Team Group Delta S TUF RGB SSD Review

Memory (DDR4/DDR5) and Storage (SSD/NVMe) 366 Page 4 of 12 Published by

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What is NAND?

What Is NAND?

Flash memory is an electronic non-volatile computer storage medium that can be electrically erased and reprogrammed. Introduced by Toshiba in 1984, flash memory was developed from EEPROM (electrically erasable programmable read-only memory). There are two main types of flash memory, which are named after the NAND and NOR logic gates. The NAND type is primarily used in main memory, memory cards, USB flash drives, solid-state drives (those produced in 2009 or later), and similar products, for general storage and transfer of data.

NAND Types

At the beginning, memory cells stored just a single bit of information. However, the charge on the floating gate can be controlled with some level of precision, allowing the storage of more information than just 0 and 1. Based on such an assumption the MLC (Multi-Level Cell) memory came to exist. To distinguish them, the old memory type was called SLC - Single Level Cell. The decision of choosing between SLC and MLC is driven by many factors such as memory performance, number of target erase/program cycles and level of data reliability. The MLC memory endurance is significantly lower (around 10,000 erase/program cycles) compared to SLC endurance (around 100,000 erase/program cycles).

  • Toggle-mode MLC - Toggle-mode MLC is asynchronous NAND that is supposed to provide similar performance as synchronous NAND, but at a lower price. Independent testing has not verified these claims yet. Toggle-mode MLC is also known as double-data-rate asynchronous NAND.

Synchronous and asynchronous NAND, based on spec sheets, look remarkably similar in performance. However, they aren't. Synchronous NAND is more expensive than asynchronous. Sync NAND is used when performance is everything, such as with gaming systems.

  • TLC NAND (triple-level cell flash) - TLC flash is a type of solid-state NAND flash memory that stores three bits of data per cell of flash media. TLC flash is less expensive than single-level cell (SLC) and multi-level cell (MLC) solid-state flash memory, which makes it appealing for consumer devices that use solid-state storage.

The drawbacks to using TLC flash are performance, reliability, and longevity. TLC flash will also have lower write endurance than both SLC and MLC flash. Generally, the more bits of data the cell has, the fewer write cycles it will support. SLC memory cells can withstand up to 100,000 write cycles before failing. A 2-bit MLC memory cell can typically withstand up to 10,000 write cycles before failing. A TLC memory cell can sustain about 1,000 write cycles before failing, which is why thus far it has been limited to consumer-grade applications.

  • QLC NAND - QLC flash writes 4 bits per cell. Adding more bits per cell also has an effect on the life-span of the NAND cell, and thus that brings down the number of times it can be written. Much like TLC (Triple-level cell), many new technologies like error-correction mechanisms and wearing have increased the life-span of the respective SSDs.

For example, a 500 GB TLC based SSD can quite easily manage a 300TB written before NAND cells start to die off. TLC has roughly a 1000 PE cycles, and that is the claim for QLC as well, a 1000 PE cycles. On 64-layer 4bits/cell NAND technology, Micron is achieving 33 percent higher array density compared to TLC, which enables them to produce the first commercially available 1 terabit die in the history of semiconductors.

  • Vertical (3D) V-NAND is physical vertical NAND cell stacking not to be puzzled with chip stacking in a multi-chip package. In 3D NAND, NAND layers, not chips, are stacked in a single IC. Stacking cells vertically has several benefits: it provides a higher capacity/volume ratio in a smaller physical space and improves electrical performance by shortening the interconnect length between cells (which also reduces power consumption).

The good news is continued cost reduction, smaller die sizes and more capacity per NAND chip. Also, installed NAND toolsets in the wafer fabs can, for the most part, be reused, thereby extending the useful life of fab equipment. Currently in 2018, in development is 96-layers stacked NAND.

So What About That New Smaller NAND Lifespan?

Smaller 15nm NAND FLASH memory was introduced, designed to be cheaper. 3D NAND cannot be vertically stacked in layers of memory cells. 64-layers are getting the norm in 2017 and we are rapidly exceeding that as well for 2018. The overall lifespan of the ICs has been reduced from 10,000 towards 5,000 program/erase cycles. Rumors are, that the numbers for consumer grade 15nm NAND flash memory (as used on the SSD tested today) are even lower at 3,000 program/erase cycles. But granted, as drastic as that sounds, it's all relative as this lifespan will very likely last longer than any mechanical HDD. Drive wearing protection and careful usage will help you out greatly. With an SSD filled normally and very heavy writing/usage of say 10 GBs data each day 365 days a year, you'd be looking at roughly 22 full SSD write cycles per year, out of the 3,000 (worst case scenario) available. However, all calculations on this matter are debatable and theoretical as usage differs and even things like how much free space you leave on your SSD can effect the drive.

I should thank Hilbert for this segment of the review, as there seemed little point in simply re-writing what he wrote in his Samsung QVO review! Plus, he is able to put it far better than I ever could. Anyway, we shall briefly cover the test environment, and then move onto actual benchmarking. I'm still, at the end of the day, curious to see what this drive can do. To be honest, if it stacks up to other offerings in the regular 2018/19 SSD range, then I'll be happy. After all, buy this drive and you should know that you're paying extra for the RGB. That's somewhat inevitable, but given how aesthetics focused modern PC building has become, I'm not half surprised.

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