Samsung Starts Mass Production of 9th Generation V-NAND: 1Tb 3D TLC NAND
Samsung Electronics has started mass production of its 9th generation of V-NAND memory. The first dies based on their latest NAND tech come in a 1 Tb capacity using a triple-level cell (TLC) architecture, with data transfer rates as high as 3.2 GT/s. The new 3D TLC NAND memory will initially be used to build high-capacity and high-performance SSDs, which will help to solidify Samsung's position in the storage market.
Diving right in, Samsung is conspicuously avoiding to list the number of layers in their latest generation NAND, which is the principle driving factor in increasing capacity generation-on-generation. The company's current 8th gen V-NAND is 236 layers – similar to its major competitors – and word on the street is that 9th gen V-NAND ups that to 290 layers, though this remains to be confirmed.
Regardless, Samsung says that its 9th generation V-NAND memory boasts an approximate 50% improvement in bit density over its 8th generation predecessor. Driving this gains, the company cites the miniaturization of the cell size, as well as the integration of enhanced memory cell technologies that reduce interference and extend the lifespan of the cells. With their latest NAND technology, Samsung has also been able to eliminate dummy channel holes, thus reducing the planar area of the memory cells.
Interestingly, today's announcement also marks the first time that Samsung has publicly confirmed their use of string stacking in their NAND, referring to it as their "double-stack structure." The company is widely believed to have been using sting stacking back in their 8th generation NAND as well, however this was never confirmed by the company. Regardless, the use of string stacking is only going to increase from here, as vendors look to keep adding layers to their NAND dies, while manufacturing variability and channel hole tolerances make it difficult to produce more than 150-200 layers in a single stack.
| Samsung TLC V- NAND Flash Memory | ||
| 9th Gen V-NAND | 8th Gen V-NAND | |
| Layers | 290? | 236 |
| Decks | 2 (x145) | 2 (x118) |
| Die Capacity | 1 Tbit | 1 Tbit |
| Die Size (mm2) | ?mm2 | ?mm2 |
| Density (Gbit/mm2) | ? | ? |
| I/O Speed | 3.2 GT/s (Toggle 5.1) |
2.4 GT/s (Toggle 5.0) |
| Planes | 6? | 4 |
| CuA / PuC | Yes | Yes |
Speaking of channel holes, another key technological enhancement in the 9th gen V-NAND is Samsung's advanced 'channel hole etching' technology. This process improves manufacturing productivity by enabling the simultaneous creation of electron pathways within a double-stack structure. This method is crucial as it enables efficient drilling through more layers, which is increasingly important as cell layers are added.
The latest V-NAND also features the introduction of a faster NAND flash interface, Toggle DDR 5.1, which boosts peak data transfer rates by 33% to 3.2 GT/s, or almost 400MB/sec for a single die. Additionally, 9th gen V-NAND's power consumption has been reduced by 10%, according to Samsung. Though Samsung doesn't state under what conditions – presumably, this is at iso-frequency rather than max frequency.
Samsung's launch of 1Tb TLC V-NAND is set to be followed by the release of a quad-level cell (QLC) model later this year.
"We are excited to deliver the industry’s first 9th-gen V-NAND which will bring future... SSDs
Posted by The Techinical Support
![TSMC to Expand Specialty Capacity by 50%, Introduce 4nm N4e Low-Power Node <p align="center"><a href="https://www.anandtech.com/show/21397/tsmc-to-expand-specialty-capacity-by-50-introduce-4nm-lowpower-node"><img src="https://images.anandtech.com/doci/21397/tsmc-semiconductor-fab-wafer-1-678_575px.jpg" alt="" /></a></p><p><p>With all the new fabs being built in Germany and Japan, as well as the expansion of production capacity in China, TSMC is planning to extend its production capacity for specialty technologies by 50% by 2027. As disclosed by the company during its European Technology Symposium this week, TSMC expects to need to not only convert existing capacity to meet demands for specialty processes, but even build new (greenfield) fab space just for this purpose. One of the big drivers for this demand, in turn, will be TSMC's next specialty node: N4e, a 4nm-class ultra-low-power production node.</p>
<p>"In the past, we always did the review phase [for upcoming fabs], but for the first time in a long time at TSMC, we started building greenfield fab that will address the future specialty technology requirements," said Dr. Kevin Zhang, Senior Vice President, Business Development and Overseas Operations Office, at the event. "In the next four to five years, we actually going to grow our specialty capacity by up to 1.5x. In doing so we actually expanding the footprint of our manufacturing network to improve the resiliency of the overall fab supply chain."</p>
<p>On top of its well-known major logic nodes like N5 and N3E, TSMC also offers a suite of specialty nodes for applications such as power semiconductors, mixed analog I/O, and ultra-low-power applications (e.g. IoT). These are typically based on the company's trailing manufacturing processes, but regardless of the underlying technology, the capacity demand for these nodes is growing right alongside the demand for TSMC's major logic nodes. All of which has required TSMC to reevaluate how they go about planning for capacity on their specialty nodes.</p>
<p>TSMC's expansion strategy in the recent years has pursued several goals. One of them has been to build new fabs outside of Taiwan; another has been to generally expand production capacity to meet future demand for all types of process technologies – which is why the company is building up capacity for specialty nodes.</p>
<p>At present, TSMC's most advanced specialty node is N6e, an N7/N6 variant that supports operating voltages between 0.4V and 0.9V. With N4e, TSMC is looking at voltages below 0.4V. Though for now, TSMC is not disclosing much in the way of technical details for the planned node; given the company's history here, we expect they'll have more to talk about next year once the new process is ready.</p>
</p> Semiconductors](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_uHP_8okfLKCylX-Gp_ac4k4H7tqAJdt7GDXToeOhFCGFI60bBKFGP7if8l3Wa2clr1sIoteFv1vqrZXZjYy5IJOr48H5sb4QWhwN31bSIZ2szYJits7otSOLl2QjDnBiTtPVDrQhYq9eTmIGzPlML6MObeV31_bg=w72-h72-p-k-no-nu)
Micron Ships Crucial-Branded LPCAMM2 Memory Modules: 64GB of LPDDR5X For $330 
As LPCAMM2 adoption begins, the first retail memory modules are finally starting to hit the retail market, courtesy of Micron. The memory manufacturer has begun selling their LPDDR5X-based LPCAMM2 memory modules under their in-house Crucial brand, making them available on the latter's storefront. Timed to coincide with the release of Lenovo's ThinkPad P1 Gen 7 laptop – the first retail laptop designed to use the memory modules – this marks the de facto start of the eagerly-awaited modular LPDDR5X memory era.
Micron's Low Power Compression Attached Memory Module 2 (LPCAMM2) modules are available in capacities of 32 GB and 64 GB. These are dual-channel modules that feature a 128-bit wide interface, and are based around LPDDR5X memory running at data rates up to 7500 MT/s. This gives a single LPCAMM2 a peak bandwidth of 120 GB/s. Micron is not disclosing the latencies of its LPCAMM2 memory modules, but it says that high data transfer rates of LPDDR5X compensate for the extended timings.
Micron says that LPDDR5X memory offers significantly lower power consumption, with active power per 64-bit bus being 43-58% lower than DDR5 at the same speed, and standby power up to 80% lower. Meanwhile, similar to DDR5 modules, LPCAMM2 modules include a power management IC and voltage regulating circuitry, which provides module manufacturers additional opportunities to reduce power consumption of their products.
Source: Micron LPDDR5X LPCAMM2 Technical Brief
It's worth noting, however, that at least for the first generation of LPCAMM2 modules, system vendors will need to pick between modularity and performance. While soldered-down LPDDR5X memory is available at speeds up to 8533 MT/sec – and with 9600 MT/sec on the horizon – the fastest LPCAMM2 modules planned for this year by both Micron and rival Samsung will be running at 7500 MT/sec. So vendors will have to choose between the flexibility of offering modular LPDDR5X, or the higher bandwidth (and space savings) offered by soldering down their memory.
Micron, for its part, is projecting that 9600 MT/sec LPCAMM2 modules will be available by 2026. Though it's all but certain that faster memory will also be avaialble in the same timeframe.
Micron's Crucial LPDDR5X 32 GB module costs $174.99, whereas a 64 GB module costs $329.99.
Memory
Source: Micron LPDDR5X LPCAMM2 Technical Brief
Update on Intel's Panther Lake at Computex 2024, Intel Powering Up Intel 18A Wafer Next Week 
During the Intel keynote hosted by CEO Pat Gelsinger, he gave the world a glimpse into the Intel Client roadmap until 2026. Meteor Lake launched last year on that roadmap, and Lunar Lake, which we dived into yesterday as Intel disclosed technical details about the upcoming platform. Pat also presented a wafer on stage, Panther Lake, and he gave some additional information about Intel's forthcoming Panther Lake platform, which is expected in 2025.
We covered Intel's initial announcement about the Panther Lake platform last year. It is set to be Intel's first client platform using its Intel 18A node. Aside from once again affirming that things are on track for a 2026 launch, Pat Gelsinger, Intel's CEO, also confirmed that they will be powering on the first 18A wafer for Panther Lake as early as next week.
| Intel CPU Architecture Generations | |||||
| Alder/Raptor Lake | Meteor Lake |
Lunar Lake |
Arrow Lake |
Panther Lake |
|
| P-Core Architecture | Golden Cove/ Raptor Cove |
Redwood Cove | Lion Cove | Lion Cove | Cougar Cove? |
| E-Core Architecture | Gracemont | Crestmont | Skymont | Crestmont? | Darkmont? |
| GPU Architecture | Xe-LP | Xe-LPG | Xe2 | Xe2? | ? |
| NPU Architecture | N/A | NPU 3720 | NPU 4 | ? | ? |
| Active Tiles | 1 (Monolithic) | 4 | 2 | 4? | ? |
| Manufacturing Processes | Intel 7 | Intel 4 + TSMC N6 + TSMC N5 | TSMC N3B + TSMC N6 | Intel 20A + More | Intel 18A + ? |
| Segment | Mobile + Desktop | Mobile | LP Mobile | HP Mobile + Desktop | Mobile? |
| Release Date (OEM) | Q4'2021 | Q4'2023 | Q3'2024 | Q4'2024 | 2025 |
One element to consider from last year is that Lunar Lake is built using TSMC, with the Lunar Lake compute tile with Xe2-LPG graphics on TSMC N3B, and the I/O tile on TSMC N6. Pat confirmed on stage that Panther Lake will be on Intel 18A. Still, he didn't confirm whether the chip will be made purely at Intel, or a mix between Intel and external foundries (ala Meteor Lake). Intel has also yet to confirm the CPU cores to be used, but from what our sources tell us, it sounds like it will be the new Cougar Cove and Darkmont cores.
As we head into the second half of 2024 and after Lunar Lake launches, Intel may divulge more information, including the architectural advancements Panther Lake is expected to bring. Until then, we will have to wait and see.
CPUs
![](https://twitter.com/share?url=https://compbuddey.blogspot.com/2024/05/samsung-starts-mass-production-of-9th_15.html&text=Samsung Starts Mass Production of 9th Generation V-NAND: 1Tb 3D TLC NAND <p align="center"><a href="https://www.anandtech.com/show/21365/samsung-starts-mass-production-of-9th-generation-vnand-1tb-3d-tlc-nand"><img src="https://images.anandtech.com/doci/21365/9th-Generation-V-NAND_main1_575px.jpg" alt="" /></a></p><p><p>Samsung Electronics has started mass production of its 9th generation of V-NAND memory. The first dies based on their latest NAND tech come in a 1 Tb capacity using a triple-level cell (TLC) architecture, with data transfer rates as high as 3.2 GT/s. The new 3D TLC NAND memory will initially be used to build high-capacity and high-performance SSDs, which will help to solidify Samsung's position in the storage market.</p>
<p>Diving right in, Samsung is conspicuously avoiding to list the number of layers in their latest generation NAND, which is the principle driving factor in increasing capacity generation-on-generation. The company's current 8th gen V-NAND is 236 layers – similar to its major competitors – and word on the street is that 9th gen V-NAND ups that to 290 layers, though this remains to be confirmed.</p>
<p>Regardless, Samsung says that its 9th generation V-NAND memory boasts an approximate 50% improvement in bit density over its 8th generation predecessor. Driving this gains, the company cites the miniaturization of the cell size, as well as the integration of enhanced memory cell technologies that reduce interference and extend the lifespan of the cells. With their latest NAND technology, Samsung has also been able to eliminate dummy channel holes, thus reducing the planar area of the memory cells.</p>
<p>Interestingly, today's announcement also marks the first time that Samsung has publicly confirmed their use of string stacking in their NAND, referring to it as their "double-stack structure." The company is widely believed to have been using sting stacking back in their 8th generation NAND as well, however this was never confirmed by the company. Regardless, the use of string stacking is only going to increase from here, as vendors look to keep adding layers to their NAND dies, while manufacturing variability and channel hole tolerances make it difficult to produce more than 150-200 layers in a single stack.</p>
<table border="1" cellpadding="1" cellspacing="1" width="70%">
<tbody>
<tr class="tgrey">
<td align="center" colspan="3">Samsung TLC V- NAND Flash Memory</td>
</tr>
<tr class="tlblue">
<td class="tlgrey" colspan="1" rowspan="1"> </td>
<td align="center" rowspan="1">9th Gen V-NAND</td>
<td align="center" colspan="1" rowspan="1">8th Gen V-NAND</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Layers</td>
<td align="center">290?</td>
<td align="center">236</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Decks</td>
<td align="center">2 (x145)</td>
<td align="center">2 (x118)</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Die Capacity</td>
<td align="center" rowspan="1">1 Tbit</td>
<td align="center" rowspan="1">1 Tbit</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Die Size (mm<sup>2</sup>)</td>
<td align="center" rowspan="1">?mm2</td>
<td align="center" rowspan="1">?mm2</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Density (Gbit/mm<sup>2</sup>)</td>
<td align="center" rowspan="1">?</td>
<td align="center" rowspan="1">?</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">I/O Speed</td>
<td align="center" rowspan="1">3.2 GT/s<br />
(Toggle 5.1)</td>
<td align="center" rowspan="1">2.4 GT/s<br />
(Toggle 5.0)</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Planes</td>
<td align="center">6?</td>
<td align="center">4</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">CuA / PuC</td>
<td align="center">Yes</td>
<td align="center">Yes</td>
</tr>
</tbody>
</table>
<p>Speaking of channel holes, another key technological enhancement in the 9th gen V-NAND is Samsung's advanced 'channel hole etching' technology. This process improves manufacturing productivity by enabling the simultaneous creation of electron pathways within a double-stack structure. This method is crucial as it enables efficient drilling through more layers, which is increasingly important as cell layers are added.</p>
<p>The latest V-NAND also features the introduction of a faster NAND flash interface, Toggle DDR 5.1, which boosts peak data transfer rates by 33% to 3.2 GT/s, or almost 400MB/sec for a single die. Additionally, 9th gen V-NAND's power consumption has been reduced by 10%, according to Samsung. Though Samsung doesn't state under what conditions – presumably, this is at iso-frequency rather than max frequency.</p>
<p>Samsung's launch of 1Tb TLC V-NAND is set to be followed by the release of a quad-level cell (QLC) model later this year.</p>
<p>"We are excited to deliver the industry’s first 9th-gen V-NAND which will bring future... SSDs){kind=link}
![](https://www.pinterest.com/pin/create/button/?url=https://compbuddey.blogspot.com/2024/05/samsung-starts-mass-production-of-9th_15.html&media=https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tGJHzldEXlLoMCkbN9wzbJhye3GKQ_HPxkE76wR_ytN1Xk7R8Emly_cAM3IUuns6J5Z9S22Qo4pRK_jztvgfWgEGk4veJVYz6FAs2mvP1nb8X13lX9Iy9ctu5rar7RXE66C1TImiu1CyhSXrEYQJpN&description=Samsung Starts Mass Production of 9th Generation V-NAND: 1Tb 3D TLC NAND <p align="center"><a href="https://www.anandtech.com/show/21365/samsung-starts-mass-production-of-9th-generation-vnand-1tb-3d-tlc-nand"><img src="https://images.anandtech.com/doci/21365/9th-Generation-V-NAND_main1_575px.jpg" alt="" /></a></p><p><p>Samsung Electronics has started mass production of its 9th generation of V-NAND memory. The first dies based on their latest NAND tech come in a 1 Tb capacity using a triple-level cell (TLC) architecture, with data transfer rates as high as 3.2 GT/s. The new 3D TLC NAND memory will initially be used to build high-capacity and high-performance SSDs, which will help to solidify Samsung's position in the storage market.</p>
<p>Diving right in, Samsung is conspicuously avoiding to list the number of layers in their latest generation NAND, which is the principle driving factor in increasing capacity generation-on-generation. The company's current 8th gen V-NAND is 236 layers – similar to its major competitors – and word on the street is that 9th gen V-NAND ups that to 290 layers, though this remains to be confirmed.</p>
<p>Regardless, Samsung says that its 9th generation V-NAND memory boasts an approximate 50% improvement in bit density over its 8th generation predecessor. Driving this gains, the company cites the miniaturization of the cell size, as well as the integration of enhanced memory cell technologies that reduce interference and extend the lifespan of the cells. With their latest NAND technology, Samsung has also been able to eliminate dummy channel holes, thus reducing the planar area of the memory cells.</p>
<p>Interestingly, today's announcement also marks the first time that Samsung has publicly confirmed their use of string stacking in their NAND, referring to it as their "double-stack structure." The company is widely believed to have been using sting stacking back in their 8th generation NAND as well, however this was never confirmed by the company. Regardless, the use of string stacking is only going to increase from here, as vendors look to keep adding layers to their NAND dies, while manufacturing variability and channel hole tolerances make it difficult to produce more than 150-200 layers in a single stack.</p>
<table border="1" cellpadding="1" cellspacing="1" width="70%">
<tbody>
<tr class="tgrey">
<td align="center" colspan="3">Samsung TLC V- NAND Flash Memory</td>
</tr>
<tr class="tlblue">
<td class="tlgrey" colspan="1" rowspan="1"> </td>
<td align="center" rowspan="1">9th Gen V-NAND</td>
<td align="center" colspan="1" rowspan="1">8th Gen V-NAND</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Layers</td>
<td align="center">290?</td>
<td align="center">236</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Decks</td>
<td align="center">2 (x145)</td>
<td align="center">2 (x118)</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Die Capacity</td>
<td align="center" rowspan="1">1 Tbit</td>
<td align="center" rowspan="1">1 Tbit</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Die Size (mm<sup>2</sup>)</td>
<td align="center" rowspan="1">?mm2</td>
<td align="center" rowspan="1">?mm2</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Density (Gbit/mm<sup>2</sup>)</td>
<td align="center" rowspan="1">?</td>
<td align="center" rowspan="1">?</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">I/O Speed</td>
<td align="center" rowspan="1">3.2 GT/s<br />
(Toggle 5.1)</td>
<td align="center" rowspan="1">2.4 GT/s<br />
(Toggle 5.0)</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Planes</td>
<td align="center">6?</td>
<td align="center">4</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">CuA / PuC</td>
<td align="center">Yes</td>
<td align="center">Yes</td>
</tr>
</tbody>
</table>
<p>Speaking of channel holes, another key technological enhancement in the 9th gen V-NAND is Samsung's advanced 'channel hole etching' technology. This process improves manufacturing productivity by enabling the simultaneous creation of electron pathways within a double-stack structure. This method is crucial as it enables efficient drilling through more layers, which is increasingly important as cell layers are added.</p>
<p>The latest V-NAND also features the introduction of a faster NAND flash interface, Toggle DDR 5.1, which boosts peak data transfer rates by 33% to 3.2 GT/s, or almost 400MB/sec for a single die. Additionally, 9th gen V-NAND's power consumption has been reduced by 10%, according to Samsung. Though Samsung doesn't state under what conditions – presumably, this is at iso-frequency rather than max frequency.</p>
<p>Samsung's launch of 1Tb TLC V-NAND is set to be followed by the release of a quad-level cell (QLC) model later this year.</p>
<p>"We are excited to deliver the industry’s first 9th-gen V-NAND which will bring future... SSDs){kind=link}
![](https://web.whatsapp.com/send?text=Samsung Starts Mass Production of 9th Generation V-NAND: 1Tb 3D TLC NAND <p align="center"><a href="https://www.anandtech.com/show/21365/samsung-starts-mass-production-of-9th-generation-vnand-1tb-3d-tlc-nand"><img src="https://images.anandtech.com/doci/21365/9th-Generation-V-NAND_main1_575px.jpg" alt="" /></a></p><p><p>Samsung Electronics has started mass production of its 9th generation of V-NAND memory. The first dies based on their latest NAND tech come in a 1 Tb capacity using a triple-level cell (TLC) architecture, with data transfer rates as high as 3.2 GT/s. The new 3D TLC NAND memory will initially be used to build high-capacity and high-performance SSDs, which will help to solidify Samsung's position in the storage market.</p>
<p>Diving right in, Samsung is conspicuously avoiding to list the number of layers in their latest generation NAND, which is the principle driving factor in increasing capacity generation-on-generation. The company's current 8th gen V-NAND is 236 layers – similar to its major competitors – and word on the street is that 9th gen V-NAND ups that to 290 layers, though this remains to be confirmed.</p>
<p>Regardless, Samsung says that its 9th generation V-NAND memory boasts an approximate 50% improvement in bit density over its 8th generation predecessor. Driving this gains, the company cites the miniaturization of the cell size, as well as the integration of enhanced memory cell technologies that reduce interference and extend the lifespan of the cells. With their latest NAND technology, Samsung has also been able to eliminate dummy channel holes, thus reducing the planar area of the memory cells.</p>
<p>Interestingly, today's announcement also marks the first time that Samsung has publicly confirmed their use of string stacking in their NAND, referring to it as their "double-stack structure." The company is widely believed to have been using sting stacking back in their 8th generation NAND as well, however this was never confirmed by the company. Regardless, the use of string stacking is only going to increase from here, as vendors look to keep adding layers to their NAND dies, while manufacturing variability and channel hole tolerances make it difficult to produce more than 150-200 layers in a single stack.</p>
<table border="1" cellpadding="1" cellspacing="1" width="70%">
<tbody>
<tr class="tgrey">
<td align="center" colspan="3">Samsung TLC V- NAND Flash Memory</td>
</tr>
<tr class="tlblue">
<td class="tlgrey" colspan="1" rowspan="1"> </td>
<td align="center" rowspan="1">9th Gen V-NAND</td>
<td align="center" colspan="1" rowspan="1">8th Gen V-NAND</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Layers</td>
<td align="center">290?</td>
<td align="center">236</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Decks</td>
<td align="center">2 (x145)</td>
<td align="center">2 (x118)</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Die Capacity</td>
<td align="center" rowspan="1">1 Tbit</td>
<td align="center" rowspan="1">1 Tbit</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Die Size (mm<sup>2</sup>)</td>
<td align="center" rowspan="1">?mm2</td>
<td align="center" rowspan="1">?mm2</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Density (Gbit/mm<sup>2</sup>)</td>
<td align="center" rowspan="1">?</td>
<td align="center" rowspan="1">?</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">I/O Speed</td>
<td align="center" rowspan="1">3.2 GT/s<br />
(Toggle 5.1)</td>
<td align="center" rowspan="1">2.4 GT/s<br />
(Toggle 5.0)</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Planes</td>
<td align="center">6?</td>
<td align="center">4</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">CuA / PuC</td>
<td align="center">Yes</td>
<td align="center">Yes</td>
</tr>
</tbody>
</table>
<p>Speaking of channel holes, another key technological enhancement in the 9th gen V-NAND is Samsung's advanced 'channel hole etching' technology. This process improves manufacturing productivity by enabling the simultaneous creation of electron pathways within a double-stack structure. This method is crucial as it enables efficient drilling through more layers, which is increasingly important as cell layers are added.</p>
<p>The latest V-NAND also features the introduction of a faster NAND flash interface, Toggle DDR 5.1, which boosts peak data transfer rates by 33% to 3.2 GT/s, or almost 400MB/sec for a single die. Additionally, 9th gen V-NAND's power consumption has been reduced by 10%, according to Samsung. Though Samsung doesn't state under what conditions – presumably, this is at iso-frequency rather than max frequency.</p>
<p>Samsung's launch of 1Tb TLC V-NAND is set to be followed by the release of a quad-level cell (QLC) model later this year.</p>
<p>"We are excited to deliver the industry’s first 9th-gen V-NAND which will bring future... SSDs | https://compbuddey.blogspot.com/2024/05/samsung-starts-mass-production-of-9th_15.html){kind=link}
![](mailto:?subject=Samsung Starts Mass Production of 9th Generation V-NAND: 1Tb 3D TLC NAND <p align="center"><a href="https://www.anandtech.com/show/21365/samsung-starts-mass-production-of-9th-generation-vnand-1tb-3d-tlc-nand"><img src="https://images.anandtech.com/doci/21365/9th-Generation-V-NAND_main1_575px.jpg" alt="" /></a></p><p><p>Samsung Electronics has started mass production of its 9th generation of V-NAND memory. The first dies based on their latest NAND tech come in a 1 Tb capacity using a triple-level cell (TLC) architecture, with data transfer rates as high as 3.2 GT/s. The new 3D TLC NAND memory will initially be used to build high-capacity and high-performance SSDs, which will help to solidify Samsung's position in the storage market.</p>
<p>Diving right in, Samsung is conspicuously avoiding to list the number of layers in their latest generation NAND, which is the principle driving factor in increasing capacity generation-on-generation. The company's current 8th gen V-NAND is 236 layers – similar to its major competitors – and word on the street is that 9th gen V-NAND ups that to 290 layers, though this remains to be confirmed.</p>
<p>Regardless, Samsung says that its 9th generation V-NAND memory boasts an approximate 50% improvement in bit density over its 8th generation predecessor. Driving this gains, the company cites the miniaturization of the cell size, as well as the integration of enhanced memory cell technologies that reduce interference and extend the lifespan of the cells. With their latest NAND technology, Samsung has also been able to eliminate dummy channel holes, thus reducing the planar area of the memory cells.</p>
<p>Interestingly, today's announcement also marks the first time that Samsung has publicly confirmed their use of string stacking in their NAND, referring to it as their "double-stack structure." The company is widely believed to have been using sting stacking back in their 8th generation NAND as well, however this was never confirmed by the company. Regardless, the use of string stacking is only going to increase from here, as vendors look to keep adding layers to their NAND dies, while manufacturing variability and channel hole tolerances make it difficult to produce more than 150-200 layers in a single stack.</p>
<table border="1" cellpadding="1" cellspacing="1" width="70%">
<tbody>
<tr class="tgrey">
<td align="center" colspan="3">Samsung TLC V- NAND Flash Memory</td>
</tr>
<tr class="tlblue">
<td class="tlgrey" colspan="1" rowspan="1"> </td>
<td align="center" rowspan="1">9th Gen V-NAND</td>
<td align="center" colspan="1" rowspan="1">8th Gen V-NAND</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Layers</td>
<td align="center">290?</td>
<td align="center">236</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Decks</td>
<td align="center">2 (x145)</td>
<td align="center">2 (x118)</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Die Capacity</td>
<td align="center" rowspan="1">1 Tbit</td>
<td align="center" rowspan="1">1 Tbit</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Die Size (mm<sup>2</sup>)</td>
<td align="center" rowspan="1">?mm2</td>
<td align="center" rowspan="1">?mm2</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">Density (Gbit/mm<sup>2</sup>)</td>
<td align="center" rowspan="1">?</td>
<td align="center" rowspan="1">?</td>
</tr>
<tr>
<td class="tlgrey" colspan="1" rowspan="1">I/O Speed</td>
<td align="center" rowspan="1">3.2 GT/s<br />
(Toggle 5.1)</td>
<td align="center" rowspan="1">2.4 GT/s<br />
(Toggle 5.0)</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">Planes</td>
<td align="center">6?</td>
<td align="center">4</td>
</tr>
<tr>
<td class="tlgrey" colspan="1">CuA / PuC</td>
<td align="center">Yes</td>
<td align="center">Yes</td>
</tr>
</tbody>
</table>
<p>Speaking of channel holes, another key technological enhancement in the 9th gen V-NAND is Samsung's advanced 'channel hole etching' technology. This process improves manufacturing productivity by enabling the simultaneous creation of electron pathways within a double-stack structure. This method is crucial as it enables efficient drilling through more layers, which is increasingly important as cell layers are added.</p>
<p>The latest V-NAND also features the introduction of a faster NAND flash interface, Toggle DDR 5.1, which boosts peak data transfer rates by 33% to 3.2 GT/s, or almost 400MB/sec for a single die. Additionally, 9th gen V-NAND's power consumption has been reduced by 10%, according to Samsung. Though Samsung doesn't state under what conditions – presumably, this is at iso-frequency rather than max frequency.</p>
<p>Samsung's launch of 1Tb TLC V-NAND is set to be followed by the release of a quad-level cell (QLC) model later this year.</p>
<p>"We are excited to deliver the industry’s first 9th-gen V-NAND which will bring future... SSDs&body=https://compbuddey.blogspot.com/2024/05/samsung-starts-mass-production-of-9th_15.html){kind=link}
Lorem Ipsum is simply dummy text of the printing and typesetting industry. Lorem Ipsum has been the industry's.
0 Comments