Title :
Noise of Ta2O5 and Nb2O5 thin insulating films in the temperature range 10 K to 400 K
Author :
Sedlakova, V. ; Chvatal, M. ; Kopecky, M. ; Sikula, J.
Author_Institution :
Dept. of Phys., Brno Univ. of Technol., Brno, Czech Republic
Abstract :
We have performed investigation of noise and transport mechanisms in insulating films of Ta2O5 and Nb2O5 from the point of view of their application as dielectric layers in capacitors, MOS devices, etc. These dielectric films show high relative permittivity, low leakage current density of the order of nA/cm2 in the electric field 1MV/cm, and high breakdown field of the order of 3-4 MV/cm. Analysis of I-V characteristics performed as a function of temperature allows the identification of dominant conduction mechanisms and corresponding noise sources. Ta2O5 films of the thickness about 28 nm and Nb2O5 thin films of the thickness about 150 nm were investigated. Tunneling current mechanism is dominant for the temperatures below 200 K. In this temperature range current noise spectral density is 1/f type. Poole-Frenkel and Schottky current transport mechanism is dominant for temperatures higher than 350 K. 1/f noise is pronounced in the frequency range bellow 20 Hz, while in the range 20 to 100 Hz GR noise is dominant for low current values. For the insulating layer thickness below 50 nm current noise spectral density is given by the superposition of at least two GR noise components with different time constants. This behavior is observed for the temperature higher than 200 K.
Keywords :
Poole-Frenkel effect; Schottky effect; dielectric thin films; electric breakdown; insulating thin films; leakage currents; niobium compounds; noise; permittivity; tantalum compounds; tunnelling; Nb2O5; Poole-Frenkel mechanism; Schottky current transport mechanism; Ta2O5; conduction mechanisms; dielectric breakdown; dielectric films; leakage current density; noise spectral density; relative permittivity; temperature 10 K to 400 K; thin insulating films; transport mechanisms; tunneling current mechanism; Electric fields; Noise; Temperature dependence; Temperature distribution; Temperature measurement; Tunneling; 1/f noise; G-R noise; Poole-Frenkel current; Thin oxide films; Tunnelling;
Conference_Titel :
Noise and Fluctuations (ICNF), 2011 21st International Conference on
Conference_Location :
Toronto, ON
Print_ISBN :
978-1-4577-0189-4
DOI :
10.1109/ICNF.2011.5994376