Title :
Tradeoff Characteristics Between Resistivity and Reliability for Scaled-Down Cu-Based Interconnects
Author :
Yokogawa, Shinji ; Kikuta, Kuniko ; Tsuchiya, Hideaki ; Takewaki, Toshiyuki ; Suzuki, Mieko ; Toyoshima, Hironori ; Kakuhara, Yumi ; Kawahara, Naoyoshi ; Usami, Tatsuya ; Ohto, Koichi ; Fujii, Kunihiro ; Tsuchiya, Yasuaki ; Arita, Koji ; Motoyama, Koichi
Author_Institution :
NEC Electron. Corp., Kawasaki
Abstract :
We investigated tradeoff characteristics between resistivity and reliability for scaled-down Cu-based interconnects. A unique resistivity-measurement technique is proposed to detect influences due to impurity doping. Using this technique, we investigated the impacts of the impurity doping on three types of copper interconnects - cobalt-tungsten-phosphorous (CoWP) metal-cap interconnects, plasma-enhanced chemical-vapor-deposition self-aligned barrier interconnects, and CuAl alloy interconnects - and clarified the tradeoffs between the resistivity and the reliability. We found that the metal-cap interconnect shows not only high reliability but also outstanding efficiency with regard to the suppression of resistance increase due to impurity doping.
Keywords :
aluminium alloys; copper; copper alloys; electrical resistivity; integrated circuit interconnections; integrated circuit reliability; phosphorus alloys; plasma CVD; semiconductor doping; tungsten alloys; CoWP; Cu; CuAl; cobalt-tungsten-phosphorous interconnects; copper interconnects; electrical resistivity; impurity doping; interconnect reliability; metal-cap interconnects; plasma-enhanced chemical-vapor-deposition; self-aligned barrier interconnects; Chemicals; Conductivity; Copper; Current density; Doping; Impurities; Integrated circuit interconnections; Mie scattering; National electric code; Plasma chemistry; Cobalt–tungsten–phosphorous (CoWP); Cobalt–tungsten–phosphorous (CoWP); copper alloy; copper interconnect; electromigration (EM); plasma-enhanced chemical-vapor-deposition (PECVD) self-aligned barrier (PSAB); reliability; resistivity; stress-induced voiding (SIV);
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2007.910619
