| Revista: | Brazilian journal of physics |
| Base de datos: | PERIÓDICA |
| Número de sistema: | 000334074 |
| ISSN: | 0103-9733 |
| Autores: | Arofiati Noor, Fatimah1 Abdullah, Mikrajuddin1 Sukirno1 Khairurrijal1 |
| Instituciones: | 1Institut Teknologi Bandung, Faculty of Mathematics and Natural Sciences, Bandung. Indonesia |
| Año: | 2010 |
| Periodo: | Dic |
| Volumen: | 40 |
| Número: | 4 |
| Paginación: | 404-407 |
| País: | Brasil |
| Idioma: | Inglés |
| Tipo de documento: | Artículo |
| Enfoque: | Analítico, descriptivo |
| Resumen en inglés | An electron direct tunneling current model of n+- poly - Si/SiO2/p - Si(100) metal-oxide-semiconductor (MOS) capacitors has been developed by considering a parallel-perpendicular kinetic energy coupling, which is represented by the gate electron phase velocity, and anisotropic masses under a parabolic E-k dispersion relationship. The electron effective mass in the oxide and the electron phase velocity in the n+ poly-Si gate are the only two fitting parameters to compare calculated tunneling currents to measured ones. It was obtained that the calculated tunneling currents fit well to the measured ones. The electron effective mass in the oxide layer tends to increase with decreasing the oxide thickness. In addition, the gate electron velocity is a constant of 1x105m/s. Moreover, the theoretical model offers a simple treatment and an accurate result in obtaining the tunneling current |
| Disciplinas: | Física y astronomía |
| Palabras clave: | Física de materia condensada, Oxido de entrada, Masa anisotrópica, Velocidad de entrada, Corriente de tunelaje |
| Keyword: | Physics and astronomy, Condensed matter physics, Gate oxide, Anisotropic mass, Gate velocity, Tunneling current |
| Texto completo: | Texto completo (Ver HTML) |
