Trap Concentration Dependence on the Electrical Properties of Annealed Ultrathin Fluorinated Silicon Oxides
スポンサーリンク
概要
- 論文の詳細を見る
In this study, the electrical properties of ultrathin (5–9 nm) liquid-phase-deposited fluorinated silicon oxides (LPD-SiOFs) are investigated under various annealing conditions. The electron tunneling current at $E_{\text{ox}}=4\text{--}6$ MV/cm is suggested to be modeled by a generalized trap-assisted tunneling (GTAT) mechanism with consideration of trapezoidal- and triangular-barrier tunnelings. This gives the trap concentration ($N_{\text{t}}$) and the trap energy level ($\Phi_{\text{t}}$) of a trapped oxide that is induced by fluorine incorporation. The reported $\Phi_{\text{t}}$ of fluorine is around 1.98–2.2 eV while $N_{\text{t}}$ for O2-annealed LPD-SiOF is $1\times 10^{16}\text{--}3\times 10^{18}$ cm-3 and $N_{\text{t}}$ for N2O-annealed LPD-SiOF is $5\times 10^{14}\text{--}2\times 10^{15}$ cm-3, depending on the annealing conditions. The trap concentration within the LPD-SiOF film is demonstrated to decrease with an increase in annealing temperature and time. From the GTAT modeling of O2- and N2O-annealed LPD-SiOF films, it is obvious that nitridation in N2O can substantially reduce the concentration of traps (by an order of magnitude of two) contained in original LPD-SiOF films. The flat-band voltage shift, interface trap density, constant current stress (CCS), and constant voltage stress (CVS) all show that LPD-SiOF annealed in N2O has the best material quality in comparison with others. As shown in the experimental and modeling results, the traps are found to be strongly dependent on the impurities contained in the oxide films (F or N atoms in this study). Using the GTAT model, we can derive the trap energy level and trap concentration simply from the current–voltage ($I$–$V$) characteristics without the use of other complicated measuring techniques.
- INSTITUTE OF PURE AND APPLIED PHYSICSの論文
- 2001-03-15
著者
-
Chang Wai-jyh
Department Of Electrical Engineering National Cheng-kung University
-
Wang Yeong-her
Department Of Electrical Engineering National Cheng Kung University
-
Houng Mau-phon
Department Of Electrical Engineering National Cheng Kung University
-
Wang Yeong-Her
Department of Electrical Engineering, National Cheng-Kung University, Taiwan, R.O.C.
-
Houng Mau-Phon
Department of Electrical Engineering, National Cheng-Kung University, Taiwan, R.O.C.
関連論文
- Molecular Beam Epitaxy Grown GaAs Bipolar-Unipolar Transition Negative Differential Resistance Power Transistor
- Trap Concentration Dependence on the Electrical Properties of Annealed Ultrathin Fluorinated Silicon Oxides
- Fourier Transform Infrared Characterization of Moisture Absorption in SiOF Film
- Effect of Fluorine Concentration on the Metal-Insulator-Semiconductor (MIS) Solar Cell Output Performance by Liquid Phase Deposition
- Near Room-Temperature Growth of SiO_2 Films for p-HgCdTe Passivation by Liquid Phase Deposition
- Bond Orbital Model with Microscopic Interface Effects(Semiconductors)
- GaAs Metal-Oxide-Semiconductor Field Effect Transistors Fabricated with Low-Temperature Liquid-Phase-Deposited SiO_2
- AlGaN/GaN Metal Oxide Semiconductor Heterostructure Field-Effect Transistor Based on a Liquid Phase Deposited Oxide : Semiconductors
- Surface Oxidation Kinetics of GaAs Oxide Growth by Liquid Phase Chemical-Enhanced Technique
- Investigation of Low-Temperature Deposition of Silicon Dioxide on Indium Phosphide by Liquid Phase Deposition
- CO_2 Laser Annealing on Fluorinated Silicon Oxide Films
- Near-Room-Temperature Selective Oxidation on GaAs Using Photoresist as a Mask
- Liquid Phase Chemical-Enhanced Oxidation for GaAs Operated Near Room Temperature
- Low-Temperature Sintering of Microwave Dielectrics (Zn,Mg)TiO3
- Formation of One-dimensional Crooked Gold Nanocrystals by Electrochemical Technique with Surfactant Solution
- Multilayer Stepped-Impedance Resonator Band-Pass Filter Implementing Using Low Temperature Cofired Ceramic Structure
- Trap Concentration Dependence on the Electrical Properties of Annealed Ultrathin Fluorinated Silicon Oxides
- CO2 Laser Annealing on Fluorinated Silicon Oxide Films