Biomedical Engineering Reference
In-Depth Information
The various aspects of the ALD process,
structural replication, enhancement or intro-
duction of functionalities, biocompatible coat-
ings, catalysis, and mineralization are all in a
very early stage of development. The tendency
toward multidisciplinary research will, sooner
rather than later, lead to new and fascinating
scientific insights as well as exciting new
applications.
[13] M.D. Groner, F.H. Fabreguette, J.W. Elam, and S.M.
George, Low-temperature Al
2
O
3
atomic layer deposi-
tion,
Chem Mater
16
(2004), 639-645.
[14] S.K. Kim, S.W. Lee, C.S. Hwang, Y.-S. Min, J.Y. Won,
and J. Jeong, Low temperature (<100 °C) deposition of
aluminum oxide thin films by ALD with O
3
as oxidant,
J Electrochem Soc
153
(2006), F69-F76.
[15] E. Langereis, M. Creatore, S.B.S. Heil, M.C.M. van den
Sanden, and W.M.M. Kessels, Plasma-assisted atomic
layer deposition of Al
2
O
3
moisture permeation barriers
on polymers,
Appl Phys Lett
89
(2006), 081915.
[16] M. Putkonen and L. Niinisto, Atomic layer deposition
of B
2
O
3
thin films at room temperature,
Thin Solid Films
514
(2006), 145-149.
[17] Y. Luo, D. Slater, M. Han, J. Moryl, and R.M.J. Osgood,
Low-temperature, chemically driven atomic-layer
epitaxy: in situ monitored growth of CdS/ZnSe (1 0 0),
Appl Phys Lett
71
(1997), 3799-3801.
[18] Y. Lu, S. Bangsarutip, X. Wang, L. Zhang, Y. Nishi, and
H. Dai, DNA functionalization of carbon nanotubes for
ultrathin atomic layer deposition of high k dielectrics
for nanotubes transistors with 60 mV/decade switch-
ing,
J Am Chem Soc
128
(2006), 3518-3519.
[19] G.A.T. Eyck, S. Pimanpang, H. Bakhru, T.-M. Lu, and
G.-C. Wang, Atomic layer deposition of Pd on an oxi-
dized metal substrate,
Chem Vap Deposit
12
(2006),
290-294.
[20] G.A.T. Eyck, J.J. Senkevich, F. Tang, D. Liu, S. Piman-
pang, T. Karaback, G.-C. Wang, T.-M. Lu, C. Jezewski,
and W.A. Lanford, Plasma-assisted atomic layer depo-
sition of palladium,
Chem Vap Deposit
11
(2005), 60-66.
[21] H.C.M. Knoops, A.J.M. Mackus, M.E. Donders, M.C.M.
van den Sanden, P.H.L. Notten, and W.M.M. Kessels,
Remote plasma ALD of platinum and platinum oxide
films,
Electrochem Solid-State Lett
12
(2009), G34-G36.
[22] W. Gasser, Y. Uchida, and M. Matsumura, Quasi-
monolayer deposition of silicon dioxide,
Thin Solid
Films
250
(1994), 213-218.
[23] J.W. Klaus, O. Sneh, and S.M. George, Growth of SiO
2
at room temperature with the use of catalyzed sequen-
tial half-reactions,
Science
278
(1997), 1934-1936.
[24] J.W. Elam, D.A. Baker, A.J. Hryn, A.B.F. Martinson,
M.J. Pellin, and J.T. Hupp, Atomic layer deposition of
tin oxide films using tetrakis(dimethylamino) tin,
J Vac
Sci Technol A
26
(2008), 244-252.
[25] K. Kukli, J. Aarik, A. Aidla, O. Kohan, T. Uustare, and
V. Sammelselg, Properties of tantalum oxide thin films
grown by atomic layer deposition,
Thin Solid Films
260
(1995), 135-142.
[26] S.B.S. Heil, F. Roozeboom, M.C.M. van den Sanden,
and W.M.M. Kessels, Plasma-assisted atomic layer
deposition of Ta
2
O
5
from alkylamide precursor and
remote O
2
plasma,
J Vac Sci Technol A
26
(2008),
472-480.
References
[1] S.I. Kol'tsov, Production and investigation of reaction
products of titanium tetrachloride with silica gel,
J.
Appl. Chem. USSR
42
(1969), 1023.
[2] T. Suntola and J. Antson,
Method for producing compound
thin films,
US Patent 4,058,430 (issued 25 November 1977).
[3] N. Pinna and M. Knez,
Atomic layer deposition of nano-
structured materials
, Wiley, Weinheim, Germany (2012).
[4] M. Knez, K. Nielsch, and L. Niinisto, Synthesis and
surface engineering of complex nanostructures by
atomic layer deposition,
Adv Mater
19
(2007),
3425-3438.
[5] S.M. George, Atomic layer deposition: an overview,
Chem Rev
110
(2010), 111-131.
[6] H. Kim, H.-B.-R. Lee, and W.-J. Maeng, Applications of
atomic layer deposition to nanofabrication and emerg-
ing nanodevices,
Thin Solid Films
517
(2009),
2563-2580.
[7] M. Leskelä and M. Ritala, Atomic layer deposition
chemistry: recent developments and future challenges,
Angew Chem Int Ed
42
(2003), 5548-5554.
[8] J.T. Korhonen, P. Hiekkataipale, J. Malm, M. Karp-
pinen, O. Ikkala, and R.H.A. Ras, Inorganic hollow
nanotube aerogels by atomic layer deposition onto
native nanocellulose templates,
ACS Nano
5
(2011),
1967-1974.
[9] R.L. Puurunen, Surface chemistry of atomic layer depo-
sition: a case study for the trimethylaluminum/water
process,
J Appl Phys
97
(2005), 121301-121352.
[10] H.B. Profijt, S.E. Potts, M.C.M. van de Sanden, and
W.M.M. Kessels, Plasma-assisted atomic layer deposi-
tion: basics, opportunities, and challenges,
J Vac Sci
Technol A
29
(2011), 050801.
[11] T. Yoshimura, S. Tatsuura, and W. Sotoyama, Polymer-
films formed with monolayer growth steps by molecu-
lar layer deposition,
Appl Phys Lett
59
(1991), 482-484.
[12] D.H. Levy, D. Freeman, S.F. Nelson, P.J. Cowdery-
Corvan, and L.M. Irving, Stable ZnO thin film transis-
tors by fast open air atomic layer deposition,
Appl Phys
Lett
92
(2008), 192101.
