Hafnium silicate (Hf1−xSixO2) films were deposited by metalorganic chemical-vapor deposition with composition x ranging from 0 to 1 using amide precursors in an organic solvent. The liquid precursors, tetrakis(diethylamido)hafnium, Hf[N(C2H5)2]4, and tetrakis(dimethylamido)silicon, Si[N(CH3)2]4, are compatible when mixed in solution, have high elemental purity, and exhibit a low halogen content. Thin oxide films were deposited with these precursors over a range of wafer temperatures from 400 to 600 °C with very low carbon and nitrogen incorporation. Control of the film composition is attained by changing the ratio of silicon concentration to hafnium concentration in the precursor solution for specific deposition conditions. Composition and growth rate are reported as a function of process condition. Interfacial layers of less than 10 Å were observed by high-resolution transmission electron microscopy.

Topics
Transmission electron microscopy, Chemical vapor deposition, Chemical elements
1.
See, for example, ITRS (1999), www.ITRS.net (2000).
2.
G. D.
Wilk
,
R. M.
Wallace
, and
J. M.
Anthony
,
J. Appl. Phys.
89
,
5243
(
2001
).
Google Scholar
 
3.
A. I.
Kingon
,
J.-P.
Maria
,
S. K.
Streiffer
,
Nature (London)
406
,
1032
(
2000
);
Google Scholar
 
D. A.
Neumayer
, and
E.
Cartier
,
J. Appl. Phys.
90
,
1801
(
2001
).
Google Scholar
 
4.
L.
Manchandra
,
M. L.
Green
,
R. B. van
Dover
,
M. D.
Morris
,
A.
Kerber
,
Y.
Hu
,
J.-P.
Han
,
P. J.
Silverman
,
T. W.
Sorsch
,
G.
Weber
,
V.
Donnelly
,
K.
Pelhos
,
F.
Klemens
,
N. A.
Ciampa
,
A.
Kornblit
,
Y. O.
Kim
,
J. E.
Bower
,
D.
Barr
,
E.
Ferry
,
D.
Jabobson
,
J.
Eng
,
B.
Busch
, and
H.
Schulte
,
Tech. Dig. Int. Electron Devices Meet.
,
23
(
2000
).
5.
G. D.
Wilk
,
R. M.
Wallace
, and
J. M.
Anthony
,
J. Appl. Phys.
87
,
484
(
2000
).
Google Scholar
 
6.
G.
Rayner
,
R.
Therrien
, and
G.
Lukovsky
,
Mater. Res. Soc. Symp. Proc.
611
,
C1
.
3
(
2000
).
Google Scholar
 
7.
W.-J.
Qi
,
R.
Nieh
,
E.
Dharmarajan
,
B. H.
Lee
,
Y.
Jeon
,
L.
Kang
,
K.
Onishi
, and
J. C.
Lee
,
Appl. Phys. Lett.
77
,
1704
(
2000
).
Google Scholar
 
8.
J. F.
Roeder
,
T. H.
Baum
,
S. M.
Bilodeau
,
G. T.
Stauf
,
C.
Ragaglia
,
M. W.
Russell
, and
P. C. Van
Buskirk
,
Adv. Mater. Opt. Electron.
10
,
145
(
2000
).
Google Scholar
 
9.
R. C.
Smith
,
C. J.
Taylor
,
J.
Roberts
,
N.
Hoilien
,
S. A.
Campbell
, and
W. L.
Gladfelter
,
Mater. Res. Soc. Symp. Proc.
611
,
C2
.
8
(
2000
).
Google Scholar
 
10.
C. H.
Lee
,
H. F.
Luan
,
W. P.
Bai
,
S. J.
Lee
,
T. S.
Jeon
,
Y.
Senzaki
,
D.
Roberts
, and
D. L.
Kwong
,
Tech. Dig. Int. Electron Devices Meet.
,
27
(
2000
).
11.
D. M.
Wolfe
,
K.
Flock
,
R.
Therrien
,
R.
Johnson
,
B.
Rayner
,
L.
Gunther
,
N.
Brown
,
B.
Claflin
, and
G.
Lukovsky
,
Mater. Res. Soc. Symp. Proc.
567
,
343
(
1999
).
Google Scholar
 
12.
R. G.
Gordon
,
J.
Becker
,
D.
Hausmann
, and
S.
Suh
,
Chem. Mater.
13
,
2463
(
2001
).
Google Scholar
 
13.
T.
Maruyama
 and
T.
Shirai
,
Appl. Phys. Lett.
63
,
611
(
1993
);
Google Scholar
 
L. M.
Atagi
,
D. M.
Hoffman
,
J.-R.
Liu
,
Z.
Zheng
, and
W.-K.
Chu
,
Chem. Mater.
6
,
360
(
1994
).
Google Scholar
 
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2002
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