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Line 32: | Line 32: | ||
| process 1 mmp Δ = 0.71x | | process 1 mmp Δ = 0.71x | ||
| process 1 sram hp = 0.130 µm² | | process 1 sram hp = 0.130 µm² | ||
− | | process 1 sram hp Δ = | + | | process 1 sram hp Δ = 0.65x |
| process 1 sram hd = 0.092 µm² | | process 1 sram hd = 0.092 µm² | ||
− | | process 1 sram hd Δ = | + | | process 1 sram hd Δ = 0.62x |
| process 1 sram lv = 0.108 µm² | | process 1 sram lv = 0.108 µm² | ||
− | | process 1 sram lv Δ = | + | | process 1 sram lv Δ = 0.63x |
| process 1 dram = 0.029 µm² | | process 1 dram = 0.029 µm² | ||
| process 1 dram Δ = | | process 1 dram Δ = | ||
Line 92: | Line 92: | ||
| process 3 gate len Δ = | | process 3 gate len Δ = | ||
| process 3 cpp = 100 nm | | process 3 cpp = 100 nm | ||
− | | process 3 cpp Δ = | + | | process 3 cpp Δ = 0.79x |
| process 3 mmp = 80 nm | | process 3 mmp = 80 nm | ||
− | | process 3 mmp Δ = | + | | process 3 mmp Δ = 0.80x |
| process 3 sram hp = 0.144 µm² | | process 3 sram hp = 0.144 µm² | ||
− | | process 3 sram hp Δ = | + | | process 3 sram hp Δ = |
| process 3 sram hd = 0.128 µm² | | process 3 sram hd = 0.128 µm² | ||
− | | process 3 sram hd Δ = | + | | process 3 sram hd Δ = 0.82x |
− | | process 3 sram lv = | + | | process 3 sram lv = |
− | | process 3 sram lv Δ = | + | | process 3 sram lv Δ = |
| process 3 dram = 0.026 µm² | | process 3 dram = 0.026 µm² | ||
− | | process 3 dram Δ = | + | | process 3 dram Δ = |
}} | }} | ||
Revision as of 20:18, 6 April 2017
The 22 nanometer (22 nm) lithography process is a full node semiconductor manufacturing process following the 28 nm process stopgap. The term "22 nm" is simply a commercial name for a generation of a certain size and its technology, as opposed to gate length or half pitch. Commercial integrated circuit manufacturing using 22 nm process began in 2008 for memory and 2012 for MPUs. This technology was replaced by with 20 nm process (HN) in 2014 and 16 nm process (FN) in late 2015.
Contents
Industry
The 22 nm became Intel's first generation of Tri-gate FinFET transistors and the first such transistor on the market. This process became 3rd generation high-k + metal gate transistors for Intel. In 2017 Intel announce the introduction of a new process "22FFL" specifically for low power IOT and mobile products for their custom foundry.
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 | Intel | IBM | |||
---|---|---|---|---|---|
P1270 (CPU) / P1271 (SoC) | 22FFL | ||||
2011 | 2017 | 2013 | |||
193 nm | 193 nm | 193 | |||
Yes | Yes | Yes | |||
SADP | SADP | ||||
Bulk | Bulk | SOI | |||
300 mm | 300 mm | 300 mm | |||
FinFET | FinFET | Planar | |||
0.75 V | |||||
Value | 32 nm Δ | Value | 32 nm Δ | Value | 32 nm Δ |
60 nm | N/A | 45 nm | N/A | N/A | |
8 nm | |||||
34 nm | |||||
26 nm | 30 nm | ||||
90 nm | 0.80x | 108 nm | 100 nm | 0.79x | |
80 nm | 0.71x | 90 nm | 80 nm | 0.80x | |
0.130 µm² | 0.65x | 0.144 µm² | |||
0.092 µm² | 0.62x | 0.088 µm² | 0.128 µm² | 0.82x | |
0.108 µm² | 0.63x | ||||
0.029 µm² | 0.026 µm² |
Intel
Intel 22nm SoC Interconnect Design Rules | ||||||
---|---|---|---|---|---|---|
Layer | Pitch | Process | Dielectric Materials | CPU | SoC | Image |
Fin | 60 nm | - | - | Fin | Fin | |
Contact | 90 nm | SAC | - | Contact | Contact | |
M1 | 90 nm | SAV | ULK CDO | M1 | M1 | |
MT - 1x | 80 nm | SAV | ULK CDO | M2/M3 | 2-6 layers | |
MT - 1.4x | 112 nm | SAV | ULK CDO | M4 | Semi-global | |
MT - 2x | 160 nm | SAV | ULK CDO | M5 | Semi-global | |
MT - 3x | 240 nm | SAV | ULK CDO | M6 | Global Routing | |
MT - 4x | 320 nm 360 nm |
Via First | LK CDO | M7/M8 | Global Routing | |
MT - TOP | 14 µm | Plate Up | Polymer | M9 | Top Metal |
Intel 22nm SoC Transistor Characteristics | ||||||
---|---|---|---|---|---|---|
Transistor Type | High Speed Logic | Low Power Logic | High Voltage Logic | |||
Options | High Performance (HP) | Standard Perf/Power (SP) | Low Power (LP) | Ultra-Low Power (ULP) | 1.8 V | 3.3 V |
Vdd (V) | 0.75 V / 1 V | 0.75 V / 1 V | 0.75 V / 1 V | 0.75 V / 1.2 V | 1.5 V / 1.8 V / 3.3 V | 3.3 V / >5V |
Gate Pitch (nm) | 90 | 90 | 90 | 108 | min. 180 | min 450 |
Lgate (nm) | 30 | 34 | 34 | 40 | min. 80 | in 280 |
N/PMOS Idsat/Ioff (mA/µm) | 1.08/0.91 @ 0.75 V, 100 nA/µm | 0.71/0.59 @0.75 V, 1 nA/µm | 0.41/0.37 @ 0.75 V, 30 pA/µm | 0.35/0.33 @ 0.75 V, 15 pA/µm | 0.92/0.8 @ 1.8 V, 10 pA/µm | 1/0.8 @ 3.3 V, 10 pA/µm |
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22 nm Microprocessors
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Click to browse all 22 nm MPU models
22 nm Microarchitectures
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Documents
References
- Narasimha, S., et al. "22nm High-performance SOI technology featuring dual-embedded stressors, Epi-Plate High-K deep-trench embedded DRAM and self-aligned Via 15LM BEOL." Electron Devices Meeting (IEDM), 2012 IEEE International. IEEE, 2012.
- Natarajan, S., et al. "A 14nm logic technology featuring 2 nd-generation FinFET, air-gapped interconnects, self-aligned double patterning and a 0.0588 µm 2 SRAM cell size." Electron Devices Meeting (IEDM), 2014 IEEE International. IEEE, 2014.
- Hamzaoglu, Fatih, et al. "13.1 a 1Gb 2GHz embedded DRAM in 22nm tri-gate CMOS technology." Solid-State Circuits Conference Digest of Technical Papers (ISSCC), 2014 IEEE International. IEEE, 2014.