Comparison of Cl 2 and F-based dry etching for high aspect ratio Si microstructures etched with an inductively coupled plasma source
The differences between Cl 2 and F-based dry etching are compared in this article. Inductively coupled plasma sources have been used to generate plasmas using both Cl 2 and SF 6 /C 4 F 8 chemistries. Trenches etched using Cl 2 suffered less aspect ratio dependent etching effects because the trenches...
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Veröffentlicht in: | Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures 2000-07, Vol.18 (4), p.1890-1896 |
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Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | The differences between
Cl
2
and F-based dry etching are compared in this article. Inductively coupled plasma sources have been used to generate plasmas using both
Cl
2
and
SF
6
/C
4
F
8
chemistries. Trenches etched using
Cl
2
suffered less aspect ratio dependent etching effects because the trenches can be etched at a much lower pressure than with F-based gases. A
1.4 μ
m
wide,
65 μ
m
deep trench can be obtained with an aspect ratio of 46 in 12 h. The average Si etch rate was 90 nm/min and the selectivity to electroplated Ni was 23. The sidewall was vertical and smooth and the trench openings were nearly the same width before and after etching. Adjacent trenches with
0.14 μ
m
mask opening and
2 μ
m
line width were etched using these two etching technologies. With
Cl
2
etching, a wider
0.25 μ
m
trench opening, due to the mask erosion effect, with a depth of
5.6 μ
m
was obtained in 50 min. However, the
0.33 μ
m
undercut increased the trench opening to
0.8 μ
m
for
10.7 μ
m
deep trenches after the F-based etching for 55 min. The Si etch rate in a large open area using F-based etching was 1818 nm/min, which is much faster than 201 nm/min when
Cl
2
etching was used. However, the Si etch rate, 112 nm/min for
Cl
2
and 195 nm/min for F-based gases, was similar when the trench opening was decreased to submicrometer dimensions. This shows that the
Cl
2
etching provides better dimension and profile control with comparable Si etch rate to F-based etching when etching submicrometer trenches. The loading effect using
Cl
2
chemistry is less than with F-based etching. The Si etch rate was
1.74 μ
m/min
for
∼100%
Si exposed area and
3.68 μ
m/min
when the exposed Si area was
∼0%
in F-based etching. Scalloping, which is a periodic undercut near the top of the sidewalls, disappeared when using an electroplated Ni mask. The size and period of the scalloped features decreased as the Si exposed area and etch time increased. |
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ISSN: | 0734-211X 1520-8567 |
DOI: | 10.1116/1.1306303 |