Title :
Numerical analysis of nano schottky junctions for developing novel sub-20 nm electronic devices
Author :
Eledlebi, Khouloud ; Ismail, Mohammed ; Rezeq, Moh´d
Author_Institution :
Dept. of Electr. & Comput. Eng., Khalifa Univ. of Sci., Abu Dhabi, United Arab Emirates
Abstract :
Nano metal-semiconductor contacts in sub-20 nm range have showed unusual electrical characteristics compared to conventional diodes. New devices based on nano Schottky junction have been proposed to overcome the limitations of CMOS devices. Here we introduce a new theoretical approach for studying the enhancement of the electric field at the interface, and then the net current along the junction. The results revealed a dominant tunneling current at the reverse bias for low n-dope semiconductor substrates. Whereas for high n-dope substrates, the thermionic current is dominant at the forward bias. We have used a finite element simulation software (COMSOL) to analyze the electrical characteristics of nano Schottky diodes, and compare the theoretical results with experimental data.
Keywords :
Schottky diodes; finite element analysis; metal-semiconductor-metal structures; nanoelectronics; CMOS devices; electric field; electronic devices; finite element simulation software; high n-dope substrates; low n-dope semiconductor substrates; nano Schottky junctions; nano metal-semiconductor contacts; thermionic current; tunneling current; Junctions; Mathematical model; Metals; Nanoscale devices; Schottky diodes; Semiconductor device modeling; Substrates; Nano Devices; Nano Metal Particles; Nano Schottky Junctions; Thermionic Current; Tunneling Current;
Conference_Titel :
Electronics, Circuits and Systems (ICECS), 2014 21st IEEE International Conference on
DOI :
10.1109/ICECS.2014.7050032
