Title :
Complementary Silicon Nanowire Hydrogen Ion Sensor With High Sensitivity and Voltage Output
Author :
Lee, Jieun ; Lee, Jin-Moo ; Lee, Jung Han ; Lee, Won Hee ; Uhm, Mihee ; Park, Byung-Gook ; Kim, Dong Myong ; Jeong, Yong-Joo ; Kim, Dae Hwan
Author_Institution :
Sch. of Electr. Eng., Kookmin Univ., Seoul, South Korea
Abstract :
Complementary Si nanowire (SiNW) hydrogen ion sensors with high sensitivity and robust voltage output are demonstrated on a 6-in silicon-on-insulator wafer using a conventional wafer-level top-down process. The proposed SiNW sensors exhibit a logic threshold voltage shift of 88.9 mV/pH and an output voltage swing of 162 mV/pH. Furthermore, a simplified analytical model confirms that the proposed sensors have an output voltage swing that is 1.6 times larger than single SiNW sensor counterparts with a resistive load. Therefore, the proposed fabrication approach is expected to be a good solution for a very sensitive voltage readout scheme for the mass production of top-down processed biosensors.
Keywords :
biosensors; chemical sensors; elemental semiconductors; nanosensors; nanowires; pH; silicon; silicon-on-insulator; 6-in silicon-on-insulator wafer; H; Si; complementary silicon nanowire hydrogen ion sensor; conventional wafer-level top-down process; logic threshold voltage shift; mass production; output voltage swing; pH; resistive load; robust voltage output; size 6 in; top-down processed biosensor; voltage readout scheme; Biosensors; FETs; Hydrogen; Nanowires; Sensitivity; Silicon; Threshold voltage; Complementary inverter; hydrogen ion sensor; silicon nanowire FET; top-down fabrication; voltage readout;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2012.2220515
