Elektromigration in Gold und Silber Nanostrukturen
Elektromigration in Gold und Silber Nanostrukturen
Elektromigration in Gold und Silber Nanostrukturen
Erfolgreiche ePaper selbst erstellen
Machen Sie aus Ihren PDF Publikationen ein blätterbares Flipbook mit unserer einzigartigen Google optimierten e-Paper Software.
124 Literatur<br />
[136] T. O. Ogurtani, E. E. Oren, J. Appl. Phys. 96(12), 7246 (2004), Electromigration-<br />
<strong>in</strong>duced void gra<strong>in</strong>-bo<strong>und</strong>ary <strong>in</strong>teractions: The mean time to failure for copper<br />
<strong>in</strong>terconnects with bamboo and near-bamboo structures.<br />
[137] A. Zehe, A. Ramirez, Cryst. Res. Technol. 35(5), 557 (2000), Electromigration of<br />
alum<strong>in</strong>um through quasi bamboo-like gra<strong>in</strong> blocked silicide <strong>in</strong>terconnects.<br />
[138] J. M. Schoen, J. Appl. Phys. 51(1), 508 (1980), A model of electromigration failure<br />
<strong>und</strong>er pulsed condition.<br />
[139] R. E. Hummel, H. H. Hoang, J. Appl. Phys. 65(5), 1929 (1989), On the electro-<br />
migration failure <strong>und</strong>er pulsed conditions.<br />
[140] K. Banerjee, A. Amerasekera, G. Dixit, N. Cheung, C. Hu, IEEE International,<br />
35th Annual Proceed<strong>in</strong>gs (Reliability Physics Symposium), 216 (1997), Characte-<br />
rization of contact and via failure <strong>und</strong>er short duration high pulsed current stress.<br />
[141] J. J. Clement, J. Appl. Phys. 82(12), 5991 (1997), Reliability analysis for en-<br />
capsulated <strong>in</strong>terconnect l<strong>in</strong>es <strong>und</strong>er dc <strong>und</strong> pulsed dc current us<strong>in</strong>g a cont<strong>in</strong>uum<br />
electromigration transport model.<br />
[142] I. A. Blech, Th<strong>in</strong> Solid Films 13, 117 (1972), Electromigration and cravice forma-<br />
tion <strong>in</strong> th<strong>in</strong> metallic films.<br />
[143] C.-F. Hong, M. Togo, K. Hoh, Jpn. J. Appl. Phys. 32, L624 (1993), Repair of<br />
electromigration-<strong>in</strong>duced voids <strong>in</strong> alum<strong>in</strong>um <strong>in</strong>terconnection by current reversal.<br />
[144] E. Scheer, P. Joyez, D. Esteve, C. Urb<strong>in</strong>a, M. H. Devoret, Phys. Rev. Lett. 78(18),<br />
3535, (1997), Conduction channel transmissions of atomic-size alum<strong>in</strong>um contacts.<br />
[145] M. L. Trouwborst, S. J. van der Molen, B. J. van Wees, J. Appl. Phys. 99, 114316<br />
(2006), The role of Joule heat<strong>in</strong>g <strong>in</strong> the formation of nanogaps by electromigration.<br />
[146] Z. M. Wu, M. Ste<strong>in</strong>acher, R. Huber, M. Calame, S. J. van der Molen, C. Schöne-<br />
berger, Appl. Phys. Lett. 91, 053118 (2007), Feedback controlled electromigration<br />
<strong>in</strong> four-term<strong>in</strong>al nanojunctions.<br />
[147] S. I. Khondaker, Z. Yao, Appl. Phys. Lett. 81(24), 4613 (2002), Fabrication of<br />
nanometer-spaced electrodes us<strong>in</strong>g gold nanoparticles.<br />
[148] Z. K. Keane, L. H. Yu, D. Natelson, Appl. Phys. Lett. 88, 06214 (2006), Magne-<br />
toresistance of atomic-scale electromigrated nickel nanocontacts.
Change language