Biomedical Engineering Reference
In-Depth Information
31. K. Prashanthi, M. Naresh, V. Seena, T. h undat, V. R. Rao, “A novel photo-
plastic piezoelectric nanocomposite for MEMS applications,”
J MEMS Lett.
,
Vol.21, pp.259 -261,(2012).
32. M. Kandpal, C. Sharan, P. Poddar, K. Prashanthi, P. R. Apte, V. R. Rao,
“Photopatternable nano-composite (SU-8/ZnO) thin i lms for piezo-electric
applications,”.
Appl. Phys.Lett.
, Vol. 101, pp.104102-5 (2012).
33. X.-wu Zhang, Y.I. Pan, Q. Zheng, and X.-su Yi, “Time Dependence of
Piezoresistance for the Conductor-,”
Polymer
, 2000, pp. 2739-2749.
34. M.H.G. Wichmann, S.T. Buschhorn, J. Gehrmann, and K. Schulte,
“Piezoresistive response of epoxy composites with carbon nanoparticles
under tensile load,” vol. c, 2009, pp. 1-8.
35. H.C. Chiamori, J.W. Brown, E.V. Adhiprakasha, and E.T. Hantsoo,
“Suspension of nanoparticles in SU-8 : Processing and characterization
of nanocomposite polymers,”
Microelectronics Journal
, vol. 39, 2008, pp.
228-236.
36. D. Tranchida, S. Piccarolo, J. Loos, A. Alexeev, D. Tranchida, S. Piccarolo,
J. Loos, and A. Alexeev, “Mechanical Characterization of Polymers on
a Nanometer Scale through Nanoindentation . A Study on Pile-up and
Viscoelasticity,”
Macromolecules
, vol. 40, 2007, pp. 1259-1267.
37. W. C. Oliver and G. M. Pharr,” Measurement of hardness and elastic mod-
ulus by instrumented indentation: Advances in understanding and rei ne-
ments to methodology”,
J. Mat. Res.
, vol.19, pp. 3-20, 2004.
38. J. C. Grunlan, D. Rowenhorst, L. F. Francis and W. W. Gerberich ,”
Modulus Determination of Polymer Matrix Composites: Comparison of
Nanoindentation and Dynamic Mechanical Analysis”
Mat. Res. Soc. Symp.
vol. 649
39. N. Abdel-Aal, Farid El-Tantawy, A. Al-Hajry and M. Bououdina , “Epoxy Resin/
Plasticized Carbon Black Composites.Part II. Correlation Among Network
Structure and Mechanical Properties”
Polymer Composites
, pp. 804 - 808, 2008.
40. C. Serre, P. Gorostiza, A. Prez-rodriguez, F. Sanz, and J.R. Morante,
“Measurement of micromechanical properties of polysilicon microstruc-
tures with an atomic force microscope,”
Sensors and Actuators
, vol. 67, 1998,
pp. 215-219.
41.
T. Sekitani, Y. Kato, S. Iba, H. Shinaoka, and T. Someya, “Bending experiment
on pentacene i eld-ef ect transistors on plastic i lms”
Appl. Phys. Letters.
, vol.
86, p.073511, 2005.
42.
T. Ji, S. Jung, and V.K. Varadan, “ Field-Controllable Flexible Strain Sensors
Using Pentacene Semiconductors”,
IEEE Electron Device Lett
., vol.28, 2007.
43.
M. Kitamura and Y. Arakawa, “Pentacene-based organic i eld-ef ect transis-
tors”,
J. Phys.: Condens. Matter
, vol. 20, pp. 184011, 2008.
44.
T. Sekitani, U. Zschieschang, H. Klauk, and T. Someya, “Flexible organic
transistors and circuits with extreme bending stability,”
Nature Materials
,
vol. 9, 2010, p. 1015.
45.
A. Jedaa and M. Halik, “Toward strain resistant l exible organic thin i lm
transistors,”
Applied Physics Letters
, vol. 95, 2009, p. 103309.
