10 nm process explained

In semiconductor fabrication, the International Technology Roadmap for Semiconductors (ITRS) defines the "10 nanometer process" as the MOSFET technology node following the "14 nm" node.

Since at least 1997, "process nodes" have been named purely on a marketing basis, and have no relation to the dimensions on the integrated circuit;^[1] neither gate length, metal pitch or gate pitch on a "10nm" device is ten nanometers.^{[2] [3] [4]} For example, GlobalFoundries' "7 nm" processes are dimensionally similar to Intel's "10 nm" process.^[5] TSMC and Samsung's "10 nm" processes are somewhere between Intel's "14 nm" and "10 nm" processes in transistor density. The transistor density (number of transistors per square millimetre) is more important than transistor size, since smaller transistors no longer necessarily mean improved performance, or an increase in the number of transistors.

All production "10 nm" processes are based on FinFET (fin field-effect transistor) technology, a type of multi-gate MOSFET technology that is a non-planar evolution of planar silicon CMOS technology. Samsung first started their production of "10 nm-class" chips in 2013 for their multi-level cell (MLC) flash memory chips, followed by their SoCs using their 10 nm process in 2016. TSMC began commercial production of "10 nm" chips in 2016, and Intel later began production of "10nm" chips in 2018.

Background

The ITRS's original naming of this technology node was "11 nm". According to the 2007 edition of the roadmap, by the year 2022, the half-pitch (i.e., half the distance between identical features in an array) for a DRAM was projected to be 11 nm.

In 2008, Pat Gelsinger, at the time serving as Intel's Chief Technology Officer, said that Intel saw a 'clear way' towards the "10 nm" node.^{[6] [7]}

In 2011, Samsung announced plans to introduce the "10nm" process the following year.^[8] In 2012, Samsung announced eMMC flash memory chips that are produced using the "10nm" process.^[9]

As of 2018, "10 nm" as it was generally understood was only in high-volume production at Samsung. GlobalFoundries had skipped "10 nm", Intel had not yet started high-volume "10 nm" production, due to yield issues, and TSMC had considered "10 nm" to be a short-lived node,^[10] mainly dedicated to processors for Apple during 2017–2018, moving on to "7 nm" in 2018.

There is also a distinction to be made between "10 nm" as marketed by foundries and "10 nm" as marketed by DRAM companies.

Technology production history

In April 2013, Samsung announced that it had begun mass production of multi-level cell (MLC) flash memory chips using a "10nm-class" process, which, according to Tom's Hardware, Samsung defined as "a process technology node somewhere between 10-nm and 20-nm".^[11] On 17 October 2016, Samsung Electronics announced mass production of SoC chips at "10 nm". The technology's main announced challenge at that time had been triple patterning for its metal layer.^{[12] [13]}

TSMC began commercial production of "10 nm" chips in early 2016, before moving onto mass production in early 2017.^[14]

On 21 April 2017, Samsung started shipping their Galaxy S8 smartphone, which used the company's version of the "10 nm" processor.^[15] On 12 June 2017, Apple delivered second-generation iPad Pro tablets powered with TSMC-produced Apple A10X chips using the "10 nm" FinFET process.^[16]

On 12 September 2017, Apple announced the Apple A11, a 64-bit ARM-based system on a chip, manufactured by TSMC using a "10 nm" FinFET process, containing 4.3 billion transistors on a die of 87.66 mm².

In April 2018, Intel announced a delay in volume production of "10 nm" mainstream CPUs until sometime in 2019.^[17] In July, the exact time was further pinned down to the holiday season.^[18] In the meantime, however, they did release a low-power "10 nm" mobile chip, albeit exclusive to Chinese markets and with much of the chip disabled.^[19]

In June 2018 at VLSI 2018, Samsung announced their "11LPP" and "8LPP" processes. "11LPP" was a hybrid based on Samsung "14 nm" and "10 nm" technology. "11LPP" was based on their "10 nm" BEOL, not their "20 nm" BEOL like the "14LPP". "8LPP" was based on the "10LPP" process.^{[20] [21]}

Nvidia released their GeForce 30 series GPUs in September 2020. They were at that time made on a custom version of Samsung's "8 nm" process, called "Samsung 8N", with a transistor density of 44.56 million transistors per mm².^{[22] [23]}

Process nodes

Foundry

	ITRS Logic Device Ground Rules (2015)		Samsung					TSMC	Intel
Process name	16/14 nm	11/10 nm	10LPE (10 nm)	10LPP (10 nm)	8LPP (8 nm)	8LPU (8 nm)	8LPA (8 nm)	10FF (10 nm)	10nm[24]	10nm SF (10 nm)
Transistor density (MTr / mm2)			51.82		61.18			52.51[25]	100.76[26]
Transistor gate pitch (nm)	70	48	68		64			66	54
Interconnect pitch (nm)	56	36	51		colspan="2"		44	36
Transistor fin pitch (nm)	42	36	42					36	34
Transistor fin height (nm)	42	42	49		colspan="2"		42	53
Production year	2015	2017	[27]	[28]		2019 production[29]		2017 production	(Cannon Lake)[30]	(Tiger Lake)[31]

Transistor gate pitch is also referred to as CPP (contacted poly pitch) and interconnect pitch is also referred to as MMP (minimum metal pitch). Samsung reported their "10 nm" process as having a 64 nm transistor gate pitch and 48 nm interconnect pitch. TSMC reported their "10 nm" process as having a 64 nm transistor gate pitch and 42 nm interconnect pitch. Further investigation by Tech Insights revealed even these values to also be false, and they have been updated accordingly. In addition, the transistor fin height of Samsung's "10 nm" process was updated by MSSCORPS CO at SEMICON Taiwan 2017.^{[32] [33] [34] [35] [36]} GlobalFoundries decided not to develop a "10 nm" node, because it believed it would be short lived.^[37] Samsung's "8 nm" process was at that time the company's last to exclusively use DUV lithography.^[38]

DRAM "10 nm class"

See main article: Dynamic random-access memory. For the DRAM industry, the term "10 nm-class" is often used and this dimension generally refers to the half-pitch of the active area. The "10 nm" foundry structures are generally much larger.

Generally "10 nm class" refers to DRAM with a 10-19 nm feature size, and was first introduced . As of 2020, there were three generations of "10 nm class" DRAM : 1x nm (19-17 nm, Gen1); 1y nm (16-14 nm, Gen2); and 1z nm (13-11 nm, Gen3). 3rd Generation "1z" DRAM was first introduced by Samsung, and was initially stated to be produced using ArF lithography without the use of EUV lithography; subsequent production did utilise EUV lithography.

Beyond 1z Samsung named its next node (fourth generation "10 nm class") DRAM : "D1a" (expected at that time to have been produced in 2021), and beyond that "D1b" (expected at that time to have been produced in 2022); whilst Micron referred to succeeding "nodes" as "D1α" and "D1β". Micron announced volume shipment of 1α class DRAM in early 2021.

Notes and References

1. Web site: No More Nanometers – EEJournal . 23 July 2020 .
2. Web site: A Brief History of Process Node Evolution. Shukla. Priyank. design-reuse.com. 2019-07-09.
3. Web site: 14nm, 7nm, 5nm: How low can CMOS go? It depends if you ask the engineers or the economists.... Hruska. Joel. ExtremeTech.
4. Web site: Exclusive: Is Intel Really Starting To Lose Its Process Lead? 7nm Node Slated For Release in 2022. wccftech.com. 2016-09-10.
5. Web site: Life at 10nm. (Or is it 7nm?) And 3nm - Views on Advanced Silicon Platforms. eejournal.com. 2018-03-12.
6. Web site: Intel's Gelsinger Sees Clear Path To 10nm Chips . Damon Poeter . https://web.archive.org/web/20090425061704/http://www.crn.com/hardware/208801780 . 2009-04-25 . live . 2009-06-20 . July 2008 .
7. Web site: MIT: Optical lithography good to 12 nanometers . https://web.archive.org/web/20120925204010/http://www.eetimes.com/news/latest/showArticle.jhtml?articleID=209400807 . 2012-09-25 . live . 2009-06-20 .
8. News: World's Largest Fabrication Facility, Line-16 . 21 June 2019 . . September 26, 2011.
9. News: Samsung's new 10nm-process 64GB mobile flash memory chips are smaller, faster, better . 21 June 2019 . . November 15, 2012.
10. Web site: 10nm rollout . 2018-08-04 . 2018-08-04 . https://web.archive.org/web/20180804110423/http://techinsights.com/about-techinsights/overview/blog/10nm-rollout-marching-right-along/ . dead .
11. News: Samsung Mass Producing 128Gb 3-bit MLC NAND Flash . 21 June 2019 . . 11 April 2013 . 21 June 2019 . https://web.archive.org/web/20190621175628/https://www.tomshardware.co.uk/NAND-128Gb-Mass-Production-3-bit-MLC,news-43458.html . dead .
12. Web site: Samsung Starts Industry's First Mass Production of System-on-Chip with 10-Nanometer FinFET Technology. news.samsung.com.
13. Web site: triple patterning for 10nm metal.
14. Web site: 10nm Technology . . 30 June 2019.
15. Web site: Buy.
16. Web site: 10nm Rollout Marching Right Along. techinsights.com. techinsights.com. 2017-06-30. https://web.archive.org/web/20170803141307/http://www.techinsights.com/about-techinsights/overview/blog/10nm-rollout-marching-right-along/. 2017-08-03. dead.
17. Web site: Intel Corp. Delays 10nm Chip Production - Mass production is now scheduled for 2019.. 2018-04-29. 2018-08-01.
18. News: Intel says not to expect mainstream 10nm chips until 2H19. 2018-07-28. 2018-08-01.
19. Web site: Intel's First 10nm Processor Lands In China. 2018-05-15. 2018-09-11.
20. Web site: VLSI 2018: Samsung's 11nm nodelet, 11LPP. 2018-06-30. WikiChip Fuse. en-US. 2019-05-31.
21. Web site: VLSI 2018: Samsung's 8nm 8LPP, a 10nm extension. 2018-07-01. WikiChip Fuse. en-US. 2019-05-31.
22. News: Nvidia confirms Samsung 8nm process for RTX 3090, RTX 3080, and RTX 3070 PC Gamer. www.pcgamer.com. September 2020 . James . Dave .
23. Web site: NVIDIA GeForce RTX 30 Ampere GPU Deep-Dive, Full Specs, Thermals, Power & Performance Detailed. September 4, 2020.
24. Web site: Intel guts 10nm to get it out the door. Demerjian. Charlie. 2018-08-02. SemiAccurate. 6 September 2024.
25. Web site: TSMC Announces 6-Nanometer Process. Schor. David. 2019-04-16. WikiChip Fuse. en-US. 2019-05-31.
26. News: Intel 10nm density is 2.7X improved over its 14nm node. HEXUS. 2018-11-14. en-GB.
27. Web site: Samsung Foundry Announces 10nm SoC In Mass-Production. Andrei. Frumusanu. www.anandtech.com.
28. Web site: Samsung Starts Mass Production of Chips Using 10nm Low Power Plus (10LPP) Process Tech. Anton. Shilov. www.anandtech.com.
29. Web site: Samsung Foundry Updates: 8LPU Added, EUVL on Track for HVM in 2019. Anton. Shilov. www.anandtech.com.
30. Web site: Cutress . Ian . July 26, 2021 . Intel's Process Roadmap to 2025: with 4nm, 3nm, 20A and 18A?! . AnandTech . 2021-07-27.
31. Web site: What Products Use Intel 10nm? SuperFin and 10++ Demystified .
32. Web site: Intel Details Cannonlake's Advanced 10nm FinFET Node, Claims Full Generation Lead Over Rivals. 2017-03-28. 2017-03-30. 2017-03-30. https://web.archive.org/web/20170330151945/http://hothardware.com/news/intel-details-advanced-10nm-node. dead.
33. Web site: International Technology Roadmap for Semiconductors 2.0 2015 Edition Executive Report. 2018-12-27.
34. Web site: 14nm 16nm 10nm and 7nm - What we know now. Scotten. Jones. 25 February 2024 .
35. Web site: Qualcomm Snapdragon 835 First to 10 nm . Samsung 10LPE process .
36. Web site: 10 nm lithography process . wikichip.
37. Web site: Exclusive - GLOBALFOUNDRIES discloses 7nm process detail. Scotten. Jones. 25 February 2024 .
38. Web site: Samsung's 8LPP Process Technology Qualified, Ready for Production. Anton. Shilov. www.anandtech.com.