论文信息 - Reactive ion etching of high‐aspect‐ratio 100 nm linewidth features in tungsten

Reactive ion etching of high‐aspect‐ratio 100 nm linewidth features in tungsten

The subtractive patterning of fine‐linewidth (sub‐250‐nm) tungsten absorbers for x‐ray masks requires the ability to etch features with high aspect ratios and vertical sidewalls. In this letter, a reactive‐ion‐etching process which meets these requirements is described. The etch gases used are SF6 and H2. It is further shown that an intermittent etch process, whereby the sample is vented to atmosphere in between etches results in an etch profile with vertical tungsten sidewalls. This interrupted etching is compared with the results from continuous etching. The straighter sidewalls in the case of the interrupted etch suggests a passivation of the sidewalls which occurs during the venting process. Results are presented to show etching of 100 nm gratings and 200 nm dot arrays. An in situ endpoint detection method developed for the reactive‐ion‐etching system is presented.

[1] Martin C. Peckerar,et al. Patterning tungsten films with an electron beam lithography system at 50 keV for x-ray mask applications , 1991 .

[2] L. Grella,et al. Energy density function determination in very‐high‐resolution electron‐beam lithography , 1990 .

[3] J. Frackoviak,et al. Tungsten patterning for 1:1 x‐ray masks , 1991 .

[4] Heinz H. Busta. End-Point Detection With Laser Interferometry , 1981, Advanced Lithography.

[5] J. R. Maldonado,et al. Prospects for x-ray lithography , 1992 .

[6] J. Frackoviak,et al. Stable low‐stress tungsten absorber technology for sub‐half‐micron x‐ray lithography , 1991 .

[7] I. Plotnik,et al. In situ stress monitoring and deposition of zero‐stress W for x‐ray masks , 1991 .

[8] H. Pépin,et al. X‐ray mask development based on SiC membrane and W absorber , 1992 .

[9] Mark L. Schattenburg,et al. Fabrication of 50 nm line‐and‐space x‐ray masks in thick Au using a 50 keV electron beam system , 1992 .

[10] W. M. Haynes. CRC Handbook of Chemistry and Physics , 1990 .

[11] Karen Petrillo,et al. Fabrication of high performance 512K static‐random access memories in 0.25 μm complementary metal–oxide semiconductor technology using x‐ray lithography , 1993 .