In today’s Intel Accelerated event, the company is driving a stake into the ground regarding where it wants to be by 2025. CEO Pat Gelsinger earlier this year stated that Intel would be returning to product leadership in 2025, but hasn’t yet explained how this is coming about – that is until today, where Intel has disclosed its roadmap for its next five generations of process node technology leading to 2025. Intel believes it can follow an aggressive strategy to match and pass its foundry rivals, while at the same time developing new packaging offerings and starting a foundry business for external customers. On top of all this, Intel has renamed its process nodes.

The Short Answer:

If you only take one thing away from this article, I'm going to put it here front and center. Here is what we're seeing for Intel's roadmaps, based on their disclosures today.

As always, there is a difference between when a technology ramps for production and comes to retail; Intel spoke about some technologies as 'being ready', while others were 'ramping', so this timeline is simply those dates as mentioned. As you might imagine, each process node is likely to exist for several years, this graph is simply showcasing the leading technology from Intel at any given time.

If you want the details on this graph, then read on.

Intel's Defines a Strong Future: Is TSMC at Risk?

Earlier this year, CEO Pat Gelsinger announced Intel’s new IDM 2.0 strategy, consisting of three elements:

  1. Build (7nm)
  2. Expand (TSMC)
  3. Productize (Intel Foundry Services)

The goal here is to continue to work on Intel’s process node technology development, going beyond the current 10nm designs in production today, but simultaneously using other foundry services from partners (or competitors) to regain/retain Intel’s position in its processors that drive a lot of the company revenue. The third element is IFS, Intel’s Foundry Services, where Intel is committing in a big way to opening up its manufacturing facilities to external semiconductor business.

Underpinning (1) and (3) is how Intel executes on its own process node development. While in Intel’s recent Q3 2021 earnings call CEO Gelsinger confirmed that Intel is now producing more 10nm wafers in a day than 14nm wafers, marking a shift in confidence between the two designs, it is no secret that Intel has had difficulty in transitioning from its 14nm process to its 10nm process. On June 29th this year, Intel also stated that its next generation 10nm product requires additional validation time to streamline deployment on enterprise systems for 2022. Note that at the same time, TSMC has surpassed Intel by shipping at capacity with its equivalent designs (called 7nm) and its leading edge (5nm) designs that surpass Intel’s performance.

As with the previous announcement in March, Intel is reaffirming that it intends to return to leadership performance in semiconductors in 2025. This will enable both the company to compete better as it builds its own products (1) but also offer a wider portfolio of performance and technologies for its future IFS customers (3). To do this, it is realigning the roadmap for its future process node technologies to be more aggressive with improvements, yet at the same time more modular with its technology to enable faster transitions.

Leading up this plan is Dr. Ann B Kelleher, who was named SVP and GM of the Technology Development division at Intel last year. This division is where all the research and development of Intel’s future process node technologies and enhancements comes from – it used to be part of Intel’s System Architecture Group, however it was split in July 2020 to re-establish a focus purely on Technology Development. Dr. Kelleher’s background involves process research in academia, followed by 26 years at Intel as a process engineer, moving up to managing Fab 24 in Ireland, Fab 12 in Arizona, Fab 11X in Rio Rancho, before landing in HQ in Oregon as the GM of Manufacturing and Operations.

Her experience covering both fab-scale production and process node research is going to be critical for Intel’s future plans. In discussing with Kelleher ahead of today’s announcements, she stated that she has implemented fundamental changes when it comes to supplier approach, ecosystem learnings, organizational changes, modular design strategies, contingency plans, and realigning the Technology Development Team into a more streamlined outfit ready to execute. These include key personnel such as Sanjay Natarajan as SVP and GM of Logic Development (one of Intel’s recent rehires) and Babak Sabi as CVP and GM of Assembly/Test Development

Intel is today defining ‘technology leadership by 2025’ as defined by the metric of performance per watt. We asked Intel is a pre-briefing what that means for peak performance, which is often a metric we care about for end product design, and the answer was that "peak performance remains a key part of Intel’s strategic development".

Intel Renames The Nodes: ‘Mine is Smaller’

The problem with simply posting Intel’s roadmap here is that the news is two-fold. Not only is Intel disclosing the state of its technology for the next several years, but the names of the technology are changing to better align with common industry norms.

It is no secret that having "Intel 10nm" being equivalent to "TSMC 7nm", even though the numbers actually have nothing to do with the physical implementation, has ground at Intel for a while. A lot of the industry, for whatever reason, hasn’t learned that these numbers aren’t actually a physical measurement. They used to be, but when we moved from 2D planar transistors to 3D FinFET transistors, the numbers became nothing more than a marketing tool. Despite this, every time there’s an article about the technology, people get confused. We’ve been talking about it for half a decade, but the confusion still remains.

To that end, Intel is renaming its future process nodes. Here’s the roadmap image, but I’ll be breaking it down piece by piece.

2020, Intel 10nm SuperFin (10SF): Current generation technology in use with Tiger Lake and Intel’s Xe-LP discrete graphics solutions (SG1, DG1). The name stays the same.

2021 H2, Intel 7: Previously known as 10nm Enhanced Super Fin or 10ESF.  Alder Lake and Sapphire Rapids will now be known as Intel 7nm products, showcasing a 10-15% performance per watt gain over 10SF due to transistor optimizations. Alder Lake is currently in volume production. Intel’s Xe-HP will now be known as an Intel 7 product.

2022 H2, Intel 4: Previously known as Intel 7nm. Intel earlier this year stated that its Meteor Lake processor will use a compute tile based on this process node technology, and the silicon is now back in the lab being tested. Intel expects a 20% performance per watt gain over the previous generation, and the technology uses more EUV, mostly in the BEOL. Intel’s next Xeon Scalable product, Granite Rapids, will also use a compute tile based on Intel 4.

2023 H2, Intel 3: Previously known as Intel 7+. Increased use of EUV and new high density libraries. This is where Intel’s strategy becomes more modular – Intel 3 will share some features of Intel 4, but enough will be new enough to describe this a new full node, in particular new high performance libraries. Nonetheless, a fast follow on is expected. Another step up in EUV use, Intel expects a manufacturing ramp in the second half of 2023 with an 18% performance per watt gain over Intel 4.

2024, Intel 20A: Previously known as Intel 5nm. Moving to double digit naming, with the A standing for Ångström, or 10A is equal to 1nm. Few details, but this is where Intel will move from FinFETs to its version of Gate-All-Around (GAA) transistors called RibbonFETs. Also Intel will debut a new PowerVia technology, described below.

2025, Intel 18A: Not listed on the diagram above, but Intel is expecting to have an 18A process in 2025. 18A will be using ASML’s latest EUV machines, known as High-NA machines, which are capable of more accurate photolithography. Intel has stated to us that it is ASML’s lead partner when it comes to High-NA, and is set to receive the first production model of a High-NA machine. ASML recently announced High-NA was being delayed- when asked if this was an issue, Intel said no, as the timelines for High-NA and 18A are where Intel expects to intersect and have unquestioned leadership.

Intel has confirmed to us that Intel 3 and Intel 20A will be offered to foundry customers (but hasn’t stated if Intel 4 or Intel 7 will be).

To bring this altogether in a single table, with known products, we have the following:

Intel's Process Node Technology
Old Name New Name Roadmap Products Features
10SF 10SF Today Tiger Lake
SG1
DG1
Xe-HPC Base Tile
Agilex-F/I FPGA
SuperMIM
Thin Film Barrier
Volume 10nm
On sale today
10ESF Intel 7 2021 H2 products Alder Lake (21)
Raptor Lake (22)?
Sapphire Rapids (22)
Xe-HP
Xe-HPC IO Tile
10-15% PPW
Upgraded FinFET
ADL in Ramp today
7nm Intel 4 2022 H2 ramp
2023 H1 products
Meteor Compute Tile
Granite Compute Tile
20% PPW vs 7
More EUV
Silicon in Lab
7+ Intel 3 2023 H2 products - 18% PPW vs 4
Area Savings
More EUV
New Perf Libraries
Faster Follow On
5nm Intel 20A 2024 - RibbonFET
PowerVia
5+ Intel 18A 2025 Unquestioned Leadership 2nd Gen Ribbon
High NA EUV

One of the issues here is the difference between a process node being ready, ramping production for product launches, and actually being made available. For example, Alder Lake (now on Intel 7nm) is due to come out this year, but Sapphire Rapids is going to be more of a 2022 product. Similarly, there are reports of Raptor Lake on Intel 7 coming out in 2022 to replace Alder Lake with the tiled Meteor Lake on Intel 4 in 2023. While Intel is happy to discuss process node development time frames, product timeframes are not as open (as no doubt customers would get frustrated if the time stated is missed).

Why The Nodes Were Renamed

So as stated before, one element of renaming the nodes is due to matching parity with other foundry offerings. Both TSMC and Samsung, competitors to Intel, were using smaller numbers to compare similar density processes. With Intel now renaming itself, it gets more in-line with the industry. That being said, perhaps sneakily, Intel’s 4nm might be on par with TSMC’s 5nm, reversing the tables. By 3nm we expect there to be a good parity point, however that will depend on Intel matching TSMC’s release schedule.

Rather than throw process node names everywhere, it is typical to refer to peak quoted transistor densities instead. Here is the table we published in our recent IBM 2nm news post, but with an updated shift on Intel’s naming.

2021 Peak Quoted Transistor Densities (MTr/mm2)
AnandTech
Process Name
IBM TSMC Intel Samsung
22nm     16.50  
16nm/14nm   28.88 44.67 33.32
10nm   52.51 100.76 51.82
7nm   91.20 100.76 95.08
5/4nm   171.30 ~200* 126.89
3nm   292.21*    
2nm / 20A 333.33      
Data from Wikichip, Different Fabs may have different counting methodologies
* Estimated Logic Density

Exactly where Intel’s new 4nm and below will end up is yet to be disclosed, as numbers with stars alongside are based on estimates by the respective companies.

It has been expected for a while that Intel would be realigning its process node naming. Behind closed doors, I personally have been lobbying for it for a while, and I know that a few other journalists and analysts have been suggesting it to Intel as well. Some responses we received were related to apathy – one executive told me that "our customers that care about this actually know the difference", which is true for sure, but what we’re talking about here is more about perception in the wider ecosystem for enthusiasts and financial analysts who might not be up to speed. It is more or less a branding exercise, and I also told Intel that they are going to have to expect a mixed response – some voices might interpret the move as Intel trying to pull one over on the market, for example. But they’re going to have to live with it, as these are the new names.

Meanwhile, despite Intel’s struggles with 10nm, it is still a process node in production and in volume production, in use for both consumer and enterprise devices, and it's coming to desktops very soon. Even though it has some stiff competition from other players, it is still an offering in the market, and for those that want to compare process node densities using these names, it should have a moniker to avoid confusion. I am applauding that Intel is doing it sooner rather than later.

One key point to note is that the new Intel 7 node, which was formerly the 10ESF node, is not necessarily a "full" node update as we typically understand it. This node is derived as an update from 10SF, and as the diagram above states, will have ‘transistor optimizations’. Moving from 10nm to 10SF, that meant SuperMIM and new thin-film designs giving an extra 1 GHz+, however the exact details from 10SF to the new Intel 7 is unclear at this point. Intel has however stated that moving from Intel 7 to Intel 4 will be a regular full node jump, with Intel 3 using modular parts of Intel 4 with new high-performance libraries and silicon improvements for another jump in performance.

We asked Intel if these process nodes will have additional optimization points, and were told that they will – whether any of them will be explicitly productized will depend on the features. Individual optimizations may account for an additional 5-10% performance per watt, and we were told that even 10SF (which keeps its name) has had several additional optimization points that haven’t necessarily been publicized. So whether these updates get marketed as 7+ or 7SF or 4HP is not known, but as with any manufacturing process as updates occur to help improve performance/power/yield, they get applied assuming the design adheres to the same rules.

"Isn't Intel Just Trying To Pull The Wool Over Our Eyes?"

No.

The problem here is that there is no consistent node naming between foundries. Intel has been saving any number change for major advances in its node manufacturing technology, instead using +/++ to signify improvements. If we compare this to TSMC and Samsung, both of whom have been happy to give half-node jumps new numbers entirely.

For example, Samsung's 7LPP is a major node, however 6LPP, 5LPE and 4LPE are all iterative efforts on the same design (arguably also iterative of 8LPP), with 3GAE being the next major jump. Compare this to Intel, who was planning 10nm to 7nm to 5nm as major process node jumps – so while Samsung had one jump planned and 4 sub-variants (or more), Intel had two major jumps. Similarly, TSMC's 10nm was a half-node jump over 16nm, while 16nm to 7nm was the full node – Intel made 14 to 10 to 7 as full nodes.

Intel stuck to its guns a long while, and delays to 10nm effectively hurt it in a multiplicative fashion. For example, if Intel had labeled 14+ as 13nm, and 14++ as 12nm, perhaps it wouldn't be so bad. I mean, yes Intel should expect some hurt for 10nm being late, but when other foundries were showcasing smaller steps as full number jumps, it became a marketing and media nightmare. 14++++ became an industry joke, and coupled with how every time when they talked about future process nodes they had to cite the equivalent TSMC of Samsung process, it got a bit too much. It had to be explained every time, as new people come into the industry.  

I've lobbied Intel to adjust its naming for a while, and I know other peers have as well. When we refer to Intel 7 from now on, we can draw equivalents to TSMC 7nm (even if TSMC is shipping 5nm in volume) without having to extensively explain differences in a simple name. This isn't Intel pulling the wool over your eyes, or trying to hide a bad situation. This is Intel catching up to the rest of the industry in how these processes are named. To add to this, it's a good thing that Intel is only renaming future nodes that haven't reached the market yet.

This is a multi-page article!

Click the dropdown below for more pages, including

  1. This Page, New Node Names
  2. A Sidebar on Intel EUV and becoming ASML Lead Partner
  3. New for 2024: RibbonFETs and PowerVias
  4. Next Gen EMIB and Foveros Packaging
  5. Customers Customers Customers
Sidebar on Intel EUV and ASML
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  • Maksdampf - Tuesday, July 27, 2021 - link

    You know that Intels numbers that they out out haven't been spotted in the wild on any of their products, right? They had been doing these marketing stunts for a while, just with a different disguise. 107MTr/mm2 vor 10SF, my Ass.

    Since Pat has relased some Transistor count figures, we know that cometlake with 4,2BTr and 205mm2 only has a density of around 21MTr/mm2 instead of the claimed 44MTr/mm2 for 14nm++ and even the newest shiniest rocketlake is worse than AMDs original zeppelin design in Density (6BTr on 270mm2 vs 4.8BTr on 192mm2).
    Since Tigerlake-H is only different in its L3 cache system, we know it is around 8-9BTr compared to cypress cove based Rocketlake. And it still has the much larger DIE coming in at 190mm2 compared to AMDs Cezanne with 10,78BTr including a much beefier GPU.

    And this is comparing Apples to Apples, so HP processes to HP, not High density to mobile.
    TSMCs and Samsungs Mobile Processes are in reality so far ahead in Density and Power of anything Intel ships, that you really need an M1 class of chip to show it.

    Intel has us fooled by meaningless laboratory numbers that can nowhere be found in real products for years and now they fuck us over again by renaming those already pretty desperate naming schemes.
  • name99 - Tuesday, July 27, 2021 - link

    Not if those transistor estimates never match real products…
    For years now, nothing Intel ships is close to their claimed transistor density. It’s like 2 to 3x off.

    So…
  • Butterfish - Tuesday, July 27, 2021 - link

    So does most chip made by other foundries. These figure are for the high density library. If you look at AMD’s CPU and GPU which use TSMC’s high performance library that aren’t optimized for density you will see much lower density number compare to what was advertised for the process nodes they are using.
  • Spunjji - Wednesday, July 28, 2021 - link

    Yes, you will see lower density - but something like 60-80% of the quoted density. Intel are hitting something more like 33-50% of what they quoted for 10nm.
  • cheshirster - Tuesday, July 27, 2021 - link

    Intel hide transistor density of their products since Coffee Lake.
    For years as of now.
  • cheshirster - Tuesday, November 23, 2021 - link

    Still Intel, cause their transistors counts aren't disclosed for any 10nm product.
  • IntelUser2000 - Monday, July 26, 2021 - link

    No, Ian lobbied for it.

    Boo!!
  • mode_13h - Tuesday, July 27, 2021 - link

    Yeah, as a journalist, he shouldn't be trying to influence the industry. He can ask them questions like how they feel about TSMC/Samsung's node naming, during interviews, but that about as far as it should go.
  • Oxford Guy - Wednesday, July 28, 2021 - link

    I can only assume your post is not particularly well-executed parody of the misguided point of view it’s espousing.

    What a stupid comment.

    Journalists, of course, can (and often should) be more than marketing department parrots, more than stenographers.
  • Spunjji - Thursday, July 29, 2021 - link

    I'm always confused by that idea that there's some magical bright line between being a journalist and an enthusiast. Ian can advocate for whatever he wants from Intel - as long as he's actually honest about it, IDGAF.

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