The Japan Prize has released some videos of Grant Willson and Jean Frechet recieving the Japan Prize.

The award ceremony:

http://www.youtube.com/watch?feature=player_embedded&v=ksGG1DAXe9M

A Japanese-language life story of Drs. Willson and Frechet, with a review of photolithography and chemically amplified resists:

http://www.youtube.com/watch?v=zDfTaFeOLuM

The winners’ commemorative lectures:

http://www.youtube.com/watch?v=FRGUPzdmrlo

The 57th International Conference on Electron, Ion and Photon Beam Technology and Nanofabrication (EIPBN, aka three-beams, aka triple-beam) was held this week in Nashville. The conference moves to a new location each year, and I have to admit that my decision to attend is extremely dependent on its location. I had never been to Nashville before, so here I am. The attendance of 400 was down from last year, so I suspect that many enjoyed last year’s location in Hawaii better.

A word about the venue this year. It was at the Gaylord Opryland Resort, outside of town but right next to the Grand Ole Opry (and a Mall). The place is huge, with nearly 3000 rooms and numerous themed areas, and resembles a Las Vegas resort, but with country music instead of casinos. It has everything one would expect: artificial waterfalls, indoor palm trees, fountain and light shows, and plenty of shopping opportunities. And it realizes every southerner’s dream: the outdoors is air-conditioned.

Compared to this Disneified resort, the actual city of Nashville looks run down and dingy. Broadway (the equivalent of Sixth Street in Austin) is lined with dive bars and free music. I loved it. I found a group of recent PhDs with similar tastes and we managed to try quite a few local beers (Yazoo Pale Ale was my favorite) and catch some amazing music. I was glad for the opportunity the see the other famous music town in America (Nashville deserves its claim to second place, after Austin, as the Music Capital).

Thursday night was the conference banquet, and we were treated to a dinner on a Cumberland River paddle boat. In keeping with the theme, the boat was huge, and the entertainment was a Las Vegas-style review of country music. The quality of the entertainment was surprisingly good, until the last song – a jingoistic God Bless America number that was heavy on the cheese and that left the very international audience wondering how to react. But I guess it is impossible to end a country music montage without providing proof that country music fans are the best Americans.

As I say every time I write about the 3-beams conference, its value lies in its themed diversity. While I have focused in my career on lithography for high volume chip manufacturing, an unforgiving technology niche that demands ultra-high performance and ultra-low unit cost in equal measures, this conference focuses on the needs of flexible, low volume fabrication. High resolution is usually important, but the need to make only a few things rather than a billion things changes the optimization dramatically. There is no convergence to one best solution, but rather an organic and eclectic mix of possibilities. It is a broadening experience to attend.

I heard nothing earth shattering this year, and I certainly listened to some pretty bad talks. But there were a few really good ones as well. I liked Hiroshi Fukuda-san’s poster paper on analyzing LER measurements, though I didn’t understand it (I’ll need to study the written paper). I enjoyed hearing about David Czaplewski’s method for measuring electron beam lithography backscatter – an impressive show of rigorous engineering that is so frequently lacking in this field. Pieter Kruit’s progress report on Mapper did not leave me encouraged, and neither did Tony Yen’s report on EUV mask defectivity. Both areas are progressing, but too slowly.

Virtually every conference I attend produces a soap-box moment for me, and this one has been a long time coming. While I admire the many interesting approaches that researchers have tried over the years to improve resolution in optical printing, I get tired of hearing about how their latest new technique is finally “beating the diffraction limit” and enabling feature sizes that are smaller than could be had with conventional imaging techniques. The “diffraction limit” of conventional imaging is invariably described as half the wavelength (/2), and then the researcher will show an isolated feature (usually of very poor quality) with a size of /5, or possibly down to /8, as demonstration of blowing past the limits. Regardless of how interesting the approach may be, I can’t help but get riled up when I hear such language.

First, a diffraction limit of /2 is the smallest pitch that can be printed, not the smallest feature, and it assumes imaging in air, even though immersion imaging is the standard in lithography today. The smallest half-pitch that we print in lithography manufacturing today is /5 in size, using perfectly conventional imaging. And of course we make a billion features at this size for a dollar. If we want to print an isolated feature, we can easily thin that line to a size of /10, again while staying within the confines of the diffraction limit. (And this is before we start down the path of double patterning.) It is very rare when some university research project using an exotic optical approach produces something as good as, let alone better than, what is routine in the semiconductor manufacturing world. The diffraction limit defines the smallest pitch (the distance between two features) that can be printed. There is no diffraction limit to the smallest individual feature that can be made – that is just a matter of control, and chip makers are very, very good at control.

So, my advice to all you researchers looking for the next big thing in lithography: go for it. Keep doing good work, exploring new ideas, and learning about what light and nonlinear materials can do. It’s really cool stuff. But be careful when you say you are beating some limit, or doing better than “conventional” lithography, because the limits aren’t so limiting, and “conventional” lithography can do some amazing things.

And so ends my report on the 57th 3-beams conference. I gave a paper as well, and I am happy with the outcome. Now I am going back to Austin, and I mean no disrespect when I say that the barbeque and the beer and the music is better there than Nashville. I probably shouldn’t compare, because Nashville is rightly proud of what it has to offer. But I am glad to be going home.

Last week we saw the first casualty of the ASML purchase of Cymer. Ushio has announced that it is closing down its XTREME subsidiary in Germany. Now it is just Cymer and Gigaphoton still standing, hoping that they can make enough EUV photons to support at least one of them.

From the Ushio press release of May 9:

USHIO INC. today announced that it will close down the activities of XTREME technologies GmbH, a research and development company for Extreme Ultraviolet (EUV) light sources for next-generation semiconductor lithography, and consolidate the EUV light source business into a single unit in Japan and continue it for inspection and development applications in the future.

With this, the maintenance services for XTREME EUV light sources that were provided for ASML Netherlands B.V., a subsidiary of Netherland-based ASML Holding N.V., are transferred to ASML on May 9, local time.

For any lithographer in Silicon Valley that is interested, I’m calling a happy hour:

Wednesday, May 8, 5pm – ?
The Fault Line (www.faultlinebrewing.com)
Corner of Oakmead Parkway and Lakeside, Sunnyvale

We might solve the pressing problems facing lithography scaling, but we will surely enjoy a beer or two. Pass the word on to anyone you think might be interested.

The final day of the Advanced Lithography Symposium contains what is commonly referred to as the “tool” sessions, where tool makers give updates on their latest and greatest products. As such it tends to have the most commercial presentations, with all the problems that come with commercial pressures. For the EUV conference it is also the day where technology cheerleading, and skepticism, reaches a fevered pitch.

ASML described the status of their production EUV scanner, the NXE:3300B. Eleven systems are under construction, nine of which should ship to customers by the end of this year or early next year. These systems will ship regardless of the source power available, and so the most anticipated talk was given at 9 am by Cymer. To put this year’s report in perspective, one year ago Cymer was delivering a 9W (intermediate focus) EUV source to customers, claiming that a 20W source was about to be “available”, and predicting 100W by December 2012. The goal for production remains 250W. This year Cymer was “proud” to demonstrate 40W production-like performance and said sources for the 3300 had already been shipped to ASML. Let’s parse this announcement a bit.

What Cymer showed was a modified 3100 source that achieved 40W production-like performance for 6 hours one day last week, and 40W production-like performance for 6 hours one day this week. While a definite milestone, it is certainly not the same as delivering 40W performance to a customer for regular production-like use. So, in the last 12 months Cymer has doubled source power in the lab. In six months ASML will begin shipping tools with, they hope, an 80W source attached. I find it highly unlikely that this will be achieved. An 80W source should enable about 40 wafer-per-hour throughput or so, which will be fast enough to enable valuable production learning. Then Cymer will need to increase source power to 140W (and deliver that power to customers) by the end of 2014 to meet ASML’s stated goal of having EUV lithography that is producing chips at 70 wph by the end of 2014. Cymer has to beat Moore’s Law by a long shot, doubling source power twice in the next 18 months. That will be a hard job, indeed.

Next, Zeiss showed their progress and roadmap for EUV optical systems. An important question is how high can the NA go before two more mirrors are added (thus cutting the throughput in half). Their answer: 0.45. Since the NXE:3300 has an NA of 0.33, increasing the NA to 0.45 will allow the resolution to improve by a factor of about 0.73, close enough to the expected feature size reduction of 0.7 that a second generation of EUV production tools might take the technology to one more node. With off-axis illumination (and a low k1), 10-nm or 11-nm half-pitch might be possible with NA = 0.45. It will not be easy, though.

In the afternoon, the tool talks in the optical lithography conference touched on one of my pet peeves (some people claim I have too many pet peeves), so it is time to step up on the soap box again and talk about “lying with graphs”. There are many ways to lie with graphs, and most result from the practice of advocacy speech: using a graph to impress rather than inform. This is what marketing folks often do. It is not what scientists should do. Let me take as an example the topic of global warming. Hopefully everyone has seen plots of global surface temperatures that show a fairly steep rise over the last 50 years (close to 1 degree Centigrade). Now suppose you want to argue that global temperatures are not rising. One approach would be to plot the same data on a graph that has a y-axis origin of zero centigrade (or better yet, zero Kelvin). The result will be a trend that looks almost totally flat, since the variation will be hard to notice when squeezed into a few percent of the area of the graph. This technique works well whenever you want to show a flat trend in the data, regardless of the actual trend in the data.

The two laser talks, by Gigaphoton and Cymer, each displayed dozens of graphs that lie in exactly this way. Both lasers can control dose by pulse over time to within 0.2%. But to plot the data, they chose a y-axis that went from -1% to +1%, so that 80% of the y-axis range was unused. Wavelength stability, spectral bandwidth, beam position, beam profile size, divergence, and other laser metrics were plotted in the same way, sometimes using less than 10% of the y-axis range. Why even show the data if you purposely choose a y-axis that makes any data variation invisible? Obviously it is not to inform the audience. I’ve seen other talks over the years doing the same thing: wafer chuck temperature, aberrations across a slit, etc. There is a simple rule to prevent this: your data should use up 70% of the range of both the x- and y-axes. Don’t be caught lying with graphs.

And so ends another SPIE Advanced Lithography Symposium. 2012 was an interesting year in lithography. 2013 will be even more so.

Wednesday was, for me, a busy day since I had two talks to give. The first was the opening keynote talk at the Design for Manufacturability (DFM) conference entitled “The future of lithography and its impact on design”. The take-home message was that lithography would become less critical to the success of the industry, and that materials, device architecture, and design would be the key technologies of the future. You can find the presentation here. Afterwards I was surprised when a few people told me they found my presentation depressing or that they were now polishing up their resumes and thinking about a future career in design.

I saw a few updates on Mapper technology, that massively parallel e-beam technique that, if it works, could provide an important solution for complimentary lithography, especially in the foundry business. Unfortunately, their first pre-production system, the Matrix 1.1, won’t ship till the second half of this year. That tool will have over 1,000 beams and run at 1 wafer per hour (as opposed to the 0.002 wph throughput of the current demonstration system). As with EUV, getting tools with sufficient throughput to enable development is a critical milestone.

I attended a few talks on metrology and resist materials related to line-edge roughness (LER). They reported small progress, but nothing even close to a breakthrough in either understanding or performance. LER remains a tough nut to crack.

With several sessions, about 70 papers, a panel, and a short course devoted to directed self assembly (DSA), this topic has definitely turned a corner at the conference. But with success comes an inevitable problem: commercial papers. I heard many complaints from people about papers describing the benefits of “polymer A” over “polymer B”, graphs with no axes numbers, and papers meant to impress rather than inform. It is certainly a high price of success to trade integrity for profit.

There were some great papers at AL on Tuesday. Here are some of my favorites. Peter Trefonas of Dow created a photosensitive block copolymer using a class of molecules called bottle brush polymers. This very early work nonetheless exhibited very good results – close to 20 nm resolution (e-beam litho) with nearly the first bottle of stuff they mixed up. The idea is simple: marry the high resolution and high sensitivity of chemically amplified photoresists with the low line-edge roughness and good CD uniformity of self-assembled block copolymers. Cool. And it looked like great fun for the chemists.

Julius Santillan of the EUVL Infrastructure Development Corp in Japan wowed the metrology conference with a high-speed atomic force microscope (AFM) that could measure 32-nm line/space features in situ during development using a carbon nanotube fiber cantilever in tapping mode. With a scan time of 2 seconds (faster is possible, he says) for a pixel size of 2.5 nm and an area of 1000nm X 750nm, the tool made absolutely remarkable movies showing resist development and roughness formation in several different kinds of resists. The difference between PHS-based EUV resists and methacryl-based EUV resists was startling. The impact of resist development on LER was clear for all to see. Now the challenge is how best to use this new view into the physics of LER formation.

The progress in directed self-assembly (DSA) since last year has been remarkable, as evidence by the number of papers on the topic this year if nothing else. The science is advancing, the technology is advancing, and the practice is advancing. We can make very tight pitch lines and spaces with DSA, but how can we cut them to make circuit patterns? Why, with DSA of course! Even better than small lines and spaces, DSA is good at making small contact holes (though not on a super-tight pitch). So the topic that most caught my attention today was the idea of using DSA-shrunk contact holes to the cut the DSA lines. The 14/10nm node(s) could be made with two 193i patterning steps (and thus only two masks), but with significant design/layout impact. This is a very, very interesting approach. I think we will hear much more about this in the next year.

As the afternoon turned to evening I went from a panel discussion on DSA to the poster session, with a “super panel” pulling in all the conferences still in store. But when the good beer ran out at the poster session, I took the opportunity to retire for the evening and let Aki Fujimura buy me an expensive dinner (thank you, Aki!). And there is still that pesky business of getting my talks ready for Wednesday. Yes, this is life at the Advanced Lithography Symposium.