Tag Archives: litho

SAQP Specs for 7nm finFETs

As discussed in my last Ed’s Threads, lithography has become patterning as evidenced by first use of Self-Aligned Quadruple Patterning (SAQP) in High Volume Manufacturing (HVM) of memory chips. Meanwhile, industry R&D hub imec has been investigating use of SAQP for “7nm” and “5nm” node finFET HVM, as reported as SPIE-AL this year in Paper 9782-12.
The specifications for pitches ranging from 18 to 24 nanometers are as follow:

  • 7.0nm Critical Dimension (CD) after etch,
  • 0.5nm (3sigma) CD uniformity (CDU), and
  • <1nm Line-Width and Line-End Roughness (LWR and LER) assuming 10% of CD.

“Pitch walk”—variation in final pitch after multi-patterning—results in different line widths, and can result in subsequent excessive etch variation due to non-uniform loading effects. To keep the pitch walk in SAQP at acceptable levels for the 7nm node, the core-1 CDU has to be 0.5nm 3sigma and 0.8nm range after both litho and etch. In other presentations at SPIE-AL this year, the best LER after litho was ~4nm, improving to ~2nm after PEALD smoothing of sidewalls, but still double the desired spec.

The team at imec developed a SAQP flow using amorphous-Carbon (aC) and amorphous-Silicon (aSi) as the cores, and low-temperature Plasma-Enhanced Atomic-Layer Deposition (PEALD) of SiO2 for both sets of spacers. Bilayer DARC (SiOC) and BARC were used for reflectivity control. Compared to SAQP schemes where the mandrels are only aSi, imec claims that this approach saves 20% in cost due to the use of aC core and the elimination of etch-stopping-layers.

—E.K.

Litho becomes Patterning

Once upon a time, lithographic (litho) processes were all that IC fabs needed to transfer the design-intent into silicon chips. Over the last 10-15 years, however, IC device structural features have continued to shrink below half the wavelength of the laser light used in litho tools, such that additional process steps are needed to form the desired features. Self-Aligned Double Patterning (SADP) schemes use precise coatings deposited as “spacers” on the sidewalls of mandrels made from developed photoresist or a sacrificial material at a given pitch, such that after selective mandrel etching the spacers pitch-split. SADP has been used in HVM IC fabs for many years now. Self-Aligned Quadruple Pattering (SAQP) has reportedly been deployed in a memory IC fab, too.

An excellent overview of the patterning complexities of SAQP was provided by Sophie Thibaut of TEL in a presentation at SPIE-AL on “SAQP integration using spacer on spacer pitch splitting at the resist level for sub-32nm pitch applications.” Use of a spacer-on-spacer process flow—enabled by clever combinations of SiO2 and TiO2 spacers deposited by Atomic Layer Deposition (ALD)—requires the following unit-process steps:
1 193i litho,
2 ALD spacers,
2 wet etches, and
4 plasma etches.

Since non-litho processes dominate the transfer of design-intent to silicon, from first principles we should consider such integrated flows as “patterning.” Etch selectivity to remove one material while leaving another, and deposition dependent on underlying materials determine much of the pattern fidelity. Such process flows are new to IC fabs, but have been used for decades in the manufacturing of Micro-Electrical Mechanical Systems (MEMS), though generally on a patterning length scale of microns instead of the nanometers needed for advanced ICs. R&D labs today are even experimenting with Self-Aligned Octuple Patterning (SAOP), and based on the legacy of MEMS processing it certainly could be done.

—E.K.

ASML Books Production EUV Orders

TSMC commits to two tools for delivery next year

Maybe, just maybe, ASML Holding N.V. (ASML) has made the near-impossible a reality by creating a cost-effective Extreme Ultra-Violet (EUV @ ~13.5nm wavelength) all-reflective lithographic tool. The company has announced that Taiwan Semiconductor Manufacturing Company Ltd. (TSMC) has ordered two NXE:3350B EUV systems for delivery in 2015 with the intention to use those systems in production. In addition, two NXE:3300B systems already delivered to TSMC will be upgraded to NXE:3350B performance. While costs and throughputs are conspicuously not-mentioned, this is still an important step for the industry.
Perhaps acquiring Cymer to get the source-technology in-house for tighter integration was important. Perhaps evolutionary improvements crept along by tough engineering rigor. Perhaps the industry got lucky. One way or the other, ASML has had the goal of delivering not just hardware but functional uptime/availability using very complex EUV technology, and now it seems to be on the cusp of making it happen. The company claims that current EUV tools are available 50% of the time, at unspecified source power levels.
At its Investor Day in London today, ASML outlined its expected opportunity to grow net sales to about EUR 10 billion and to triple earnings per share by 2020, an indication of the confidence the company has in its technology and employees. Much of the growth will be in Deep-UV immersion tools, and in so-called “Holistic Lithography” products to deliver advanced correction capabilities. An example of Holistic Litho is Source-Mask-Optimization (SMO) that can be used for triple-patterning of a 48nm minimum pitch metal layer using DUV immersion in a Litho-Etch-Litho-Etch-Litho-Etch (LELELE) flow, such that the Depth-of-Focus (DoF) can be increased from 70 to 86nm. Holistic EUV means that SMO can reduce the dose required to get 120nm DoF from 46 to 20 mJ/cm2 for a 45nm minimum pitch metal layer.
The presentations can be found at the company’s website.
— E. K.