Title :
Complementary Logic Gates and Ring Oscillators on Plastic Substrates by Use of Printed Ribbons of Single-Crystalline Silicon
Author :
Kim, Dae-Hyeong ; Ahn, Jong-Hyun ; Kim, Hoon-Sik ; Lee, Keon Jae ; Kim, Tae-Ho ; Yu, Chang-Jae ; Nuzzo, Ralph G. ; Rogers, John A.
Author_Institution :
Univ. of Illinois at Urbana-Champaign, Urbana
Abstract :
CMOS inverters and three-stage ring oscillators were formed on flexible plastic substrates by transfer printing of p-type and n-type single crystalline ribbons of silicon. The gain and the sum of high and low noise margins of the inverters were as high as ~150 and 4.5 V at supply voltages of 5 V, respectively. The frequencies of the ring oscillators reached 2.6 MHz at supply voltages of 10 V. These results, as obtained with devices that have relatively large critical dimensions (i.e., channel lengths in the several micrometer range), taken together with good mechanical bendability, suggest promise for the use of this type of technology for flexible electronic systems.
Keywords :
CMOS digital integrated circuits; elemental semiconductors; invertors; logic gates; oscillators; silicon; CMOS inverters; Si; complementary logic gates; flexible electronic systems; frequency 2.6 MHz; mechanical bendability; plastic substrates; printed ribbons; single-crystalline silicon; three-stage ring oscillators; voltage 10 V; voltage 4.5 V; voltage 5 V; CMOS logic circuits; Crystallization; Frequency; Inverters; Logic gates; Plastics; Printing; Ring oscillators; Silicon; Voltage; CMOS inverter; flexible circuits; thin-film transistor (TFT);
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2007.910770
