Your search keyword '"Jin Udagawa"' showing total 5 results

1. Full-field exposure performance of electron projection lithography tool

Author

Saori Fukui, Aoyama Takashi, Kazuaki Suzuki, Toshimasa Shimoda, Takaharu Miura, Tomoharu Fujiwara, Hiroshi Hirose, Junji Ikeda, Futoshi Mori, Hiroyasu Shimizu, Hidekazu Takekoshi, Shigeru Takemoto, Norihiro Katakura, Takehisa Yahiro, Toru Tanida, Kenji Morita, Yoshiaki Kohama, Suzuki Motoko, Atsushi Yamada, Takaaki Umemoto, Yukiharu Ohkubo, Teruaki Okino, Kaoru Ohmori, Takeshi Yoshioka, Yoichi Watanabe, Yukio Kakizaki, Shintaro Kawata, Shohei Suzuki, Noriyuki Hirayanagi, Shinichi Kojima, Hajime Yamamoto, Jin Udagawa, and Kazunari Hada

Subjects

Physics, Depth of focus, business.industry, General Engineering, law.invention, Image stitching, Optics, law, Reticle, X-ray lithography, Stepper, Photolithography, business, Lithography, Electron-beam lithography

Abstract

Electron projection lithography (EPL) is a realistic technology for the 65nm node and below, as a complementary technology of optical lithography especially for contacts and gate layers because of its high resolution and large process margin. Nikon has developed an EPL exposure tool as an electron-beam (EB) stepper and the first generation EB stepper; NSR-EB1A is now almost completed as an R&D tool for the 65nm technology node. Using a ϕ200mm reticle, a 20mm×25mm exposure field is realized. Full-field exposure performance of NSR-EB1A is shown. A 70nm isolated line and 1:1 nested lines are simultaneously resolved, as are 50nm 1:2 nested lines. 60nm contact holes are resolved with a depth of focus over a 10μm range and dosage window over ±6%. Stitching accuracy is about 20nm (3σ) and the single machine overlay is about 30nm (mean + 3σ). These data mean sufficient performance for device manufacturing of the 65nm technology node. The concept of a large subfield is one candidate for resolution and throughput e...

Published

2004

2. High overlay accuracy for double patterning using an immersion scanner

Author

Chihaya Motoyoshi, Katsushi Makino, Yuji Shiba, Hajime Yamamoto, Yuuki Ishii, Yasuhiro Morita, Jin Udagawa, Takahisa Kikuchi, and Yosuke Shirata

Subjects

Scanner, Semiconductor device fabrication, business.industry, Computer science, Node (networking), Immersion (virtual reality), Multiple patterning, Optoelectronics, Overlay, business, Telecommunications, Lithography

Abstract

Double patterning (DP) is widely regarded as the lithography solution for 32 nm half pitch semiconductor manufacturing, and DP will be the most likely litho technology for the 22 nm node [1]. When using the DP technique, overlay accuracy and CD control are of critical importance [2]. We previously introduced the NSR-S620D immersion scanner, which provides 2 nm overlay capabilities. In the case of the latest generation NSR-S621D system, improvements have been developed for further overlay accuracy enhancement. In this paper, we will show the overlay accuracy and Mix-and-Match performance of the NSR-S621D. Further, the marked improvement in product overlay and the overlay result in Spacer DP as a result of enhanced alignment accuracy will also be shown.

Published

2012

3. Nikon EPL tool: the latest development status and results

Author

Atsushi Yamada, Kaoru Ohmori, Yukiharu Ohkubo, Kazuaki Suzuki, Junji Ikeda, Yoichi Watanabe, Toshimasa Shimoda, Noriyuki Hirayanagi, Takaaki Umemoto, Yukio Kakizaki, Kenji Morita, Takehisa Yahiro, Masaya Miyazaki, Takaharu Miura, Futoshi Mori, Toru Tanida, Shigeru Takemoto, Takeshi Yoshioka, Hidekazu Takekoshi, Kazunari Hada, Jin Udagawa, and Shintaro Kawata

Subjects

Image stitching, Engineering, Depth of focus, Optics, business.industry, Wafer, Node (circuits), Overlay, Stepper, business, Lithography, Computer hardware, AND gate

Abstract

Electron Projection Lithography (EPL) is considered one of promising technologies below 45nm node, especially for contact/via holes and gate layers. EPL has some nice features such as very high resolution to be applied for two device nodes, large process margin associated with large depth of focus and an expected lower CoO. Nikon has been developing an EPL tool, so-called EB Stepper. NSR-EB1A is the first EB Stepper that was designed as R&D tool for 65nm technology node and that was already delivered for Selete (Semiconductor Leading Edge Technologies, Inc.) at Tsukuba in Japan. Nikon has developed two NSR-EB1A tools so far, one system for Selete as a 300mm wafer system and the other for Nikon's development and evaluation as a 200mm wafer system. Both tools have already started to show full performance data and good stability characteristics. The latest EB1A tool performance shows very good results in such data as the resolution of 50nm 2:1 L/S and 60nm 1:1 dense contact holes patterns, stitching accuracy of around 18nm, and overlay accuracy of around 20nm(X+3sigma).

Published

2005

4. Total performance of Nikon EB stepper R&D tool

Author

Sumito Shimizu, Kazuaki Suzuki, Jin Udagawa, Hidekazu Takekoshi, Junji Ikeda, Tomoharu Fujiwara, and Noriyuki Hirayanagi

Subjects

Image stitching, Engineering, Optics, business.industry, Cathode ray, Reticle, Wafer, Overlay, Stepper, business, Lithography, Electron-beam lithography

Abstract

The development of Electron Projection Lithography (EPL) has proceeded for more than 10 years since its first description. EPL is regarded as a practical technology for 65 nm technology node and below. Nikon has been developing an EPL tool, named as the EB stepper. NSR-EB1A is the first EPL tool that has full functions for practical R&D use such as dynamic exposure by combination of electron beam deflection and stage scanning, wafer alignment, and so on. Some features of the EB stepper, which uses a 100 kV electron beam, are high resolution, and a large process margin associated with large depth of focus (DOF). Large DOF is a major feature of electron beam lithography. In the previous paper, we reported data of dynamic resolution and subfield stitching accuracy as preliminary performances that were obtained by NSR-EB1A. Recently the development of EPL reticle is significantly progressed. Today, high quality 200 mm diameter EPL reticle is available from plural mask suppliers. Using 200mm EPL reticle, we achieved subfield stitching accuracy about 20nm (3s). And we also evaluated total performance such as CD uniformity, overlay accuracy. This paper reports the latest performance of NSR-EB1A.

Published

2004

5. First dynamic exposure results from an electron projection lithography tool

Author

Shigeru Takemoto, Yukiharu Ohkubo, Suzuki Motoko, Shinichi Kojima, Kazuya Okamoto, Takeshi Yoshioka, Kaminaga Takeshi, Toru Tanida, Atsushi Yamada, Sumito Shimizu, Hiroyasu Shimizu, Masateru Tokunaga, Keiichi Hirose, Muneki Hamashima, Takaharu Miura, Tatsuo Sato, Kazunari Hada, Teruaki Okino, Yu Sato, Takehisa Yahiro, Jin Udagawa, Tomoharu Fujiwara, Shin-ichi Takahashi, Yoshiaki Kohama, Junji Ikeda, Hajime Yamamoto, Noriyuki Hirayanagi, Shintaro Kawata, Satoshi Katagiri, Hiroshi Hirose, Futoshi Mori, Takaaki Umemoto, Kazuaki Suzuki, Toshimasa Shimoda, Saori Fukui, Yoichi Watanabe, Yukio Kakizaki, Kenji Morita, and Hidekazu Takekoshi

Subjects

Image stitching, Materials science, Nanolithography, Optics, business.industry, General Engineering, Reticle, Cathode ray, Wafer, Stepper, business, Lithography, Electron-beam lithography

Abstract

Electron projection lithography (EPL) is one of the promising technologies below the 65 nm node, especially for contact hole and gate layers. Nikon is developing an EPL exposure tool as an electron beam (EB) stepper and the first generation EB stepper is now being manufactured. The voltage of 100 kV is adopted for electron beam acceleration. The subfield size is 0.25 mm×0.25 mm on the wafer and the deflection width of the electron beam is 5 mm on the wafer. The magnification of the projection optics is 1/4. A 5 mm×25 mm area from the φ200 mm reticle can be exposed by the combination of beam deflection and stage scanning motion (dynamic exposure). This area is called “a mechanical stripe.” After one mechanical stripe exposure, the reticle and wafer stages turn around and the next exposure of the adjacent mechanical stripe starts as a scan and stitch stage motion. Finally, a 20 mm×25 mm exposure field from the φ200 mm reticle is exposed. We report the first dynamic exposure in the history of EPL although only a φ100 mm reticle was used. A 5 mm×10 mm area was used as the mechanical stripe and 10 mm×10 mm exposure fields were exposed. 100 nm nested lines were resolved in the entire exposure field and stitching accuracies of 17–18 nm (3σ) are obtained. There remain systematic errors, and stitching accuracy less than 15 nm will be achieved after fine adjustment of the subfield positions. We feel the reality of EPL is now sufficiently proven.

Published

2003