Bibliography

1

C. Albonetti, J. Martínez, N. S. Losilla, P. Greco, M. Cavallini, F. Borgatti, M. Montecchi, L. Pasquali, R. García, and F. Biscarini.
Parallel-local anodic oxidation of silicon surfaces by soft stamps.
Nanotechnology, 19(43):435303(9), 2008.

2

W. Arden, M. Brillouet, P. Cogez, P. Graef, B. Huizing, and R. Mahnkopf.
More-than-Moore white paper.
Technical report, International Technical Roadmap for Semiconductors, 2010.
http://www.itrs.net/Links/2010ITRS/IRC-ITRS-MtM-v2%203.pdf.

3

T. K. Asuha, O. Maida, M. Inoue, M. Takahashi, Y. Todokoro, and H. Kobayashi.
Ultrathin silicon dioxide layers with a low leakage current density formed by chemical oxidation of Si.
Applied Physics Letters, 81(18):3410-3412, 2002.

4

P. Avouris, T. Hertel, and R. Martel.
Atomic force microscope tip-induced local oxidation of silicon: kinetics, mechanism, and nanofabrication.
Applied Physics Letters, 71(2):285-287, 1997.

5

P. Avouris, Y. Lin, F. Xia, T. Mueller, D. Farmer, C. Dimitrakopoulos, and A. Grill.
Graphene-based fast electronics and optoelectronics.
In Device Research Conference (DRC), pages 205-206, 2010.

6

P. Avouris, R. Martel, T. Hertel, and R. Sandstrom.
AFM-tip-induced and current-induced local oxidation of silicon and metals.
Applied Physics A: Materials Science & Processing, 66(1):S659-S667, 1998.

7

C. Bai.
Scanning tunneling microscopy and its application.
Scientific and Technical Publishers, 1995.

8

A. Bardea and R. Naaman.
Magnetolithography: From the bottom-up route to high throughput.
Advances in Imaging and Electron Physics, 164:1-27, 2010.

9

D. Beckel, A. Dubach, A. Studart, and L. Gauckler.
Spray pyrolysis of La$_{0.6}$ Sr$_{0.4}$ Co$_{0.2}$ Fe$_{0.8}$ O $_{3-\delta}$ thin film cathodes.
Journal of Electroceramics, 16(3):221-228, 2006.

10

R. J. Belen, S. Gomez, D. Cooperberg, M. Kiehlbauch, and E. S. Aydil.
Feature-scale model of Si etching in SF$_{6}$/O$_{2}$ plasma and comparison with experiments.
Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, 23(2):1430-1439, 2005.

11

R. J. Belen, S. Gomez, M. Kiehlbauch, and E. S. Aydil.
Feature scale model of Si etching in SF$_6$/O$_2$/HBr plasma and comparison with experiments.
Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, 24(2):350-361, 2006.

12

G. Binnig, C. F. Quate, and C. Gerber.
Atomic force microscope.
Physical Review Letters, 56(9):930-933, 1986.

13

G. Binnig and H. Rohrer.
EU patent number 0027517: Scanning apparatus for surface analysis using vacuum-tunnel effect at cryogenic temperatures. (issued 29 April 1981).

14

G. Binnig and H. Rohrer.
Scanning tunneling microscopy.
Surface Science, 126(1-3):236-244, 1983.

15

G. Binnig and H. Rohrer.
Scanning tunneling microscopy - from birth to adolescence (Nobel lecture).
Angewandte Chemie International Edition in English, 26(7):606-614, 1987.

16

G. Binnig, H. Rohrer, C. Gerber, and E. Weibel.
Surface studies by scanning tunneling microscopy.
Physical Review Letters, 49(1):57-61, 1982.

17

G. Binnig, H. Rohrer, C. Gerber, and E. Weibel.
7x7 Reconstruction on Si(111) resolved in real space.
Physical Review Letters, 50(2):120-123, 1983.

18

J. Bjorkholm.
Euv lithography - the successor to optical lithography.
Intel Technology Journal, 3:98, 1998.
http://download.intel.com/technology/itj/q31998/pdf/euv.pdf.

19

G. Blandenet, M. Court, and Y. Lagarde.
Thin layers deposited by the pyrosol process.
Thin Solid Films, 77(1-3):81-90, 1981.

20

A. Bongiorno and A. Pasquarello.
Atomic-scale modelling of kinetic processes occurring during silicon oxidation.
Journal of Physics: Condensed Matter, 17(21):S2051-S2063, 2005.

21

O. Buiu, G. Kennedy, M. Gartner, and S. Taylor.
Structural analysis of silicon dioxide and silicon oxynitride films produced using an oxygen plasma.
IEEE Transactions on Plasma Science, 26(6):1700-1712, 1998.

22

D. A. P. Bulla and N. I. Morimoto.
Deposition of thick TEOS PECVD silicon oxide layers for integrated optical waveguide applications.
Thin Solid Films, 334(1-2):60-64, 1998.

23

D. Bullen and C. Liu.
Electrostatically actuated dip pen nanolithography probe arrays.
Sensors and Actuators A: Physical, 125(2):504-511, 2006.

24

J. H. Burnett, S. G. Kaplan, E. L. Shirley, P. J. Tompkins, and J. E. Webb.
High-index materials for 193 nm immersion lithography.
In Proceedings of SPIE 5754, Optical Microlithography XVIII, pages 611-621, 2005.

25

M. Burzo, P. Komarov, and P. Raad.
Thermal transport properties of gold-covered thin-film silicon dioxide.
IEEE Transactions on Components and Packaging Technologies, 26(1):80-88, 2003.

26

N. Cabrera and N. F. Mott.
Theory of the oxidation of metals.
Reports on Progress in Physics, 12:163-184, 1949.

27

T. S. Cale and G. B. Raupp.
A unified line-of-sight model of deposition in rectangular trenches.
Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures, 8(6):1242-1248, 1990.

28

M. Calleja and R. García.
Nano-oxidation of silicon surfaces by noncontact atomic-force microscopy: size dependence on voltage and pulse duration.
Applied Physics Letters, 76(23):3427-3429, 2000.

29

R. R. Chamberlin and J. S. Skarman.
Chemical spray deposition process for inorganic films.
Journal of the Electrochemical Society, 113(1):86-89, 1966.

30

S. Y. Chou, P. R. Krauss, and P. J. Renstrom.
Imprint lithography with 25-nanometer resolution.
Science, 272(5258):85-87, 1996.

31

S. Y. Chou, P. R. Krauss, and P. J. Renstrom.
Nanoimprint lithography.
Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures, 14(6):4129-4133, 1996.

32

K. Choy and B. Su.
Growth behavior and microstructure of CdS thin films deposited by an electrostatic spray assisted vapor deposition (ESAVD) process.
Thin Solid Films, 388(1-2):9-14, 2001.

33

M.-C. Chuang and J. W. Coburn.
Molecular-beam study of gas-surface chemistry in the ion-assisted etching of silicon with atomic and molecular hydrogen and chlorine.
Journal of Vacuum Science & Technology, 8(3):1969-1976, 1990.

34

C. R. Cleavelin, S. Pas, E. M. Vogel, and J. J. Wortman.
Oxidation, chapter 7, pages 163-183.
Marcel Dekker Inc., 2000.

35

J.-P. Colinge, C.-W. Lee, A. Afzalian, N. D. Akhavan, R. Yan, I. Ferain, P. Razavi, B. O'Neill, A. Blake, M. White, A.-M. Kelleher, B. McCarthy, and R. Murphy.
Nanowire transistors without junctions.
Nature Nanotechnology, 5(3):225-229, 2010.

36

E. B. Cooper, S. R. Manalis, H. Fang, H. Dai, K. Matsumoto, S. C. Minne, T. Hunt, and C. F. Quate.
Terabit-per-square-inch data storage with the atomic force microscope.
Applied Physics Letters, 75(22):3566-3568, 1999.

37

H. Cui, Y. Sun, G. Z. Yang, G. W. Yang, and C. X. Wang.
Size-dependent oxidation behavior for the anomalous initial thermal oxidation process of Si.
Applied Physics Letters, 94(8):083108-083108-3, 2009.

38

J. Dagata, J. Schneir, H. Harary, C. Evans, M. Postek, and J. Bennett.
Modification of hydrogen-passivated silicon by a scanning tunneling microscope operating in air.
Applied Physics Letters, 56(20):2001-2003, 1990.

39

J. A. Dagata, F. Perez-Murano, G. Abadal, K. Morimoto, T. Inoue, J. Itoh, and H. Yokoyama.
Predictive model for scanned probe oxidation kinetics.
Applied Physics Letters, 76(19):2710-2712, 2000.

40

H. C. Day and D. R. Allee.
Selective area oxidation of silicon with a scanning force microscope.
Applied Physics Letters, 62(21):2691-2693, 1993.

41

R. M. C. de Almeida, S. Gonçalves, I. J. R. Baumvol, and F. C. Stedile.
Dynamics of thermal growth of silicon oxide films on Si.
Physical Review B, 61(19):12992-12999, 2000.

42

B. E. Deal and A. S. Grove.
General relationship for the thermal oxidation of silicon.
Journal of Applied Physics, 36(12):3770-3778, 1965.

43

A. A. Dehzangi, A. A. M. Abdullah, F. F. Larki, S. S. D. Hutagalung, E. E. B. Saion, M. M. N. Hamidon, J. J. Hassan, and Y. Y. Gharayebi.
Electrical property comparison and charge transmission in p-type double gate and single gate junctionless accumulation transistor fabricated by AFM nanolithography.
Nanoscale Research letters, 7(1):381, 2012.

44

M. Despont, J. Brugger, U. Drechsler, U. Dürig, W. Häberle, M. Lutwyche, H. Rothuizen, R. Stutz, R. Widmer, G. Binnig, H. Rohrer, and P. Vettiger.
VLSI-NEMS chip for parallel AFM data storage.
Sensors and Actuators A: Physical, 80(2):100-107, 2000.

45

S. Djurkovic, C. Clemons, D. Golovaty, and G. Young.
Effects of the electric field shape on nano-scale oxidation.
Surface Science, 601(23):5340-5358, 2007.

46

E. Dubois and J.-L. Bubbendorff.
Nanometer scale lithography on silicon, titanium and PMMA resist using scanning probe microscopy.
Solid-State Electronics, 43(6):1085-1089, 1999.

47

B. El-Kareh.
Fundamentals of Semiconductor Processing Technologies.
Kluwer Academic Publishers, 1995.

48

J.-J. Eltgen.
US patent number 5644987: Process and apparatus for printing using a magnetic toner which is electrostatically charged. (issued 08 August 1997).

49

B. Engquist and S. Osher.
Stable and entropy satisfying approximations for transonic flow calculations.
Mathematics of Computation, 34(149):45-75, 1980.

50

O. Ertl.
Numerical Methods for Topography Simulation.
Dissertation, Technischen Universität Wien, Fakultät für Elektrotechnik und Informationstechnik, 2010.
http://www.iue.tuwien.ac.at/phd/ertl/.

51

O. Ertl and S. Selberherr.
A fast level set framework for large three-dimensional topography simulations.
Computer Physics Communications, 180(8):1242-1250, 2009.

52

F.-R. F. Fan and A. J. Bard.
Electrochemical detection of single molecules.
Science, 267(5199):871-874, 1995.

53

T.-H. Fang.
Mechanisms of nanooxidation of Si(100) from atomic force microscopy.
Microelectronics Journal, 35(9):701-707, 2004.

54

P. Fay, R. T. Brockenbrough, G. Abeln, P. Scott, S. Agarwala, I. Adesida, and J. W. Lyding.
Scanning tunneling microscope stimulated oxidation of silicon (100) surfaces.
Journal of Applied Physics, 75(11):7545-7549, 1994.

55

P. A. Fontaine, E. Dubois, and D. Stievenard.
Characterization of scanning tunneling microscopy and atomic force microscopy-based techniques for nanolithography on hydrogen-passivated silicon.
Journal of Applied Physics, 84(4):1776-1781, 1998.

56

R. Gallage, A. Matsuo, T. Watanabe, N. Matsushita, and M. Yoshimura.
Fabrication of transparent ceria films by spray deposition without post firing.
Journal of Electroceramics, 22(1):33-39, 2009.

57

Y. Gan, H. Wong, and W. Lee.
A novel atomic force microscopy based lithography system for automated patterning via anodic oxidation.
Composites Part B: Engineering, 42(3):456-461, 2011.

58

A. Ganán-Calvo, J. Lasheras, J. Dávila, and A. Barrero.
The electrostatic spray emitted from an electrified conical meniscus.
Journal of Aerosol Science, 25(6):1121-1142, 1994.

59

R. García.
Keynote speech: Bridging nano and macro worlds with water miniscii: attomol chemistry and nanofabrication by local oxidation nanolithography.
LITHO, 2004.
http://www.imm.cnm.csic.es/spm/Articulos/Garcia_Litho2004.pdf.

60

R. García, M. Calleja, and F. Perez-Murano.
Local oxidation of silicon surfaces by dynamic force microscopy: Nanofabrication and water bridge formation.
Applied Physics Letters, 72(18):2295 -2297, 1998.

61

R. García, R. V. Martínez, and J. Martínez.
Nano-chemistry and scanning probe nanolithographies.
Chemical Society Review, 35(1):29-38, 2006.

62

A. García-Martin and R. García.
Formation of nanoscale liquid menisci in electric fields.
Applied Physics Letters, 88(12):123115-123115-3, 2006.

63

U. Gasser, M. Sigrist, S. Gustavsson, K. Ensslin, and T. Ihn.
Tip-Based Nanofabrication: Fundamentals and Applications, chapter 3: Double Layer Local Anodic Oxidation Using Atomic Force Microscopy, pages 91-128.
Springer, 1st edition, 2011.

64

M. Giorgio, B. Elise, K. Anton, and S. Steinhauer.
Private communication with members of the molecular diagnostics, health and environment group at the Austrian Institute of Technology (AIT)., 2012.

65

A. E. Gordon, R. T. Fayfield, D. D. Litfin, and T. K. Higman.
Mechanisms of surface anodization produced by scanning probe microscopes.
Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures, 13(6):2805-2808, 1995.

66

S. Gottlieb and C. W. Shu.
Total variation diminishing Runge-Kutta schemes.
Mathematics of Computation, 67(221):73-85, 1998.

67

L. Gross, F. Mohn, N. Moll, B. Schuler, A. Criado, E. Guitián, D. Peña, A. Gourdon, and G. Meyer.
Bond-order discrimination by atomic force microscopy.
Science, 337(6100):1326-1329, 2012.

68

R. Guckenberger, M. Heim, G. Cevc, H. F. Knapp, W. Wiegrabe, and A. Hillebrand.
Scanning tunneling microscopy of insulators and biological specimens based on lateral conductivity of ultrathin water films.
Science, 266(5190):1538-1540, 1994.

69

L. J. Guo.
Recent progress in nanoimprint technology and its applications.
Journal of Physics D: Applied Physics, 37(11):R123-R141, 2004.

70

B. Haavind and J. Montgomery.
SPIE: AMD, IBM tip first "full field" EUV chip.
Solid State Technology: Insights for Electronics Manufacturing, 2008.
http://www.electroiq.com/articles/mlw/2008/02/spie-amd-ibm-tip-first-full-field-euv-chip.html.

71

H. F. Hamann, M. O'Boyle, Y. C. Martin, M. Rooks, and H. K. Wickramasinghe.
Ultra-high-density phase-change storage and memory.
Nature Materials, 5(5):383-387, 2006.

72

E. Harari.
Plenary: Flash memory - the great disruptor!
In IEEE International Solid-State Circuits Conference (ISSCC) Digest of Technical Papers, pages 10-15, 2012.

73

T. Hattori, Y. Ejiri, K. Saito, and M. Yasutake.
Fabrication of nanometer-scale structures using atomic force microscope with conducting probe.
Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, 12(4):2586-2590, 1994.

74

R. Hayes, N. Borisenko, M. K. Tam, P. C. Howlett, F. Endres, and R. Atkin.
Double layer structure of ionic liquids at the Au(111) electrode interface: an atomic force microscopy investigation.
The Journal of Physical Chemistry C, 115(14):6855-6863, 2011.

75

A. Hemeryck, N. Richard, A. Estève, and M. D. Rouhani.
Diffusion of oxygen atom in the topmost layer of the Si(100) surface: Structures and oxidation kinetics.
Surface Science, 601(11):2339-2343, 2007.

76

C. D. Hendricks Jr.
Charged droplet experiments.
Journal of Colloid Science, 17(3):249-259, 1962.

77

M. D. Henry.
ICP Etching of silicon for micro and nanoscale devices.
Ph.d. dissertation, California Institute of Technology, 2010.
http://thesis.library.caltech.edu/5846/2/MDH-Thesis-Rev1.pdf.

78

D. W. Hess.
Plasma-assisted oxidation, anodization, and nitridation of silicon.
IBM Journal of Research and Development, 43(1.2):127-145, 1999.

79

Y. Hirai, S. Yoshida, and N. Takagi.
Defect analysis in thermal nanoimprint lithography.
Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures, 21(6):2765-2770, 2003.

80

C. Hollauer.
Modeling of Thermal Oxidation and Stress Effects.
Dissertation, Technischen Universität Wien, Fakultät für Elektrotechnik und Informationstechnik, 2007.
http://www.iue.tuwien.ac.at/phd/hollauer/.

81

H. Holterman.
Kinetics and Evaporation of Water Drops in Air.
IMAG, Wageningen (Netherlands), 2003.

82

S. Hong and C. A. Mirkin.
A nanoplotter with both parallel and serial writing capabilities.
Science, 288(5472):1808-1811, 2000.

83

B. Houston, M. B. Nielsen, C. Batty, O. Nilsson, and K. Museth.
Hierarchical RLE level set: A compact and versatile deformable surface representation.
ACM Transactions on Graphics, 25(1):151-175, 2006.

84

J. Huang, C.-L. Tsai, and A. A. Tseng.
The influence of the bias type, doping condition and pattern geometry on AFM tip-induced local oxidation.
Journal of the Chinese Institute of Engineers, 33(1):55-61, 2010.

85

S. Hutagalung and K. Lew.
Electrical characteristics of silicon nanowire transistor fabricated by AFM lithography.
In IEEE International Conference on Semiconductor Electronics (ICSE), pages 358-362, 2010.

86

T. Ichikawa, D. Ichinose, K. Kawabata, and N. Tamaoki.
Topography simulation of BiCS memory hole etching modeled by elementary experiments of SiO$_2$ and Si etching.
In International Conference on Simulation of Semiconductor Processes and Devices (SISPAD), pages 45-48, 2010.

87

N. Ikarashi, K. Watanabe, and Y. Miyamoto.
High-resolution transmission electron microscopy of an atomic structure at a Si(001) oxidation front.
Physical Review B, 62(23):15989-15995, 2000.

88

S. Imai, M. Takahashi, and H. K. Asuha.
Nitric acid oxidation of silicon at $\sim$120$^o$C to form 3.5-nm SiO$_2$/Si structure with good electrical characteristics.
Applied Physics Letters, 85(17):3783-3785, 2004.

89

S. Imai, M. Takahashi B., K. Matsuba B., Asuha B., Y. Ishikawa B., and H. Kobayashi B.
Formation and electrical characteristics of silicon dioxide layers by use of nitric acid oxidation method.
Acta Physica Slovaca, 55(3):305-313, 2005.

90

K. Imamura, O. Maida, K. Hattori, M. Takahashi, and H. Kobayashi.
Low temperature formation of SiO$_2$/Si structure by nitric acid vapor.
Journal of Applied Physics, 100(11):114910-114910-4, 2006.

91

Institute for Microelectronics, Technischen Universität Wien: PROMIS.
http://www.iue.tuwien.ac.at/index.php?id=promis.

92

A. M. Ionescu.
Electronic devices: Nanowire transistors made easy.
Nature Nanotechnology, 5(3):178-179, 2010.

93

I. Ionica, L. Montès, S. Ferraton, J. Zimmermann, L. Saminadayar, and V. Bouchiat.
Field effect and coulomb blockade in silicon on insulator nanostructures fabricated by atomic force microscope.
Solid-State Electronics, 49(9):1497-1503, 2005.

94

J. Jang, H.-S. Kim, W. Cho, H. Cho, J. Kim, S. I. Shim, Y. Jang, J.-H. Jeong, B.-K. Son, D. W. Kim, Kihyun, J.-J. Shim, J. S. Lim, K.-H. Kim, S. Y. Yi, J.-Y. Lim, D. Chung, H.-C. Moon, S. Hwang, J.-W. Lee, Y.-H. Son, U.-I. Chung, and W.-S. Lee.
Vertical cell array using TCAT (Terabit Cell Array Transistor) technology for ultra high density NAND flash memory.
In 2009 Symposium on VLSI Technology, pages 192-193, 2009.

95

M. Johannes, D. Cole, and R. Clark.
Three-dimensional design and replication of silicon oxide nanostructures using an atomic force microscope.
Nanotechnology, 18(34):345304-7, 2007.

96

A. R. Jones and K. C. Thong.
The production of charged monodisperse fuel droplets by electrical dispersion.
Journal of Physics D: Applied Physics, 4(8):1159-1168, 1971.

97

R. Katsumata, M. Kito, Y. Fukuzumi, M. Kido, H. Tanaka, Y. Komori, M. Ishiduki, J. Matsunami, T. Fujiwara, Y. Nagata, L. Zhang, Y. Iwata, R. Kirisawa, H. Aochi, and A. Nitayama.
Pipe-shaped BiCS flash memory with 16 stacked layers and multi-level-cell operation for ultra high density storage devices.
In Proceedings of the 2009 Symposium on VLSI Technology, pages 136-137, 2009.

98

L. E. Katz and L. C. Kimerling.
Defect formation during high pressure, low temperature steam oxidation of silicon.
Journal of the Electrochemical Society, 125(10):1680-1683, 1978.

99

A. J. Kelly.
Charge injection electrostatic atomizer modeling.
Aerosol Science and Technology, 12(3):526-537, 1990.

100

J. Kim, A. Hong, S. M. Kim, E. Song, J. H. Park, J. Han, S. Choi, D. Jang, J. T. Moon, and K. Wang.
Novel vertical-stacked-array-transistor (VSAT) for ultra-high-density and cost-effective NAND flash memory devices and SSD (solid state drive).
In Proceedings of the 2009 Symposium on VLSI Technology, pages 186-187, 2009.

101

J. Kim, A. J. Hong, S. M. Kim, K.-S. Shin, E. B. Song, Y. Hwang, F. Xiu, K. Galatsis, C. O. Chui, R. N. Candler, S. Choi, J.-T. Moon, and K. L. Wang.
A stacked memory device on logic 3D technology for ultra-high-density data storage.
Nanotechnology, 22(25):254006-7, 2011.

102

W. Kim, S. Choi, J. Sung, T. Lee, C. Park, H. Ko, J. Jung, I. Yoo, and Y. Park.
Multi-layered vertical gate NAND flash overcoming stacking limit for terabit density storage.
In Proceedings of the 2009 Symposium on VLSI Technology, pages 188-189, 2009.

103

H. Kobayashi, K. Imamura, W.-B. Kim, S.-S. Im, and Asuha.
Nitric acid oxidation of Si (NAOS) method for low temperature fabrication of SiO$_2$/Si and SiO$_2$/SiC structures.
Applied Surface Science, 256(19):5744-5756, 2010.

104

H. Kobayashi, T. Matsumoto, and S. Imai.
Nitric acid oxidation method to form a gate oxide layer in sub-micrometer TFT.
ECS Meeting Abstracts, 22(4), 2011.

105

H. Kobayashi Asuha, O. Maida, M. Takahashi, and H. Iwasa.
Nitric acid oxidation of Si to form ultrathin silicon dioxide layers with a low leakage current density.
Journal of Applied Physics, 94(11):7328-7335, 2003.

106

H. Koo, S. Hong, S. Ju, I. Seo, and Y. Kang.
PbO-B$_2$O$_3$-SiO$_2$ glass powders with spherical shape prepared by spray pyrolysis.
Journal of Non-Crystalline Solids, 352(30-31):3270-3274, 2006.

107

G. Korotcenkov, V. Brinzari, J. Schwank, M. DiBattista, and A. Vasiliev.
Peculiarities of SnO$_2$ thin film deposition by spray pyrolysis for gas sensor application.
Sensors and Actuators B: Chemical, 77(1-2):244-252, 2001.

108

N. Kramer, J. Jorritsma, H. Birk, and C. Schonenberger.
Nanometer lithography on silicon and hydrogenated amorphous silicon with low energy electrons.
Journal of Vacuum Science & and Technology B: Microelectronics and Nanometer Structures, 13(3):805-811, 1995.

109

N. Kramer, M. van den Berg, and C. Schoenenberger.
Scanning tunnelling microscope-induced oxidation of hydrogen passivated silicon surfaces.
Thin Solid Films, 281-282(0):637-639, 1996.

110

C. Krzeminski, G. Larrieu, J. Penaud, E. Lampin, and E. Dubois.
Silicon dry oxidation kinetics at low temperature in the nanometric range: Modeling and experiment.
Journal of Applied Physics, 101(6):064908-8, 2011.

111

Y. Kubota.
Submicrometer ultralow-power TFT with 1.8 nm NAOS SiO$_2$/20nm CVD SiO$_2$ gate stack structure.
IEEE Transactions on Electron Devices, 58(4):1134-1140, 2011.

112

Y. Kubota, T. Matsumoto, H. Tsuji, N. Suzuki, S. Imai, and H. Kobayashi.
1.5-V-operation ultralow power circuit of Poly-Si TFTs fabricated using the NAOS method.
IEEE Transactions on Electron Devices, 59(2):385-392, 2012.

113

A. La Magna and G. Garozzo.
Factors affecting profile evolution in plasma etching of SiO$_2$ modeling and experimental verification.
Journal of The Electrochemical Society, 150(10):F178-F185, 2003.

114

A. La Storia, D. Ercolini, F. Marinello, R. D. Pasqua, F. Villani, and G. Mauriello.
Atomic force microscopy analysis shows surface structure changes in carvacrol-treated bacterial cells.
Research in Microbiology, 162(2):164-172, 2011.

115

S. Lai.
Non-volatile memory technologies: The quest for ever lower cost.
In Proceedings of the IEEE International Electron Devices Meeting (IEDM), pages 1-6, 2008.

116

T. Lane.
Atomic force microscopy.
Journal of the Advanced Undergraduate Physics Laboratory Investigation, pages 1-6, 2012.
http://opus.ipfw.edu/jaupli/vol0/iss0/2.

117

F. Larki, S. D. Hutagalung, A. Dehzangi, E. B. Saion, A. Abedini, A. M. Abdullah, M. N. Hamidon, and J. Hassan.
Electronic transport properties of junctionless lateral gate silicon nanowire transistor fabricated by atomic force microscope nanolithography.
Microelectronics and Solid State Electronics, 1:15-20, 2012.

118

C. Larriba-Andaluz and J. F. de la Mora.
Electrospraying insulating liquids via charged nanodrop injection from the taylor cone of an ionic liquid.
Physics of Fluids, 22(7):072002-7, 2010.

119

A. Lefebvre.
Atomization and sprays.
Hemisphere Publishing Corporation, 1989.

120

B. Legrand and D. Stievenard.
Nanooxidation of silicon with an atomic force microscope: A pulsed voltage technique.
Applied Physics Letters, 74(26):4049-4051, 1999.

121

I. W. Lenggoro.
An experimental and modeling investigation of particle production by spray pyrolysis using a laminar flow aerosol reactor.
Journal of Materials Research, 15(3):733-743, 2000.

122

E. A. Lewis and E. A. Irene.
The effect of surface orientation on silicon oxidation kinetics.
Journal of the Electrochemical Society, 134(9):2332-2339, 1987.

123

L. Ley, T. Teuschler, K. Mahr, S. Miyazaki, and M. Hundhausen.
Kinetics of field-induced oxidation of hydrogen-terminated si (111).
Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures, 14(4):2845-2849, 1996.

124

L. N. Lie, R. R. Razouk, and B. E. Deal.
Selective oxidation of silicon in high pressure steam.
Journal of the Electrochemical Society, 125(11):1824-1829, 1981.

125

L. N. Lie, R. R. Razouk, and B. E. Deal.
High pressure oxidation of silicon in dry oxygen.
Journal of the Electrochemical Society, 129(12):2828-2834, 1982.

126

J. R. Ligenza.
Effect of crystal orientation on oxidation rates of silicon in high pressure steam.
The Journal of Physical Chemistry, 65(11):2011-2014, 1961.

127

J. E. Lilienfeld.
US patent number 1745175: Method and apparatus for controlling electric current. (issued 28 January 1930).

128

J. E. Lilienfeld.
US patent number 1900018: Device for controlling electric current. (issued 07 March 1933).

129

N. S. Losilla, J. Martínez, and R. García.
Large area nanoscale patterning of silicon surfaces by parallel local oxidation.
Nanotechnology, 20(47):475304-5, 2009.

130

C.-Y. Lu, H. T. Lue, and Y. C. Chen.
State-of-the-art flash memory devices and post-flash emerging memories.
Science China Information Sciences, 54(5):1039-1060, 2011.

131

C.-Y. Lu and J. Sung.
Reverse short-channel effects on threshold voltage in submicrometer salicide devices.
IEEE Electron Device Letters, 10(10):446-448, 1989.

132

A. Ludsteck, J. Schulze, I. Eisele, W. Dietl, and Z. Nenyei.
Growth model for thin oxides and oxide optimization.
Journal of Applied Physics, 95(5):2827-2831, 2004.

133

M. Luna, J. Colchero, and A. M. Baro.
Intermittent contact scanning force microscopy: The role of the liquid necks.
Applied Physics Letters, 72(26):3461-3463, 1998.

134

J. Lyding.
UHV STM nanofabrication: progress, technology spin-offs, and challenges.
Proceedings of the IEEE, 85(4):589-600, 1997.

135

S. F. Lyuksyutov, P. B. Paramonov, I. Dolog, and R. M. Ralich.
Peculiarities of an anomalous electronic current during atomic force microscopy assisted nanolithography on n-type silicon.
Nanotechnology, 14(7):716-721, 2003.

136

W. Ma, C. Yang, X. Gong, K. Lee, and A. Heeger.
Thermally stable, efficient polymer solar cells with nanoscale control of the interpenetrating network morphology.
Advanced Functional Materials, 15(10):1617-1622, 2005.

137

S. Major, A. Banerjee, and K. Chopra.
Highly transparent and conducting indium-doped zinc oxide films by spray pyrolysis.
Thin Solid Films, 108(3):333-340, 1983.

138

J. Manifacier, J. Fillard, and J. Bind.
Deposition of In2O3-SnO2 layers on glass substrates using a spraying method.
Thin Solid Films, 77(1-3):67 - 80, 1981.

139

G. Marsaglia and T. A. Bray.
A convenient method for generating normal variables.
Society for Industrial and Applied Mathematics (SIAM) Review, 6(3):260-264, 1964.

140

R. V. Martínez, N. S. Losilla, J. Martínez, Y. Huttel, and R. García.
Patterning polymeric structures with 2 nm resolution at 3 nm half pitch in ambient conditions.
Nano Letters, 7(7):1846-1850, 2007.

141

R. V. Martínez, J. Martínez, and R. García.
Silicon nanowire circuits fabricated by AFM oxidation nanolithography.
Nanotechnology, 21(24):245301-5, 2010.

142

H. Z. Massoud and J. D. Plummer.
Analytical relationship for the oxidation of silicon in dry oxygen in the thin-film regime.
Journal of Applied Physics, 62(8):3416-3423, 1987.

143

H. Z. Massoud, J. D. Plummer, and E. A. Irene.
Thermal oxidation of silicon in dry oxygen: Accurate determination of the kinetic rate constants.
Journal of The Electrochemical Society, 132(7):1745-1757, 1985.

144

H. Z. Massoud, J. D. Plummer, and E. A. Irene.
Thermal oxidation of silicon in dry oxygen: Growth - rate enhancement in the thin regime II. Physical mechanisms.
Journal of The Electrochemical Society, 132(11):2693-2700, 1985.

145

F. Masuoka.
US patent number 4437172: Semiconductor memory device (issued 13 March 1984).

146

F. Masuoka and K. Ochii.
US patent number 4710897: Semiconductor memory device comprising six-transistor memory cells (issued 01 December 1987).

147

T. Matsumoto, Y. Kubota, M. Yamada, H. Tsuji, T. Shimatani, Y. Hirayama, S. Terakawa, S. Imai, and H. Kobayashi.
Ultralow-power TFT with gate oxide fabricated by nitric acid oxidation method.
IEEE Electron Device Letters, 31(8):821-823, 2010.

148

C. Mellor.
The 3D die stack tack: Toshiba builds towering column of flash.
The Register online, 2012.
http://www.theregister.co.uk/2012/10/15/toshiba_3d_solid_state/.

149

G. Mesa, E. Dobado-Fuentes, and J. J. Saenz.
Image charge method for electrostatic calculations in field-emission diodes.
Journal of Applied Physics, 79(1):39-44, 1996.

150

G. L. Messing, S.-C. Zhang, and G. V. Jayanthi.
Ceramic powder synthesis by spray pyrolysis.
Journal of the American Ceramic Society, 76(11):2707-2726, 1993.

151

A. Misaka and K. Harafuji.
Simulation study of micro-loading phenomena in silicon dioxide hole etching.
IEEE Transactions on Electron Devices, 44(5):751-760, 1997.

152

S. Mizushima, S. Imai, Asuha, M. Tanaka, and H. Kobayashi.
Nitric acid method for fabrication of gate oxides in TFT.
Applied Surface Science, 254(12):3685-3689, 2008.

153

J. B. Mooney and S. B. Radding.
Spray pyrolysis processing.
Annual Review of Materials Science, 12(1):81-101, 1982.

154

G. Moore.
Cramming more components onto integrated circuits.
Electronics, 38(8):114-117, 1965.

155

J. L. Moruzzi, A. Kiermasz, and W. Eccleston.
Plasma oxidation of silicon.
Plasma Physics, 24(6):605-614, 1982.

156

G. Mutinati, E. Brunet, S. Steinhauer, A. Köck, J. Teva, J. Kraft, J. Siegert, F. Schrank, and E. Bertagnolli.
CMOS-integrable ultrathin SnO$_2$ layer for smart gas sensor devices.
Procedia Engineering, 47, 2012.

157

A. Nakaruk and C. Sorrell.
Conceptual model for spray pyrolysis mechanism: fabrication and annealing of titania thin films.
Journal of Coatings Technology and Research, 7(5):665-676, 2010.

158

M. R. Namin and B. H. Blott.
Superconducting Bi-Sr-Ca-Cu-O films prepared by DC magnetron sputtering on new polycrystalline substrates.
Superconductor Science and Technology, 4(3):110-113, 1991.

159

M. Navi and S. T. Dunham.
A viscous compressible model for stress generation/relaxation in SiO$_2$.
Journal of the Electrochemical Society, 144(1):367-371, 1997.

160

K.-O. Ng and D. Vanderbilt.
Structure and oxidation kinetics of the Si(100)-SiO$_2$ interface.
Physical Review B, 59(15):10132-10137, 1999.

161

S. H. Ng, J. Wang, D. Wexler, S. Y. Chew, and H. K. Liu.
Amorphous carbon-coated silicon nanocomposites: a low-temperature synthesis via spray pyrolysis and their application as high-capacity anodes for lithium-ion batteries.
The Journal of Physical Chemistry C, 111(29):11131-11138, 2007.

162

A. Notargiacomo and A. Tseng.
Assembling uniform oxide lines and layers by overlapping dots and lines using AFM local oxidation.
In IEEE Conference on Nanotechnology, pages 907-910, 2009.

163

J. Ohshima.
State-of-the-art flash memory technology, looking into the future.
In Presented at the GSA/Sematech Memory Conference, 2012.

164

A. Orians, C. Clemons, D. Golovaty, and G. Young.
One-dimensional dynamics of nano-scale oxidation.
Surface Science, 600(16):3297-3312, 2006.

165

S. Osher and J. A. Sethian.
Fronts propagating with curvature-dependent speed: Algorithms based on hamilton-jacobi formulations.
Journal of Computational Physics, 79(1):12-49, 1988.

166

B. Päivänranta, A. Langner, E. Kirk, C. David, and Y. Ekinci.
Sub-10 nm patterning using EUV interference lithography.
Nanotechnology, 22(37):375302-7, 2011.

167

A. Pantazi, A. Sebastian, T. A. Antonakopoulos, P. Bändchtold, A. R. Bonaccio, J. Bonan, G. Cherubini, M. Despont, R. A. DiPietro, U. Drechsler, U. Dündrig, B. Gotsmann, W. Händberle, C. Hagleitner, J. L. Hedrick, D. Jubin, A. Knoll, M. A. Lantz, J. Pentarakis, H. Pozidis, R. C. Pratt, H. Rothuizen, R. Stutz, M. Varsamou, D. Wiesmann, and E. Eleftheriou.
Probe-based ultrahigh-density storage technology.
IBM Journal of Research and Development, 52(4.5):493-511, 2008.

168

F. Paraguay D., W. Estrada L., D. Acosta N., E. Andrade, and M. Miki-Yoshida.
Growth, structure and optical characterization of high quality ZnO thin films obtained by spray pyrolysis.
Thin Solid Films, 350(1-2):192-202, 1999.

169

A. Pasquarello, M. S. Hybertsen, and R. Car.
Atomic dynamics during silicon oxidation.
In Y. J. Chabal, editor, Fundamental Aspects of Silicon Oxidation, volume 46 of Springer Series in Materials Science, pages 107-125. Springer Berlin Heidelberg, 2001.

170

L. Pauling.
The nature of silicon-oxygen bonds.
American Mineralogist, 65:321-323, 1980.

171

D. Perednis.
Thin Film Deposition by Spray Pyrolysis and the Application in Solid Oxide Fuel Cells.
Dissertation, Swiss Federal Institute of Technology Zurich - Eidgenössische Technische Hochschule (ETH) Zürich, 2003.
http://e-collection.library.ethz.ch/eserv/eth:26881/eth-26881-02.pdf.

172

D. Perednis and L. J. Gauckler.
Solid oxide fuel cells with electrolytes prepared via spray pyrolysis.
Solid State Ionics, 166(3-4):229-239, 2004.

173

R. Perez.
Discriminating chemical bonds.
Science, 337(6100):1305-1306, 2012.

174

R. D. Piner, J. Zhu, F. Xu, S. Hong, and C. A. Mirkin.
"Dip-pen" nanolithography.
Science, 283(5402):661-663, 1999.

175

J. D. Plummer, M. D. Deal, and P. B. Griffin.
Silicon VLSI Technology - Fundamentals, Practice and Modeling.
Prentice Hall Electronics and VLSI Series. Prentice-Hall Inc., Upper Saddle River, NJ, 2000.

176

W. H. Press.
Numerical Recipes: The Art of Scientific Computing.
Cambridge University Press, 3rd edition, 2007.

177

M. Quirk and J. Serda.
Semiconductor Manufacturing Technology.
Prentice-Hall Inc., Upper Saddle River, NJ, 2001.

178

M. Radi.
Three-Dimensional Simulation of Thermal Oxidation.
Dissertation, Technischen Universität Wien, Institute for Microelectronics, 1998.
http://www.iue.tuwien.ac.at/phd/radi/.

179

R. R. Razouk, L. N. Lie, and B. Deal.
Kinetics of high pressure oxidation of silicon in pyrogenic steam.
Journal of the Electrochemical Society, 128(10):2214-2220, 1981.

180

S. Rozati and T. Ganj.
Transparent conductive Sn-doped indium oxide thin films deposited by spray pyrolysis technique.
Renewable Energy, 29(10):1671-1676, 2004.

181

J. Ruzyllo1, G. T. Duranko1, and A. M. Hoff1.
Preoxidation UV treatment of silicon wafers.
Journal of the Electrochemical Society, 134(8):2052-2055, 1987.

182

K. Sakai.
High-index immersion lithography.
Recent Advances in Nanofabrication Techniques and Applications, pages 397-416, 2004.
http://cdn.intechweb.org/pdfs/24508.pdf.

183

W. Sears and M. A. Gee.
Mechanics of film formation during the spray pyrolysis of tin oxide.
Thin Solid Films, 165(1):265-277, 1988.

184

M. Serra-García, F. Pérez-Murano, and A. San Paulo.
Nonlinear detection mechanism in quantitative atomic force microscopy characterization of high-frequency nanoelectromechanical systems.
Physical Review B, 85(3):035433-9, 2012.

185

J. A. Sethian.
Level Set Methods and Fast Marching Methods.
Cambridge University Press, 2nd edition, 1999.

186

T. Shimura, E. Mishima, H. Watanabe, K. Yasutake, M. Umeno, K. Tatsumura, T. Watanabe, I. Ohdomari, K. Yamada, S. Kamiyama, Y. Akasaka, Y. Nara, and K. Nakamura.
Ordered structure in the thermal oxide layer on silicon substrates.
ECS Transactions, 1(1):39-48, 2005.

187

W. Siefert.
Properties of thin In$_2$O$_3$ and SnO$_2$ films prepared by corona spray pyrolysis, and a discussion of the spray pyrolysis process.
Thin Solid Films, 120(4):275-282, 1984.

188

Silvaco, Inc.: ATHENA Process Simulation Framework.
http://www.silvaco.com/products/process_simulation/athena.html.

189

Silvaco, Inc.: VICTORY Process 3D Process Simulator.
http://www.silvaco.com/products/vwf/athena/victory/victory_br.html.

190

P. Smeys.
Geometry and Stress Effects in Scaled Integrated Circuit Isolation Technologies.
Ph.d. dissertation, Stanford University, 1996.
http://searchworks.stanford.edu/view/3371223.
http://searchworks.stanford.edu/view/3371223.

191

E. S. Snow and P. M. Campbell.
Fabrication of Si nanostructures with an atomic force microscope.
Applied Physics Letters, 64(15):1932-1934, 1994.

192

E. S. Snow, G. G. Jernigan, and P. M. Campbell.
The kinetics and mechanism of scanned probe oxidation of Si.
Applied Physics Letters, 76(13):1782-1784, 2000.

193

Spraying Systems Co., Volume median diameter versus air pressure at constant liquid pressures.
Data Sheet No. 36892-8M.

194

S. N. Srivastava, K. C. Thompson, E. L. Antonsen, H. Qiu, J. B. Spencer, D. Papke, and D. N. Ruzic.
Lifetime measurements on collector optics from Xe and Sn extreme ultraviolet sources.
Journal of Applied Physics, 102(2):023301-6, 2007.

195

Stanford University: SUPREM-IV.
http://www-tcad.stanford.edu/tcad/programs/suprem4.html.

196

Stanford University: SUPREM-IV.GS Two Dimensional Process Simulation for Silicon and Gallium Arsenide, 1993.
http://www-tcad.stanford.edu/tcad/pubs/Suprem-IV.GS.pdf.

197

D. Stiévenard, P. Fontaine, and E. Dubois.
Nanooxidation using a scanning probe microscope: an analytical model based on field induced oxidation.
Applied Physics Letters, 70(24):3272-3274, 1997.

198

D. Stiévenard and B. Legrand.
Silicon surface nano-oxidation using scanning probe microscopy.
Progress in Surface Science, 81(2-3):112-140, 2006.

199

A. M. Stoneham, M. A. Szymanski, and A. L. Shluger.
Atomic and ionic processes of silicon oxidation.
Physical Review B, 63(24):241304-4, 2001.

200

H. Sugimura, T. Uchida, N. Kitamura, and H. Masuhara.
Scanning tunneling microscope tip-induced anodization for nanofabrication of titanium.
The Journal of Physical Chemistry, 98(16):4352-4357, 1994.

201

H. Sugimura, T. Uchida, N. Kitamura, and H. Masuhara.
Scanning tunneling microscope tip-induced anodization of titanium: Characterization of the modified surface and application to the metal resist process for nanolithography.
Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures, 12(5):2884-2888, 1994.

202

A. G. Sutjipto, A. R. Muhida, and S. Mridha.
Novel nanofabrication process of oxide patterns using AFM in low operating temperature: a promising lithographic tool for future molecular electronics.
In Proceedings of the International Conference on Electrical Engineering and Informatics, pages 238-239, 2007.

203

V. Suvorov, A. Hössinger, Z. Djuric, and N. Ljepojevic.
A novel approach to three-dimensional semiconductor process simulation: Application to thermal oxidation.
Journal of Computational Electronics, 5(4):291-295, 2006.

204

Synopsys, Inc.: Sentaurus Process.
http://www.synopsys.com/Tools/TCAD/ProcessSimulation/Pages/SentaurusProcess.aspx.

205

Synopsys, Inc.: Taurus TSUPREM-IV.
http://www.synopsys.com/Tools/TCAD/ProcessSimulation/Pages/TaurusTSupreme4.aspx.

206

H. Tanaka, M. Kido, K. Yahashi, M. Oomura, R. Katsumata, M. Kito, Y. Fukuzumi, M. Sato, Y. Nagata, Y. Matsuoka, Y. Iwata, H. Aochi, and A. Nitayama.
Bit cost scalable technology with punch and plug process for ultra high density flash memory.
In IEEE Symposium on VLSI Technology, pages 14-15, 2007.

207

Q. Tang, S. Shi, and L. Zhou.
Nanofabrication with atomic force microscopy.
Journal of Nanoscience and Nanotechnology, 4(8):948-963, 2004.

208

K. Tatsumura, T. Watanabe, D. Yamasaki, T. Shimura, M. Umeno, and I. Ohdomari.
Residual order within thermally grown amorphous SiO$_2$ on crystalline silicon.
Physical Review B, 69(8):085212-5, 2004.

209

M. Tello and R. García.
Nano-oxidation of silicon surfaces: Comparison of noncontact and contact atomic-force microscopy methods.
Applied Physics Letters, 79(3):424-426, 2001.

210

T. Teuschler, K. Mahr, S. Miyazaki, M. Hundhausen, and L. Ley.
Nanometer-scale field-induced oxidation of Si(111):H by a conducting-probe scanning force microscope: Doping dependence and kinetics.
Applied Physics Letters, 67(21):3144-3146, 1995.

211

A. Tischner, T. Maier, C. Stepper, and A. Köck.
Ultrathin SnO$_2$ gas sensors fabricated by spray pyrolysis for the detection of humidity and carbon monoxide.
Sensors and Actuators B: Chemical, 134(2):796-802, 2008.

212

A. A. Tseng.
Advancements and challenges in development of atomic force microscopy for nanofabrication.
Nano Today, 6(5):493-509, 2011.

213

A. A. Tseng, T. Lee, A. Notargiacomo, and T. P. Chen.
Formation of uniform nanoscale oxide layers assembled by overlapping oxide lines using atomic force microscopy.
Journal of Micro/Nanolithography, MEMS, and MOEMS, 8(4):043050-8, 2009.

214

Y. Tu and J. Tersoff.
Microscopic dynamics of silicon oxidation.
Physical Review Letters, 89(8):086102-4, 2002.

215

D. Veberic.
Having Fun with Lambert W(x) Function.
ArXiv e-prints, 2010.
http://adsabs.harvard.edu/abs/2010arXiv1003.1628V.

216

J. C. Viguié and J. Spitz.
Chemical vapor deposition at low temperatures.
Journal of The Electrochemical Society, 122(4):585-588, 1975.

217

S. A. Vitale, H. Chae, and H. H. Sawin.
Silicon etching yields in F$_2$, Cl$_2$, Br$_2$, and HBr high density plasmas.
Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, 19(5):2197-2206, 2001.

218

W. L. Warren, K. Vanheusden, J. R. Schwank, D. M. Fleetwood, P. S. Winokur, and R. A. B. Devine.
Mechanism for anneal-induced interfacial charging in SiO$_2$ thin films on Si.
Applied Physics Letters, 68(21):2993-2995, 1996.

219

H. Watanabe, N. Miyata, and M. Ichikawa.
Layer-by-layer oxidation of Si(001) surfaces.
In Y. J. Chabal, editor, Fundamental Aspects of Silicon Oxidation, volume 46 of Springer Series in Materials Science, pages 89-105. Springer Berlin Heidelberg, 2001.

220

T. Watanabe and I. Ohdomari.
A new kinetic equation for thermal oxidation of silicon replacing the Deal-Grove equation.
ECS Transactions, 6(3):465-481, 2007.

221

T. Watanabe, K. Tatsumura, and I. Ohdomari.
New linear-parabolic rate equation for thermal oxidation of silicon.
Physical Review Letters, 96(19):196102-4, 2006.

222

S. B. Weber, H. L. Lein, T. Grande, and M.-A. Einarsrud.
Deposition mechanisms of thick lanthanum zirconate coatings by spray pyrolysis.
Journal of the American Ceramic Society, 94(12):4256-4262, 2011.

223

J. Welker and F. J. Giessibl.
Revealing the angular symmetry of chemical bonds by atomic force microscopy.
Science, 336(6080):444-449, 2012.

224

L. Weng, L. Zhang, Y. Chen, and L. Rokhinson.
AFM local oxidation nanolithography of graphene.
Bulletin of the American Physical Society, 54:1-3, 2009.

225

S. Whang, K. Lee, D. Shin, B. Kim, M. Kim, J. Bin, J. Han, S. Kim, B. Lee, Y. Jung, S. Cho, C. Shin, H. Yoo, S. Choi, K. Hong, S. Aritome, S. Park, and S. Hong.
Novel 3-dimensional dual control-gate with surrounding floating-gate (DC-SF) NAND flash cell for 1Tb file storage application.
In IEEE International Electron Devices Meeting (IEDM), pages 29-7, 2010.

226

R. T. Whitaker.
A level-set approach to 3D reconstruction from range data.
International Journal of Computer Vision, 29(3):203-231, 1998.

227

R. Wiesendanger.
Scanning probe microscopy and spectroscopy: Methods and applications.
Cambridge University Press, 1994.

228

O. Wilhelm.
Electrohydrodynamic spraying - Transport, Mass and Heat Transfer of Charged Droplets and Their Application to the Deposition of Thin Functional Films.
Dissertation, Swiss Federal Institute of Technology Zurich - Eidgenössische Technische Hochschule (ETH) Zürich, 2004.
http://fex-dev2.ethz.ch/eserv/eth:27191/eth-27191-02.pdf.

229

D. R. Wolters and A. T. A. Z. Duijnhoven.
Silicon oxidation and fixed oxide charge.
Journal of the Electrochemical Society, 139(1):241-249, 1992.

230

Y. Xia and G. Whitesides.
Soft lithography.
Angewandte Chemie International Edition, 37(1):550-575, 1998.

231

M. Yasutake, Y. Ejiri, and T. Hattori.
Modification of silicon surface using atomic force microscope with conducting probe.
Japanese Journal of Applied Physics Letters B, 32:L1021-L1023, 1993.

232

H. Yu, Y. Sun, N. Singh, G.-Q. Lo, and D.-L. Kwong.
Perspective of flash memory realized on vertical Si nanowires.
Microelectronics Reliability, 52(4):651-661, 2012.

233

M. Zhang, D. Bullen, S.-W. Chung, S. Hong, K. S. Ryu, Z. Fan, C. A. Mirkin, and C. Liu.
A MEMS nanoplotter with high-density parallel dip-pen nanolithography probe arrays.
Nanotechnology, 13(2):212-217, 2002.

234

Q. Zhong, D. Inniss, K. Kjoller, and V. Elings.
Fractured polymer/silica fiber surface studied by tapping mode atomic force microscopy.
Surface Science Letters, 290(1-2):L688-L692, 1993.

235

J. Zou, D. Bullen, X. Wang, C. Liu, and C. A. Mirkin.
Conductivity-based contact sensing for probe arrays in dip-pen nanolithography.
Applied Physics Letters, 83(3):581-583, 2003.