Wednesday, August 7th 2024

Imec Demonstrates Logic and DRAM Structures Using High NA EUV Lithography

Imec, a world-leading research and innovation hub in nanoelectronics and digital technologies, presents patterned structures obtained after exposure with the 0.55NA EUV scanner in the joint ASML-imec High NA EUV Lithography Lab in Veldhoven, the Netherlands. Random logic structures down to 9,5 nm (19 nm pitch), random vias with 30 nm center-to-center distance, 2D features at 22 nm pitch, and a DRAM specific lay out at P32nm were printed after single exposure, using materials and baseline processes that were optimized for High NA EUV by imec and its partners in the framework of imec's Advanced Patterning Program. With these results, imec confirms the readiness of the ecosystem to enable single exposure high-resolution High NA EUV Lithography.

Following the recent opening of the joint ASML-imec High NA EUV Lithography Lab in Veldhoven, the Netherlands, customers now have access to the (TWINSCAN EXE:5000) High NA EUV scanner to develop private High NA EUV use cases leveraging the customer's own design rules and lay outs.
Imec has successfully patterned single exposure random logic structures with 9,5 nm dense metal lines, corresponding to a 19 nm pitch, achieving sub 20 nm tip-to-tip dimensions. Random vias with a 30 nm center-to-center distance showcased excellent pattern fidelity and critical dimension uniformity. Furthermore, 2D features at a P22nm pitch exhibited outstanding performance, highlighting the potential of High NA Lithography to enable 2D routing.

Beyond logic structures, imec successfully patterned, in a single exposure, designs that integrate the storage node landing pad with the bit line periphery for DRAM. This achievement underscores the potential of High NA technology to replace the need of several mask layers by 1 single exposure.

These breakthrough results follow intensive preparatory work by imec and ASML - in close collaboration with its partners - to ready the patterning ecosystem and metrology for the first generation of High NA EUV Lithography. Prior to the exposures, imec prepared dedicated wafer stacks (including advanced resists, underlayers and photomasks), and transferred High NA EUV baseline processes (such as optical proximity correction (OPC), integrated patterning and etch techniques) to the 0.55NA EUV scanner.
Steven Scheer, senior vice president of compute technologies & systems / compute system scaling at imec: "We are thrilled to demonstrate the world's first High NA-enabled logic and memory patterning in the joint ASML-imec lab as an initial validation of industry applications. The results showcase the unique potential for High NA EUV to enable single-print imaging of aggressively-scaled 2D features, improving design flexibility as well as reducing patterning cost and complexity. Looking ahead, we expect to provide valuable insights to our patterning ecosystem partners, supporting them in further maturing High NA EUV specific materials and equipment."
Luc Van den hove, president and CEO of imec: "The results confirm the long-predicted resolution capability of High NA EUV lithography, targeting sub 20 nm pitch metal layers in one single exposure. High NA EUV will therefore be highly instrumental to continue the dimensional scaling of logic and memory technologies, one of the key pillars to push the roadmaps deep into the 'angstrom era'. These early demonstrations were only possible thanks to the set-up of the joint ASML-imec lab allowing our partners to accelerate the introduction of High NA lithography into manufacturing.".
Source: Imec
Add your own comment

5 Comments on Imec Demonstrates Logic and DRAM Structures Using High NA EUV Lithography

#1
Vincero
Can't tell if this is more aimed as a feature 'improvement' in terms of what is available or new tech that essentially allows a cost reduced process to be used instead...
Posted on Reply
#2
Nomad76
News Editor
VinceroCan't tell if this is more aimed as a feature 'improvement' in terms of what is available or new tech that essentially allows a cost reduced process to be used instead...
Faster process (single exposure), simpler production line/process, more advanced chip internal circuits/logic...
Posted on Reply
#3
Shrek
Sure looks like a lot of cross connects to me.

Posted on Reply
#4
Wirko
VinceroCan't tell if this is more aimed as a feature 'improvement' in terms of what is available or new tech that essentially allows a cost reduced process to be used instead...
A bit of both. A coarse process cam be used to draw fine structures on the chip. An example would be DUV for the 5 nm node. But the cost is unbearable.
Posted on Reply
#5
Minus Infinity
VinceroCan't tell if this is more aimed as a feature 'improvement' in terms of what is available or new tech that essentially allows a cost reduced process to be used instead...
Currently low NA EUV with multipatterning produces just as small features for far less money. High NA won't be viable until we hit 1.4nm or smaller. High NA EUV machines cost ~ 4x much as current low NA machines. Intel raced to be first to buy the tech and bought 6 or 7 machines at nearly $3 billion dollars.
Posted on Reply
Dec 21st, 2024 21:26 EST change timezone

New Forum Posts

Popular Reviews

Controversial News Posts