- 【Updated on May 12, 2025】 Integration of CiNii Dissertations and CiNii Books into CiNii Research
- Trial version of CiNii Research Knowledge Graph Search feature is available on CiNii Labs
- 【Updated on June 30, 2025】Suspension and deletion of data provided by Nikkei BP
- Regarding the recording of “Research Data” and “Evidence Data”
Novel Spin-on Carbon Hard Mask with Hardening by Ion Implantation
-
- Ishibashi Takeo
- Renesas Technology Corp
-
- Ono Yoshiharu
- Renesas Technology Corp
-
- Yamaguchi Atsumi
- Renesas Technology Corp
-
- Ogawa Sachiko
- Renesas Technology Corp
-
- Hanawa Tetsuro
- Renesas Technology Corp
-
- Shinohara Masaaki
- Renesas Technology Corp
-
- Tadokoro Masahiro
- Renesas Technology Corp
-
- Yonekura Kazumasa
- Renesas Technology Corp
-
- Mitani Yuko
- Renesas Semiconductor Engineering Corp
-
- Matsuda Keiko
- Toray Research Center Inc.
-
- Hirori Hideaki
- Toray Research Center Inc.
-
- Miyamoto Takashi
- Toray Research Center Inc.
-
- Matsunobu Takeshi
- Toray Research Center Inc.
Search this article
Description
In this article, we present a novel high-performance multi-layer resist (MLR) process that uses a spin-on carbon (SOC) hard mask (HM). In the process, a technique involving the implantation of ions into the SOC just after coating was employed. B, P, Ar, and As were implanted in order to compare the degrees of hardening for the same dose amount (1E+15) and equivalent mean projected range Rp (ca. 75 nm); the parameters were controlled by dose energy for each ion. The results indicated that heavier ions with high dose energy showed higher hardening efficiency. The hardening depth in the SOC film approximately corresponded to the mean projected range (Rp). These findings were consistent with the physics of ion implantation, in which elastic and inelastic collisions between ions and target atoms and electrons are considered. As a next step, we attempted to apply this process to form ultra-thin lines using the implantation of Ar ions as an inert species. We confirmed that by using this system, the fundamental lithographic performance obtained was equivalent to that obtained by using the conventional MLR system. Furthermore, excellent etching performance was obtained when the implantation was carried out at higher dose energies. Accordingly, the formation of ultra-thin lines (ca. 25 nm) was successfully achieved by tuning the hardening condition.
Journal
-
- Journal of Photopolymer Science and Technology
-
Journal of Photopolymer Science and Technology 20 (3), 365-372, 2007
The Society of Photopolymer Science and Technology(SPST)
- Tweet
Details 詳細情報について
-
- CRID
- 1390001204323763968
-
- NII Article ID
- 130004464557
- 40015602501
-
- NII Book ID
- AA11576862
-
- COI
- 1:CAS:528:DC%2BD2sXot1Wmsr4%3D
-
- ISSN
- 13496336
- 09149244
-
- NDL BIB ID
- 8918837
-
- Text Lang
- en
-
- Data Source
-
- JaLC
- NDL Search
- Crossref
- CiNii Articles
-
- Abstract License Flag
- Disallowed