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EUVL Materials Readiness for HVM

Friday, June 2nd, 2017


By Ed Korczynski, Sr. Technology Editor

Extreme-Ultra-Violet Lithography (EUVL)—based on ~13.5nm wavelength EM waves bouncing off mirrors in a vacuum—will finally be used in commercial IC fabrication by Intel, Samsung, and TSMC starting in 2018. In a recent quarterly earning calls ASML reported a backlog of orders for 21 EUVL tools. At the 2017 SPIE Advanced Lithography conference, presentations detailed how the source and mask and resist all are near targets for next year, while the mask pellicle still needs work. Actinic metrology for mask inspection still remains a known expensive issue to solve.

Figure 1 shows minimal pitch line/space grids and contact-hole arrays patterned with EUVL at global R&D hub IMEC in Belgium, as presented at the recent 2017 IMEC Technology Forum. While there is no way with photolithography to escape the trade-offs of the Resolution/Line-Width-Roughness/Sensitivity (RLS) triangle, patterning at the leading edge of possible pitches requires application-specific etch integration. The bottom row of SEMs in this figure all show dramatic improvements in LWR through atomic-scale etch and deposition treatments to patterned sidewalls.

Fig.1: SEM plan-view images of minimum pitch Resolution and Line-Width-Roughness and Sensitivity (RLS) for both Chemically-Amplified Resist (CAR) and Non-Chemically-Amplified Resist (NCAR, meaning metal-oxide solution from Inpria) formulations, showing that excessive LWR can be smoothed by various post-lithography deposition/etch treatments. (Source: IMEC)

ASML has recently claimed that as an indication of continued maturity, ASML’s NXE:33×0 steppers have now collectively surpassed one million processed wafers to date, and only correctly exposed wafers were included in the count. During the company’s 1Q17 earnings call, it was reported that three additional orders for NXE:3400B steppers were received in Q1 adding  to a total of 21 in backlog, worth nearly US$2.5B.

At $117M each NXE:3400B, assuming 10 years useful life it costs $32,000 each day and assuming 18 productive hours/day and 80 wafers/hour then it costs $22 per wafer-pass just for tool depreciation. In comparison, a $40M argon-fluoride immersion (ArFi) stepper over ten years with 21 available hours/day and 240 wafers/hour costs $2.2 per wafer-pass for depreciation. EUVL will always be an expensive high-value-add technology, even though a single EUVL exposure can replace 4-5 ArFi exposures.

Fabs that delay use of EUVL at the leading edge of device scaling will instead have to buy and facilitize many more ArFi tools, demanding more fab space and more optical lithography gases. SemiMD spoke with Paul Stockman, Linde Electronics’ Head of Market Development, about the global supply of specialty neon and xenon gas blends:  “Xenon is only a ppm level component of the neon-blend for Kr and Ar lasers, so there should be no concerns with Xenon supply for the industry. In our modeling we’ve realized the impact of multi-patterning on gas demand, and we’ve assumed that the industry would need multi-patterning in our forecasts.” said Stockman.

“From the Linde perspective, we manage supply carefully to meet anticipated customer demand,” reminded Stockman. “We recently added 40 million liters of neon capacity in the US, and continue to add significant supply with partners so that we can serve our customers regardless of the EUV scenario.” (Editor’s note: reported by SemiMD here.)

At SPIE Advanced Lithography 2017, SemiMD discussed multi-patterning process flows with Uday Mitra and Regina Freed of Applied Materials. “We need a lot of materials engineering now,” explained Freed. “We need new gap-fills and hard-masks, and we may need new materials for selective deposition. Regarding the etch, we need extreme selectivity with no damage, and ability to get into the smallest features to take out just one atomic layer at a time.”

Reminding us that IC fabs must be risk-averse when considering technology options, Mitra (formerly with Intel) commented, “You don’t do a technology change and a wafer size change at the same time. That’s how you risk manage, and you can imagine with something like EUVL that customers will first use it for limited patterning and check it out.”

Figure 2 lists the major issues in pattern-transfer using plasma etch tools, along with the process variables that must be controlled to ensure proper pattern fidelity. Applied Materials’ Sym3 etch chamber features hardware that provides pulsed energy at dual frequencies along with low residence time of reactant byproducts to allow for precise tuning of process parameters no matter what chemistry is needed.

Fig.2: Patterning issues and associated etch process variables which can be used for control thereof. (Source: Applied Materials)

Andrew Grenville, CEO of resist supplier Inpria, in an exclusive interview with SemiMD, commented on the infrastructure readiness for EUVL volume production. “We are building up our pilot line facility in Corvallis, Oregon. The timing for that is next year, and we are putting in place plans to continue to scale up the new materials at the same times as the quality control systems such as functional QC.” The end-users ask for quality control checks of more parameters, putting a burden on suppliers to invest in more metrology tools and even develop new measurement techniques. Inpria’s resist is based on SnOx nanoparticles, which provide for excellent etch resistance even with layers as thin as 20nm, but required the development of a new technique to measure ppb levels of trace metals in the presence of high tin signals.

“We believe that there is continued opportunity for improvement in the overall patterning performance based on the ancillaries, particularly in simplifying the under-layers. One of the core principles of our material is that we’re putting the ‘resist’ back in the resist,” enthused Grenville. “We can show the etch contrast of our material can really improve the Line-Width Roughness of the patterns because of what you can do in etch, and it’s not merely smoothing the resist. We can substantially improve the outcome by engineering the stack and the etch recipe using completely different chemistry than could be used with chemically-amplified resist.”

The 2017 EUVL Workshop (2017 International Workshop on EUV Lithography) will be held June 12-15 at The Center for X-ray Optics (CXRO) at Lawrence Berkeley National Laboratory in Berkeley, CA. This workshop, now in its tenth year, is focused on the fundamental science of EUV Lithography (EUVL). Travel and hotel information as well as on-line registration is available at

[DISCLOSURE:  Ed Korczynski is also Sr. Analyst for TECHCET responsible for the Critical Materials Report (CMR) on Photoresists, Extensions & Ancillaries.]


Applied Materials Releases Selective Etch Tool

Wednesday, June 29th, 2016


By Ed Korczynski, Sr. Technical Editor

Applied Materials has disclosed commercial availability of new Selectra(TM) selective etch twin-chamber hardware for the company’s high-volume manufacturing (HVM) Producer® platform. Using standard fluorine and chlorine gases already used in traditional Reactive Ion Etch (RIE) chambers, this new tool provides atomic-level precision in the selective removal of materials in 3D devices structures increasingly used for the most advanced silicon ICs. The tool is already in use at three customer fabs for finFET logic HVM, and at two memory fab customers, with a total of >350 chambers planned to have been shipped to many customers by the end of 2016.

Figure 1 shows a simplified cross-sectional schematic of the Selectra chamber, where the dashed white line indicates some manner of screening functionality so that “Ions are blocked, chemistry passes through” according to the company. In an exclusive interview with Solid State Technology, company representative refused to disclose any hardware details. “We are using typical chemistries that are used in the industry,” explained Ajay Bhatnagar, managing director of Selective Removal Products for Applied Materials. “If there are specific new applications needed than we can use new chemistry. We have a lot of IP on how we filter ions and how we allow radicals to combine on the wafer to create selectivity.”

FIG 1: Simplified cross-sectional schematic of a silicon wafer being etched by the neutral radicals downstream of the plasma in the Selectra chamber. (Source: Applied Materials)

From first principles we can assume that the ion filtering is accomplished with some manner of electrically-grounded metal screen. This etch technology accomplishes similar process results to Atomic Layer Etch (ALE) systems sold by Lam, while avoiding the need for specialized self-limiting chemistries and the accompanying chamber throughput reductions associated with pulse-purge process recipes.

“What we are doing is being able to control the amount of radicals coming to the wafer surface and controlling the removal rates very uniformly across the wafer surface,” asserted Bhatnagar. “If you have this level of atomic control then you don’t need the self-limiting capability. Most of our customers are controlling process with time, so we don’t need to use self-limiting chemistry.” Applied Materials claims that this allows the Selectra tool to have higher relative productivity compared to an ALE tool.

Due to the intrinsic 2D resolutions limits of optical lithography, leading IC fabs now use multi-patterning (MP) litho flows where sacrificial thin-films must be removed to create the final desired layout. Due to litho limits and CMOS device scaling limits, 2D logic transistors are being replaced by 3D finFETs and eventually Gate-All-Around (GAA) horizontal nanowires (NW). Due to dielectric leakage at the atomic scale, 2D NAND memory is being replaced by 3D-NAND stacks. All of these advanced IC fab processes require the removal of atomic-scale materials with extreme selectivity to remaining materials, so the Selectra chamber is expected to be a future work-horse for the industry.

When the industry moves to GAA-NW transistors, alternating layers of Si and SiGe will be grown on the wafer surface, 2D patterned into fins, and then the sacrificial SiGe must be selectively etched to form 3D arrays of NW. Figure 2 shows the SiGe etched from alternating Si/SiGe stacks using a Selectra tool, with sharp Si corners after etch indicating excellent selectivity.

FIG 2: SEM cross-section showing excellent etch of SiGe within alternating Si/SiGe layers, as will be needed for Gate-All-Around (GAA) horizontal NanoWire (NW) transistor formation. (Source: Applied Materials)

“One of the fundamental differences between this system and old downstream plasma ashers, is that it was designed to provide extreme selectivity to different materials,” said Matt Cogorno, global product manager of Selective Removal Products for Applied Materials. “With this system we can provide silicon to titanium-nitride selectivity at 5000:1, or silicon to silicon-nitride selectivity at 2000:1. This is accomplished with the unique hardware architecture in the chamber combined with how we mix the chemistries. Also, there is no polymer formation in the etch process, so after etching there are no additional processing issues with the need for ashing and/or a wet-etch step to remove polymers.”

Systems can also be used to provide dry cleaning and surface-preparation due to the extreme selectivity and damage-free material removal.  “You can control the removal rates,” explained Cogorno. “You don’t have ions on the wafer, but you can modulate the number of radicals coming down.” For HVM of ICs with atomic-scale device structures, this new tool can widen process windows and reduce costs compared to both dry RIE and wet etching.