Chemistry Reference
In-Depth Information
156. S. Meiners, J.G.H. Salge, E. Prinz, and F. Förster. Surface modification of polymer
materials by transient gas discharges at atmospheric pressure.
Surf. Coat. Technol.
,
98(1-3):1121-1127, 1998.
157. U. Lommatzsch, D. Pasedag, A. Baalmann, G. Ellinghorst, and H.-E. Wagner.
Atmospheric pressure plasma jet treatment of polyethylene surfaces for adhesion
improvement.
Plasma Process. Polym.
, 4(S1):S1041-S1045, 2007.
158. F. Massines and G. Gouda. A comparison of polypropylene-surface treatment by
filamentary, homogeneous and glow discharges in helium at atmospheric pressure.
J. Phys. D Appl. Phys.
, 31(24):3411-3420, 1998.
159. S. Guimond, I. Radu, G. Czeremuszkin, D.J. Carlsson, and M.R. Wertheimer. Biax-
ially oriented polypropylene (BOPP) surface modification by nitrogen atmospheric
pressure glow discharge (APGD) and by air corona.
Plasmas Polym.
, 7(1):71-88,
2002.
160. R. Seeböck, H. Esrom, M. Charbonnier, and M. Romand. Modification of polyimide
in barrier discharge air-plasmas: Chemical and morphological effects.
Plasmas
Polym.
, 5(2):103-118, 2000.
161. R. Seeböck, H. Esrom, M. Charbonnier, M. Romand, and U. Kogelschatz. Surface
modification of polyimide using dielectric barrier discharge treatment.
Surf. Coat.
Technol.
, 142-144:455-459, 2001.
162. G. Borcia, C.A. Anderson, and N.M.D. Brown. The surface oxidation of selected
polymers using an atmospheric pressure air dielectric barrier discharge. Part I.
Appl.
Surf. Sci.
, 221(1-4):203-214, 2004.
163. S. Mändl. Ionenbeschuss von Polymeren für die Medizintechnik.
Vac. Forsch. Prax.
22(6):36-40, 2010.
164. A. Ohl, H. Strobel, J. Röpcke, H. Kammerstetter, A. Pries, and M. Schnei-
der. Investigation of plasma surface cleaning in planar low-pressure microwave
discharges-investigation of plasmasurfacecleaning in planar low-pressuremicrowave
discharges.
Surf. Coat. Technol.
, 74-75:59-62, 1995.
165. J. Benedikt, C. Flötgen, G. Kussel, V. Raball, and A. von Keudell. Etching of
Bacillus atrophaeus
by oxygen atoms, molecules and argon ions.
J.Phys.Conf.Ser.
,
133:012012, 2008.
166. T. Schwarz-Selinger, U. von Toussaint, C. Hopf, M. Schlüter, and W. Jacob. Chemical
sputtering of carbon films by simultaneous irradiation with argon ions and molecular
oxygen.
New J. Phys.
, 10:090322, 2008.
167. M.R. Baklanov, D.G. Shamiryan, Zs. Tökei, G.P. Beyer, T. Conard, S. Vanhaele-
meersch, and K. Maex. Characterization of Cu surface cleaning by hydrogen plasma.
J. Vac. Sci. Technol. B
, 19(4):1201-1211, 2001.
168. Y. Sawada, N. Taguchi, and K. Tachibana. Reduction of copper oxide thin films
with hydrogen plasma generated by a dielectric-barrier glow discharge.
Jpn. J. Appl.
Phys.
, 38:6506-6511, 1999.
169. D. Korzec, M. Teschke, E.G. Finatu, G. Nau, and J. Engemann. In
Conference
Proceedings of the 47th Meeting of the Society of Vacuum Coaters
, Dallas, TX,
pp. 455-460, 2004.
170. J.H. Hsieh, L.H. Fong, S. Yi, and G. Metha. Plasma cleaning of copper leadframe
with Ar and Ar/H
2
gases.
Surf. Coat. Technol.
, 112:245-249, 1999.
171. P. Fuchs. Low-pressure plasma cleaning of Au and PtIr noble metal surfaces.
Appl.
Surf. Sci.
, 256(5):1382-1390, 2009.
172. S. Veprek, J. Patscheider, and J. Elmer. Restoration and conservation of ancient
artifacts: A new area of application of plasma chemistry.
Plasma Chem. Plasma
Process.
, 5(2):201-209, 1985.
