and/or memory chips or airflow is still desirable in some cases.

And the higher the speed, the hotter the drive became. This forced the release of models with a heat-dissipating radiator already installed. At the same time, the same drive model could have a modification without such thermal protection.

Motherboard manufacturers themselves try to combat possible SSD overheating by supplying their models (mostly in the mid- and high-end price ranges) with radiators included. Unfortunately, not all motherboards have this option.

The problem is further aggravated by the fact that the M.2 connectors on the surface of the motherboard are not located in the most optimal places from a cooling point of view. Thus, a drive installed between two PCI-Express connectors, which contain one or even two powerful video cards, is sandwiched between these two “stoves”, which do not at all improve working conditions.

Hence the conclusion that drives need to be cooled, especially since temperatures can be very serious. Thus, the Samsung 960 Pro with a capacity of 512 GB used as a test subject in the Atto Disk Benchmark test, the controller heated up to 111°C, and the memory chips – up to 71°C. Needless to say, this is a bit much.

Naturally, throttling appeared, and read speeds dropped from more than 3 GB/s to 2.4 GB/s, while write speeds dropped from 2 GB/s to less than 1.7 GB/s. One might assume that the drop is not that big, but firstly, why then buy a drive that cannot be used to its full capacity. And secondly, it's simply dangerous. After all, if something happens, not only the piece of iron, but also the data stored on it will go to another world.

To be fair, it must be said that blowing bears fruit. Installing a 92mm fan at a distance corresponding to the front wall of the middle case reduces the temperature of the controller to an acceptable 79°C. The problem is that this is under ideal conditions. Will you be able to provide the drive with a constant flow of air that is not obstructed by any other elements, wires, etc. specifically in your computer? Whatever one may say, additional cooling is highly desirable.

Test participants

The test subject has already been mentioned; this is the Samsung 960 Pro. But 8 models acted as radiators, most of which were standard heat-dissipating covers from motherboards, but there was one more participant. We are talking about the recently released radiator for SSD M.2 by EK.

This manufacturer is well known for its cooling systems, primarily liquid ones. This radiator is a fairly tall design with deep fins, which allows us to hope for efficient cooling.

Other radiators included in motherboards:

Small heatsink from ASUS ROG Strix Z370-I Gaming.
Heatsink from ASUS ROG Maximus X Hero.
Heatsink from ASUS TUF X299 MARK 1.
The largest option is from ASUS ROG Strix X299-XE Gaming, which is a cooler for both the drive and the chipset.
Modest in size, thin piece of hardware from Gigabyte, which has several small ribs.
An even more modest version of M.2 Shield from MSI.
And a more solid version from the same manufacturer, called “M.2 Shield Frozr”.

Radiators EK

I’ll make a short digression to get acquainted with the recently released heatsinks for NVMe drives from the Slovenian company EKWB. The design consists of two aluminum plates. The back is a simple aluminum rectangle. The front part, which is in contact with the chips on the drives, has a base 0.5 mm thick, on which ribs are located 3 mm high and with a pitch of 2 mm.

These two plates are connected to each other with steel latches. The radiator contacts the elements on the M.2 SSD through thermal pads, and they are installed on both surfaces of the drive.

The heatsink is compatible with M.2 SSD size 2280. Heatsinks are currently available in several colors: black, grey, red, blue, green and purple. The cost is about 10 euros.

Test results

For testing, we used the Atto Disk Benchmark program, which recorded 32 GB of data with a queue of 8 to achieve maximum load. The temperatures of the controller and NAND chips were measured. All tests were carried out both without blowing and using a simulating case fan with a diameter of 92 mm.

In the case without forced airflow, the MSI M.2 Shield radiator showed the weakest result, which, however, is not surprising, given the size of this piece of hardware. You can’t expect any serious opportunities from it, and yet you can’t call it useless either. More than 20 “reset” degrees is useful in any case.

The best result, as expected, was shown by the most massive heatsink from the ASUS ROG Strix X299-XE Gaming motherboard. Still, size matters, no matter how you look at it. True, not everything is so simple here, but more on that later. Product EK shows average results.

When a fan is connected, the temperature drops noticeably. However, there are no significant changes in the distribution of places. The M.2 Shield has the weakest cooling, but the hefty radiator from the Strix X299-XE is again the best. The EK radiator remains in the middle, but the loss to the leader is significantly reduced. Apparently, large edges work well when blowing.

The measured read/write speed during testing showed a significant decrease with increasing temperature when using an SSD without a heatsink. With installed cooling systems, the results are very close and, apparently, the difference is due not to the cooling efficiency, but to the spread of values during testing.

From this we can conclude that even the most “frail” radiator allows you to use the drive at full capacity. The temperature, of course, will be higher than if more effective solutions are used, but, as they say, in this case this does not affect the speed if it does not come to throttling.

Conclusion. Testing cooling radiators for SSDs – they need to be cooled

The question “is it necessary to cool high-performance NVMe SSD M.2” can be answered with confidence in the affirmative. Even the simplest radiator can significantly reduce the temperature, keeping it within acceptable limits. Naturally, different models of these coolers have different efficiencies.

Moreover, the difference between them is only in the actual heating values of the elements on the storage device. The speed of operation when using all tested models is the same. Naturally, if the location of the drive on the motherboard is not very good in terms of cooling, and even with the “heating” of a powerful video card (or two) located in close proximity, then it makes sense to use a more efficient radiator.

The only thing that needs to be said is that the results of the largest heatsink on the Strix X299-XE Gaming motherboard are not entirely fair. On the one hand, the dimensions differ significantly from its competitors, on the other hand, in the test it was used only with a drive, although in normal life it also cools the chipset, i.e. the actual temperature of the drive will probably be higher. And yet this does not in any way contradict the conclusions.

For owners of motherboards on which such radiators are already installed initially, there is no point in changing them to something else, nor in refusing to use them. For those who do not have any cooling provided, or if the board is an old model, it is still advisable to purchase a radiator for the SSD.

Of course, this is only true if two factors are present. Firstly, you have a truly top-end, high-performance drive. And secondly, you use it to its full potential.

Serious overheating issue even though it's fairly new (<6 месяцев). Он по-прежнему постоянно перегревается до такой степени, что он отключается. Обычно это происходит во время игры, но иногда во время просмотра видео или с помощью видеозвонков Skype в течение длительного времени. Я уже держу его в воздухе на охлаждающем поддоне с 2 внешними кулерами, но это, похоже, не помогает.

The only thing I can think of is to install an SSD instead of the current HDD. I've read that they generate less heat than HDDs, but could this actually make a serious difference to the laptop's heat levels?

If there are other suggestions please feel free to comment.

Laptop Toshiba Satellite L650D-11R.

12 Solutions collect form web for “Will an SSD prevent my laptop from overheating?”

In general, no, because SSDs do not have significant advantages in terms of power consumption compared to regular mechanical hard drives (see the bottom of this article for an example). especially If we compare this difference with the energy consumption of the system as a whole,

It really comes down to how much power each drive consumes under load or at idle. What do you care?

Well, both drives are like a closed system, and from the first law of thermodynamics, the heat we put into the system must be equal to the heat that comes out (since no work is actually done other than moving the plates, and even then the movement of the disk plates, in ultimately through microscopic and macroscopic processes is dissipated into heat, as well as the second law of thermodynamics). In short, if an SSD consumes more power, it dissipates more heat.

Unless you find a solid state drive that uses less power than your current hard drive (or any drive for that matter), keep what you have ;)

For example, for some claims like the OCZ Agility 3 SSD uses 1.5W at idle and 2.7W under load, while the 1TB WD Scorpio Blue HDD only uses 1.4W under load and only 0.6W at idle!

Most likely not. Most of the heat is likely generated by the CPU and discrete GPU (ATI HD 5650). This is common on laptops because fans and vents become clogged with dust and dirt relatively easily. It could also be caused by poorly applied thermal paste, or the heatsink may have failed.

I would check the vents for obvious blockages. Open the case and clean it if you can. If this doesn't help, or if you'd rather not open a case, contact the retailer or manufacturer and report the problem - it should still be covered anyway.

But still don't hesitate to upgrade to SSD because the performance improvement will be amazing...

Usually while gaming, but sometimes while watching videos or using Skype video calls for a long time.

All activities that are video streaming or CPU/GPU intensive. Check for very poor airflow, dust and lint trapped in heat sinks or obstructing airflow past your video processor, CPU and memory cards.

Gluing an SSD drive into this machine will probably be like installing a chrome radiator cap on a connected heatsink. Purti with bragging rights, but the heat output still stinks.

Well, since you asked about other suggestions. (Presumably except that it changes hdd to ssd) and I may include photos of other offerings.

You can get things like this. Laptop coolers. Pillows for cooling laptops.

I have a couple of laptops and this is an issue on my PC laptop. (My Mac laptop has a metal case, the fan rarely ever goes above very low speed)

This is an old post, but I'd like to point out an obvious solution that no one has suggested yet:

Have you tried cleaning the heatsink and CPU fan? For these things, it is very common to drown the dust, and sometimes even the cat.

On some laptops, you can blow compressed air into the exhaust or fan.

If you can see the CPU fan, you will want to GET CARE to turn off the laptop, then (with the power off) use a pen or paperclip to hold the fan in place while blowing in compressed air. The reason for this is that compressed air can spin the fan faster than it was designed and wear out or fail the fan bearings.

If there are a lot of geeks that won't come out, you may need to partially separate the laptop.

Before you do anything, please read the manual for this laptop. There should be instructions on how to clean the radiator, or at least enough information about opening it so that you are confident (if you've done it before or are comfortable doing so).

You don't talk about it. Do you have enough bar to handle games and videos properly? Additionally, many new laptops are loaded with bloatware (software that can run inefficiently in the background), which can overload your processor.

The CNET website has free utilities that will check your CPU usage when you're not playing games or watching videos. This will give you an idea of what software on your laptop may be using your processor and possibly causing your system to overheat, slow down, and possibly crash.

I got a copy of CPUID HWMonitor and found that it was my CPU overheating. I adjusted the power settings -> CPU power management -> Max power consumption to 80% and my fan became quiet again. Obviously if I'm doing something that requires 100% CPU usage I'll need to adjust it, but for daily use I can't tell the difference.

Definitely not. The HDD/SSD does not generate enough heat* to cause the system to stall even under the most adverse conditions.

The fact is that you have a cooling problem in the CPU and GPU subsystem. Here are some potential reasons:

Incorrectly installed heat sink(s), either not properly connected, or the thermal interface connection was not applied correctly (if at all).
Blocked fans/air flow. Clean the dust, clean the fins, etc.
Broken fans either don't work or don't work well.
Too many processes running in the background. If you are using an intensive application, find ways to disable or close applications running in the background to reduce CPU usage.
Poor overall design. My opinion is that this is a real problem for you. Unfortunately, most laptops have thermal designs that are so poor that they overheat when given a decent CPU/GPU load for a long time... practically out of the box. The number of laptops on the market with poor thermal designs is simply tragic, and the sad reality is people who don't know ahead of time.

(*) – However, moving from MHD to SSD will actually impact your thermal processors. My own experience is that moving from MHD to SSD actually increases CPU usage because the CPU no longer has to wait on the HDD to find data. In theory, your CPU will be able to do more in less time, but in practice you will do more - which will tax the CPU even more.

By switching my regular HD to an SSD, my HP HD16t dropped 10 degrees.

This was supposed to be a comment but couldn't be posted due to length...

One thing to note: my laptop fan often came with hot air being pushed out to the sides. For what? It wasn't the CPU - I use Core Temp, so I could see in my tray that the CPU was basically idle (i7)... but seeing it every day, I had a good idea of CPU temps. Then I decided to move my cached IDE files to ramdisk for performance... and yes, it made the IDE faster. But.. an interesting advantage on the side, the temps were around 10-15C for the CPU cooler. And I almost never hear the fan or feel the hot air. It seems that constant SSD access heats up the insides of the laptop case. I have a Samsung EVO 850, I'm not sure if it's the same for all SSDs.. but it's an interesting article. Powerful SSDs: hotter than disks | ZDNet. However, I don't know exactly how this applies to regular SSDs.

I know this is an old post, but I wanted to call back. I had problems with my Dell xps 15 L501X overheating. What I had to fix was that I took my entire computer down, removed the heatsink from the CPU, and cleaned out the really bad factory installed thermal paste. I then applied high performance thermal paste while reinstalling the heatsink. And since then I have never had another overheating problem. I would suggest that you do this and also clean your entire computer frequently as they get clogged up easily with dust. I also installed an SSD to this day, I'm writing this post three years later and play very high graphics games on my PC and NEVER HAD ANOTHER QUESTION. Good luck

The problem with an SSD is that it will give the computer a false reading of its temperature. And if the computer detects an overheated hard drive (SSD), then it will run the fan at maximum rpm, but the fan does not turn on because the rpm value is not recognized. I suggest getting a cooling pad and running speed. When you watch a movie or play games, use a cooling pad. But disable the HDD temperature sensor because it will give a false CPU reading.

Solid state drives have become extremely popular over the past few years, in some cases completely replacing hard drives, which could not but lead to a mountain of myths about them. So let's figure out what you can and can't do with SSDs, and how different systems work with them.

Myth one: old systems cannot work with SSDs and thereby kill them

The reason for the myth is clear: the TRIM command “out of the box” is supported only by relatively modern versions of systems: in the case of Windows, this is 7 and higher. What kind of command is this and why is it needed? The problem is that when you delete a file in the same Explorer, it is not physically deleted from the drive, the latter does not even know about it: your file system simply marks the necessary cells on it as “unused”. In the case of hard drives, there are no problems: for them there is no difference in the speed of writing and rewriting a cell, but SSDs rewrite data much slower than they write. This is why the TRIM command was introduced: it clears “unused” cells before new information is written to them, that is, the speed of the drive will always be high.

From here we can draw a simple conclusion: older systems do not kill SSDs, simply due to the lack of TRIM support, such drives may run slower in them. But, again, this is “slow” many times faster than the best hard drives, and given the general undemanding nature of a ten-year-old OS on solid-state drives, they will simply fly.

Myth two: SSDs are much less reliable than hard drives

It depends on what you consider reliability: if you drop a SATA SSD from a height of a couple of tens of centimeters onto a table, you most likely will not harm it in any way. But such a fall can easily send a hard drive to computer heaven. But if we talk about the lifetime of these types of drives, then everything is not so obvious.

Tests conducted by 3Dnews show that even cheap SSDs can store 500-700 TB of information on them. Is it a lot or a little? Even if you actively install games on the solid-state drive and store 4K video on it, you are unlikely to write more than 15-20 TB onto it in a year. In other words, you will exhaust the resource for rewriting cells in about 20, or even 30 years (and for top-end SSDs in a century) - obviously, you will stop using this drive much earlier and for other reasons.

On the other hand, at various computer flea markets it is easy to find HDDs with capacities of 20-40 GB, which are two decades old and have good SMART indicators - they are sold only because smartphones in the modern world have much more memory. So, in general, for most modern drives, be it SSDs or hard drives, one thing can be said: with a high degree of probability they will outlive your device, or even more than one, and are more likely to become obsolete than break.

Myth three: there is no point in installing SSDs in weak computers

There are two questions here - which PC is considered weak, and for what purposes do you use it. From my own experience, I can say that even in the case of Pentium 4, which are 15 years old, Windows 7 on an SSD runs and loads much faster than on a hard drive. But on the Internet, for example, there is no difference - everything quickly comes down to 100% load on the CPU and works slowly on both drives.

In general, one thing can be said here: if in your everyday tasks the processor does not work at its maximum, then installing an SSD will speed them up, no matter how old your CPU is. In practice, even in the case of Core 2 Duo, which are only a couple of years younger than P4, Windows 10 on a solid-state drive “rusts” much faster, and this is clearly visible even when surfing the Internet.

Myth four: top gaming computers need NVMe SSDs, period

I am amused by the fact that everyone is massively installing fast NVMe SSDs in expensive builds or laptops. In short, this is a new protocol developed specifically for SSDs and allows them to be connected via as many as 4 PCIe lanes, which gives mind-blowing sequential read and write speeds of over 2-3 GB/s.

But in practice, if you compare the speed of loading games from such monsters and simple budget SATA SSDs, the difference turns out to be... one or two seconds, and the gap from the HDD is often 2-3 times. Why is this happening?

Firstly, sequential reading or writing is a spherical horse in a vacuum: literally in a couple of tens of seconds the fast SLC cache runs out and the speed drops to several hundred megabytes per second, that is, quite to the level of a typical SATA 3. Secondly, games (and programs in general) - these are not a couple of files weighing several gigabytes, these are thousands and tens of thousands of small files weighing kilobytes, and SSDs, again, do not work very quickly with them, often the speeds are only tens of megabytes per second - this again available for regular SATA SSDs, and at the same time an order of magnitude faster than the best HDDs. And thirdly, the loading speed of games depends not only on the SSD: the processor, video card, and RAM also play a role here.

As a result, we get that a cool NVMe SSD and a simple SATA perform almost identically when loading games, so there is absolutely no point in overpaying for the first one - you will hardly feel the difference between 24 and 25 seconds, but with the money saved you can improve other components.

Myth five: you can completely delete data from an SSD only by completely formatting it

How does full formatting work? It’s very simple - it simply writes zeros to all storage cells. It is almost impossible to recover data after this (due to the magnetic nature of the HDD, this is still possible, but it requires very expensive equipment and the chance of completely restoring deleted information is zero), so it is actively used to clear the drive of data for, for example, sale.

But to delete information from an SSD, the TRIM command is used, which completely erases the cells, making data recovery impossible. And it is called just during quick formatting, so full formatting in the case of a solid-state drive is simply not necessary, moreover, it is even harmful: you essentially increase the amount of information recorded on it by its volume, thereby reducing its resource.

Myth six: SSDs do not increase FPS in games

It would seem, what is the myth? After all, data from the drive is first preloaded into RAM, and then the processor and video card work with it. That is, the number of frames per second in games depends only on the three of them, the drive is not important here.

However, this is not entirely true: modern games are very heavy, and the speed of the hard drive may not be enough to load the necessary data into RAM. As a result, this will either cause unloaded textures, which in itself is unpleasant, or, even worse, so-called “freezes”: in other words, the picture will freeze. This will not affect the average FPS in any way - but the so-called 1% low or 0.1% low can drop to 5-10 FPS: this will mean that the game freezes every few seconds, and playing like this, of course, is very unpleasant.

Moving the game to an SSD will help get rid of this problem, and in this case, 1% low and 0.1% low will seriously increase and there will be no freezes, so the SSD can really increase the number of frames in games.

Myth seven: you can’t just move the system from HDD to SSD

For some reason, some people think that modern systems are installed differently on these two types of drives, so if you installed an SSD in your computer, you will have to reinstall the system. This is fundamentally not true: even if you installed Windows 10 on a HDD, drivers for working with an SSD will still be stored in the system folder, so when you transfer the system to such a drive, it will work on it without any problems after some independent configuration.

Of course, there are exceptions: for example, the release Windows 7 cannot work with NVMe SSD, so before transferring it to such a drive, you will have to integrate a driver with its support. It is also possible that the system activation may fail, but, in general, in the vast majority of cases there will be no problems.

Myth eight: in order for an SSD to live for a long time, you need to transfer the swap file from it, disable indexing, virus scanning, and so on

Perhaps there is nothing surprising here: indeed, if we disable all system operations that overwrite anything on the SSD, it will certainly live longer. Only here there is one subtle point: even without such tricks, your solid-state drive can work for more than a dozen years, but without a page file (or with it, but on the HDD), you will quickly experience all the pain from the lack of RAM and will “enjoy” the minute searching for files on a disk with indexing disabled. So the principle here is simple: don’t touch anything and enjoy fast work.

Myth nine: SSD requires defragmentation

I think many of those who installed the system on an HDD still remember that after six months or a year, defragmenting the drive often made it possible to return it to its former speed without reinstallation. The reason for this is simple: it is easier for the HDD head to read data from the disk when they are located sequentially. Any transfer of it to another location is a delay of tens of milliseconds, which easily results in extra tens of seconds for loading the system or programs. Therefore, defragmentation - that is, the process of combining “pieces” of programs from different areas of the disk into one - really speeded up the work.

However, in the case of an SSD, this is not the case: without going into details, the access time to any cell on it is the same. Therefore, it makes no difference whether the program is written in one solid piece or broken into many small ones - it will open equally quickly. So the defragmentation process for a solid-state drive is simply unnecessary and even harmful, since it will again reduce its service life.

Myth tenth: SSDs do not require further configuration after system installation

Not really. Indeed, most users simply install the desired OS on solid-state drives and work quietly without any problems, but in reality SSD devices are quite complex, and some manufacturers (for example, Samsung) write separate drivers for them and release utilities for updating their firmware. So, of course, you can leave everything alone and it will work fine on modern systems, but it is often possible to improve SSD performance even further by updating drivers or firmware.

Myth eleven: SSDs, like RAM, don’t get very hot, so they don’t need radiators

They're still warming up. Of course, if you take cheap SATA drives with simple controllers, then there will be no problems with them. But top-end NVMe SSDs from Samsung or Intel often have powerful dual-core controllers, and without cooling they can be difficult: temperatures quickly jump to 70-75 degrees and throttling begins, leading to a decrease in read and write speeds. So, if in the case of RAM, radiators are actually a prank, then for fast solid-state drives they are, as they say, a must-have.

Myth twelfth: SSDs need to be constantly monitored

Not necessarily. Of course, you need to keep an eye on everything: a computer is a rather complex thing, so it is still advisable to check the temperature or the condition of the drives once every time. But doing this on an ongoing basis, moreover, keeping monitoring programs in memory, is absolutely not necessary: the SSD controller itself is excellent at distributing information across cells, and modern operating systems are excellent at working with solid-state drives and sending them the right commands at the right time.

As a result, as you can see, there are a lot of myths about SSDs. Do you know any others? Write about it in the comments.