TY - JOUR
T1 - Short-Time Failure of Metal Interconnect Caused by Current Pulses
AU - Murguia, James E.
AU - Bernstein, Joseph B.
N1 - Funding Information:
Manuscript received July 9, 1993. This work was supported by the Department of the Air Force. The authors are with Lincoln Laboratory, Massachusetts Institute of Technology, Lexington, MA 02173. IEEE Log Number 9212550.
PY - 1993/10
Y1 - 1993/10
N2 - Metal interconnect reliability studies are frequently concerned with lifetimes on the order of years at signal level current densities. Voltage programmable link (VPL) technologies impose a new criterion on the reliability of metal interconnect. Lines of metallization must support the full programming current, which can be many times larger than signal level current, for very short periods of time. For a sufficiently short high current pulse, the wire, encapsulated in oxide, will not reach thermal equilibrium and the current-induced heating can be modeled as being adiabatic. Energy conservation predicts a relationship between maximum current density that can be carried by a wire before it fuses, and the pulse duration time, J2t = 108 A2 · s/cm4. This relationship is based on a temperature rise in the metal line at failure of θf * = 300°C. The time required for the metal to reach thermal equilibrium at a given current density is shown to be proportional to the square of the oxide thickness. These predictions are experimentally verified with layered AlSi/Ti metallization on thermal oxide on silicon substrates.
AB - Metal interconnect reliability studies are frequently concerned with lifetimes on the order of years at signal level current densities. Voltage programmable link (VPL) technologies impose a new criterion on the reliability of metal interconnect. Lines of metallization must support the full programming current, which can be many times larger than signal level current, for very short periods of time. For a sufficiently short high current pulse, the wire, encapsulated in oxide, will not reach thermal equilibrium and the current-induced heating can be modeled as being adiabatic. Energy conservation predicts a relationship between maximum current density that can be carried by a wire before it fuses, and the pulse duration time, J2t = 108 A2 · s/cm4. This relationship is based on a temperature rise in the metal line at failure of θf * = 300°C. The time required for the metal to reach thermal equilibrium at a given current density is shown to be proportional to the square of the oxide thickness. These predictions are experimentally verified with layered AlSi/Ti metallization on thermal oxide on silicon substrates.
UR - http://www.scopus.com/inward/record.url?scp=0027685138&partnerID=8YFLogxK
U2 - 10.1109/55.244737
DO - 10.1109/55.244737
M3 - ???researchoutput.researchoutputtypes.contributiontojournal.article???
AN - SCOPUS:0027685138
SN - 0741-3106
VL - 14
SP - 481
EP - 483
JO - IEEE Electron Device Letters
JF - IEEE Electron Device Letters
IS - 10
ER -