From WikiChip
Difference between revisions of "7 nm lithography process"

(7 nm Microarchitectures)
(Industry)
Line 13: Line 13:
 
  | process 1 name        = P1276 (CPU), P1277 (SoC)
 
  | process 1 name        = P1276 (CPU), P1277 (SoC)
 
  | process 1 date        =  
 
  | process 1 date        =  
  | process 1 lith        =  
+
  | process 1 lith        = EUV
 
  | process 1 immersion    =  
 
  | process 1 immersion    =  
 
  | process 1 exposure    =  
 
  | process 1 exposure    =  
Line 47: Line 47:
 
  | process 2 lith        = 193 nm
 
  | process 2 lith        = 193 nm
 
  | process 2 immersion    = Yes
 
  | process 2 immersion    = Yes
  | process 2 exposure    = LELELE
+
  | process 2 exposure    = SAQP
 
  | process 2 wafer type  = Bulk
 
  | process 2 wafer type  = Bulk
 
  | process 2 wafer size  = 300 mm
 
  | process 2 wafer size  = 300 mm
 
  | process 2 transistor  = FinFET
 
  | process 2 transistor  = FinFET
  | process 2 volt        = 0.50 V
+
  | process 2 volt        = 0.70 V
 
  | process 2 delta from  = [[10 nm]] Δ
 
  | process 2 delta from  = [[10 nm]] Δ
 
  | process 2 fin pitch    =  
 
  | process 2 fin pitch    =  
Line 75: Line 75:
 
<!-- GlobalFoundries -->
 
<!-- GlobalFoundries -->
 
  | process 3 fab          = [[GlobalFoundries]]
 
  | process 3 fab          = [[GlobalFoundries]]
  | process 3 name        = &nbsp;
+
  | process 3 name        = 7LP<info>7nm Leading Performance</info>
 
  | process 3 date        = 2019
 
  | process 3 date        = 2019
 
  | process 3 lith        = 193 nm
 
  | process 3 lith        = 193 nm
Line 83: Line 83:
 
  | process 3 wafer size  = 300 mm
 
  | process 3 wafer size  = 300 mm
 
  | process 3 transistor  = FinFET
 
  | process 3 transistor  = FinFET
  | process 3 volt        = 0.50 V
+
  | process 3 volt        = 0.70 V
 
  | process 3 delta from  = [[14 nm]] Δ
 
  | process 3 delta from  = [[14 nm]] Δ
 
  | process 3 fin pitch    = &nbsp;
 
  | process 3 fin pitch    = &nbsp;

Revision as of 12:15, 17 March 2018

The 7 nanometer (7 nm) lithography process is a technology node semiconductor manufacturing process following the 10 nm process node. The term "7 nm" is simply a commercial name for a generation of a certain size and its technology and does not represent any geometry of a transistor. Commercial mass production of integrated circuit using 7 nm process is set to begin sometimes in 2019 or 2020. This technology will be replaced by 5 nm process around 2022.

Industry

Only four semiconductor foundries are able to develop the advanced 7nm: Intel, Samsung, TSMC, and GlobalFoundries.

Symbol version future.svg Preliminary Data! Information presented in this article deal with future products, data, features, and specifications that have yet to be finalized, announced, or released. Information may be incomplete and can change by final release.


 
Process Name
1st Production
Lithography Lithography
Immersion
Exposure
Wafer Type
Size
Transistor Type
Voltage
 
Fin Pitch
Width
Height
Gate Length (Lg)
Contacted Gate Pitch (CPP)
Minimum Metal Pitch (MMP)
SRAM bitcell High-Perf (HP)
High-Density (HD)
Low-Voltage (LV)
DRAM bitcell eDRAM
Intel TSMC GlobalFoundries Samsung Common Platform Paper
P1276 (CPU), P1277 (SoC) 7FF, 7FF+
will use EUVL instead of immersion lithography
, 7HPC
7LP
7nm Leading Performance
7LPE
7 nm Low Power Early
 
    2019 2019  
EUV 193 nm 193 nm EUV EUV
  Yes Yes    
  SAQP SAQP SE SE
Bulk Bulk Bulk Bulk Bulk
300 mm 300 mm 300 mm 300 mm 300 nm
  FinFET FinFET FinFET FinFet
  0.70 V 0.70 V    
Value 10 nm Δ Value 10 nm Δ Value 14 nm Δ Value 10 nm Δ Value 10 nm Δ
                   
                   
                   
                   
    54 nm 0.84x 56 nm 0.72x 54 nm 0.79x 48 nm 0.75x
    40 nm 0.95x 40 nm 0.63x 36 nm 0.7x 36 nm 0.75x
                   
    0.027 µm² 0.64x 0.0269 µm² 0.34x 0.0260 µm² 0.65x    
                   
                   

Intel

  • Note: For the most part, foundries' 7nm process is competing against Intel's 10nm process, not their 7nm.

On February 8 2017 Intel announced a $7B investment in Arizona's Fab 42 which will eventually produce chips on a 7 nm process. In May of 2017, Intel's Technology and Manufacturing Group Director, Mark Bohr, confirmed that Intel's 7 nm node has entered development phase and that the company's research focuses on the 5 nm and 3 nm nodes. Details of their 7 nm node have not been disclosed yet. CEO Brian Krzanich mentioned a 2020 timeframe in an investor conference in June.

GlobalFoundries

globalfoundries interconnect 7nm.jpg

On May 30 2017, GlobalFoundries Senior Vice President and head of CMOS Business Unit, Gregg Bartlett, announced their updated roadmap. Instead of EUV, the company will use multiple patterning 193i for their 7 nm node. The company is planning on first tape-out in the 2nd half of 2018 with mass production to begin in 2019. Bartlett noted that GF will switch to EUVL when it's ready.

The 7nm proces features SAQP for the FEOL, and double patterning for the BEOL. GlobalFoundries claims a 2.8 times density improvement compared to their 14nm proces, and a performance improvement of 40% or a 55% reduction in power consumption. Two versions of the process will be developed: a low power version for mobile applications. And a high performance version for desktop and server chips.

TSMC

7nm tsmc.jpeg

In ISSCC 2017, the memory group at TSMC detailed their test 256 MiB SRAM chip which featured a 42.64 mm² die. The chip is manufactured on TSMC's 7nm HK-MG FinFET process using 4P4E LELELELE patterning technique. The over die is 0.34x smaller than their 16 nm process version. TSMC's 7nm process density is 1.6X compared to their 10nm process. Minimum metal pitch is 40 nm, as reported at IEDM 2016. TSMC claims their 7nm process will deliver a 20% performance improvement and a 40% reduction in power consumption.

The 7nm node will come in two variants, one optimized for mobile applications and a second one optimized for High performance applications. TSMC plans to introduce a second improved process called 7nm+ a year later, which will introduce some layers processed with EUVL. This will improve yields and reduce fab cycle times. The 7nm+ process will deliver improved power consumption and between 15-20% area scaling over their first generation 7nm process.

Samsung

Samsung will use EUVL for their 7nm node and thus will be the first to introduce this new technology after more than a decade of development. On May 24 2017, Samsung released a press release of their updated roadmap. Due to delays in the introduction of EUVL, Samsung will introduce a new process called 8nm LPP, to bridge the gap between 10nm and 7nm. The process will be manufactured without the use of EUVL and will feature a slightly relaxed transistor size.

7 nm Microprocessors

This list is incomplete; you can help by expanding it.

7 nm Microarchitectures

See also

References

  • Chang, Jonathan, et al. "12.1 A 7nm 256Mb SRAM in high-k metal-gate FinFET technology with write-assist circuitry for low-V MIN applications." Solid-State Circuits Conference (ISSCC), 2017 IEEE International. IEEE, 2017.
  • Standaert, T., et al. "BEOL process integration for the 7 nm technology node." Interconnect Technology Conference/Advanced Metallization Conference (IITC/AMC), 2016 IEEE International. IEEE, 2016.
  • Samsung/GlobalFoundries, IEEE International Electron Devices Meeting (IEDM) 2016