Title :
The impact of uniform strain applied via bonding onto plastic substrate on MOSFET performance
Author :
Bera, L.K. ; Loh, W.Y. ; Guo, L.H. ; Zhang, X.W. ; Lo, G.Q. ; Balasubramanian, N. ; Kwong, D.-L.
Author_Institution :
Inst. of Microelectron., Singapore, Singapore
Abstract :
For the first time, this letter presents a novel post-backend strain applying technique and the study of its impact on MOSFET device performance. By bonding the Si wafer after transistor fabrication onto a plastic substrate (a conventional packaging material FR-4), a biaxial-tensile strain (/spl sim/0.026%) was achieved globally and uniformly across the wafer due to the shrinkage of the bonded adhesive. A drain-current improvement (average /spl Delta/I/sub d//I/sub d//spl sim/10%) for n-MOSFETs uniformly across the 8-in wafer is observed, independent of the gate dimensions (L/sub g//spl sim/55 nm -0.530 μm/W /spl sim/2-20 μm). The p-MOSFETs also exhibited I/sub d/-improvement by /spl sim/7% under the same biaxial-tensile strain. The strain impact on overall device characteristics was also studied, including increased gate-induced drain leakage and short-channel effects.
Keywords :
MOSFET; adhesive bonding; elemental semiconductors; leakage currents; silicon; stress effects; wafer bonding; 8 in; MOSFET device performance; Si; biaxial-tensile strain; drain induced barrier lowering; drain-current enhancement; gate-induced drain leakage; n-MOSFET device; p-MOSFET device; packaging material; plastic substrates; post-backend strain effects; short-channel effects; wafer bonding; Bonding processes; Capacitive sensors; Electrodes; Implants; MOSFET circuits; Packaging; Plastics; Stress; Transistors; Wafer bonding; Biaxial-tensile strain; drain–current enhancement; drain-induced barrier lowering (DIBL); wafer bonding;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2005.861719
